- Veridian Developments

The Most Ambitious Standard

Living Building
Challenge

Buildings that give more to the living world than they take. Seven petals — Place, Water, Energy, Health, Materials, Equity, Beauty — defining what it truly means for a building to be alive.

🏆

The most rigorous green building standard on Earth. LBC 4.0 is not a checklist — it demands NET POSITIVE performance in energy, water, and waste. Projects must demonstrate actual performance over a 12-month occupied period (not predicted performance). The standard operates across 7 Petals and 20 Imperatives. All Core Imperatives must be met for any certification level. There are no credits — either you meet each Imperative or you don’t.

105%

Net Positive energy — must produce 105% of all energy needs from on-site renewables

I08 Net Positive Carbon

50%

Potable water reduction vs baseline (new buildings). 30% for existing buildings.

I05 + I06 Water Petals

70%

Energy use reduction for new buildings vs baseline EUI (I07)

50% existing · 40% interior

20%

Embodied carbon reduction in primary materials vs baseline (I07)

LCA stages A1–A5

90%

Materials by cost must avoid Red List chemical classes (I13)

100 ppm disclosure threshold

12 mo

Performance Period — continuous 12 months at ≥85% occupancy required to certify

Must be actual not predicted

20

Total Imperatives across 7 Petals

10 are Core (C1–C10)

0

Combustion-based heating/cooling allowed in new construction

Zero combustion mandate

Certification Types — Four Pathways

Certification	Imperatives Required	Performance Period	What It Signals
Living Certified	All 20 Imperatives (all 7 Petals)	12 months at ≥85% occupancy	The highest level. Net positive energy, water, carbon. Zero Red List. Full regenerative performance.
Petal Certification	3+ Petals (must include Energy, Water, OR Materials)	12 months	Demonstrable excellence in specific domains. Common stepping stone. Energy Petal is most popular single-Petal.
Core Green Building Certification	10 Core Imperatives only (C1–C10)	Documentation at completion (no performance period needed)	Best-practice green building. Equivalent to a high-performing LEED/Green Star project. No performance period requirement.
Zero Energy Certified	I07 + I08 Energy Imperatives + Core I01, I09, I12, I17, I20	12 months	Net zero energy building. Requires 100%+ on-site renewables. Similar to Passive House Plus/Premium concept.

The 7 Petals — 20 Imperatives Overview

Petal	Imperatives	Core?	Core Requirement Summary
🌍 Place	I01 Ecology of Place · I02 Urban Agriculture · I03 Habitat Exchange · I04 Human-Scaled Living	I01, I04	No build on greenfield/floodplain. Restore ecology toward Reference Habitat. No petro fertilisers/pesticides.
💧 Water	I05 Responsible Water Use · I06 Net Positive Water	I05	50% potable water reduction (new). No potable irrigation. All stormwater managed on-site.
⚡ Energy	I07 Energy + Carbon Reduction · I08 Net Positive Carbon	I07, I08	70% energy reduction (new). No combustion heating/cooling. 20% embodied carbon reduction. 105% on-site renewables for Net Positive. One-time offset of all construction embodied carbon.
🌿 Health + Happiness	I09 Healthy Interior Environment · I10 Healthy Interior Performance · I11 Access to Nature	I09, I10, I11	ASHRAE 62 ventilation. No smoking 25ft from openings. IAQ test 1–6 months post-occupancy. 90% CDPH-compliant materials. Views + daylight to 95% of regularly occupied spaces.
🔩 Materials	I12 Responsible Materials · I13 Red List · I14 Responsible Sourcing · I15 Living Economy Sourcing · I16 Net Positive Waste	I12, I13	Avoid Red List chemicals in 90% of materials. Declare labels, FSC wood (50%+), 20% from within 500km. 80% construction waste diverted.
⚖️ Equity	I17 Universal Access · I18 Inclusion	I17, I18	ADA/universal access. No blocking fresh air/sunlight/waterways. JUST labels. Diverse procurement.
✨ Beauty	I19 Beauty + Biophilia · I20 Education + Inspiration	I19, I20	Biophilic Design Exploration and Framework. Public art. One annual open building day. O&M Manual. LFA-credentialed team member.

🌍 PLACE PETAL — I01 Ecology of Place (C1) · I04 Human-Scaled Living (C2) SITE ▶

I01 — Ecology of Place (Core C1)

Prohibited sites: Pristine greenfield, wilderness, prime farmland, or floodplain (unless Exception granted).

Required: Document Reference Habitat (pre-disturbance ecological baseline). Demonstrate net positive ecological contribution. On-site landscape designed to mature toward Reference Habitat. Cultural and social equity assessment.

Zero tolerance: No petrochemical fertilisers or pesticides for ongoing landscape maintenance, including urban agriculture.

I04 — Human-Scaled Living (Core C2)

Projects in Transects L3–L6 must contribute to a walkable, human-scaled community. Requires contextual analysis of neighbourhood walkability, transit access, and local food systems. Projects must not rely on single-occupancy vehicle infrastructure as the primary access mode.

Transect system (L1–L6): L1=wilderness, L2=rural, L3=sub-urban, L4=general urban, L5=urban centre, L6=urban core. The Transect determines which Imperatives and Exceptions apply.

I02 — Urban Agriculture (Full LBC)

Two pathways — Pathway 1 (agriculture only) or Pathway 2 (reduced agriculture + weekly community food access):

Transect	Path 1: Agri only	Path 2: Agri + weekly access
L1 (Wilderness)	100% of Project Area	50% + weekly access
L2 (Rural)	50%	25% + weekly access
L3 (Sub-urban)	15%	7% + weekly access
L4 (General Urban)	5%	2.5% + weekly access
L5 (Urban Centre)	2%	1% + weekly access
L6 (Urban Core)	1%	0.5% + weekly access

Resilience food storage: Non-residential: 75% FTE × 3 days × 2,100 cal/person/day. Residential: 2-week supply for all occupants. On-site agriculture outside the growing season must be supplemented with stored food.

Agriculture types allowed: In-ground crops, raised beds, rooftop gardens, vertical walls, greenhouses, orchards, livestock, beekeeping, aquaponics, hydroponics, ethnobotanical gardens. Ornamental plants do NOT count.

I03 — Habitat Exchange (Full LBC)

For every project, a protected habitat area must be permanently set aside through an approved land trust. This acknowledges that all development — even LBC — has an ecological footprint.

Project Type	Required Habitat Offset
Standard projects	= Project Area OR 0.4 ha — whichever is GREATER
Affordable housing	= ½ Project Area OR 0.2 ha — whichever is greater

Conditions: Land must be part of or contiguous to ≥100 acres (40.5 ha) of intact, high-value ecosystem. Cannot be project property or land owned by project owner. Must be held in perpetuity by LTAC-accredited land trust. Priority given to land trusts in same region/country.

Single-family homes (Exception PL-010): May substitute 100 volunteer hours with an approved land trust in lieu of financial contribution.

Australian note: Trust for Nature (VIC), NSW Land Trust, and Bush Heritage Australia are appropriate land trusts. Ensure contiguity with existing reserves ≥100 acres.

💧 WATER PETAL — I05 Responsible Water Use (C3) · I06 Net Positive Water WATER ▶

I05 — Responsible Water Use (Core C3)

Typology	Potable Reduction
New Building	−50% vs baseline
Existing Building + Interior	−30% vs baseline
Affordable Housing	Handprinting pathway available

No potable water for irrigation — ever. All stormwater must be treated and managed on-site. Stormwater targets scale with climate change: design precipitation depths +15% for year 2100. Stormwater peak discharge controlled to pre-development hydrology for 2yr, 10yr, 25yr, 100yr events.

I06 — Net Positive Water

100% of project water needs from: captured precipitation, natural closed-loop systems, or recycled water. No chemicals for treatment (chlorine/chloramine/hypochlorite banned). UV disinfection permitted.

Greywater + blackwater: On-site treatment and reuse, or municipal connection only if: biologically-based treatment, tertiary treatment, nutrient capture, same watershed discharge. Or handprinting pathway.

Resilience: Must store ≥1 gallon/FTE/day for 7 days emergency drinking water. Non-potable storage allowed if treatment method (filters/iodine) provided without mains power.

Non-potable end uses: Toilets, urinals, irrigation, cooling tower makeup, laundry, equipment washing.

⚡ ENERGY PETAL — I07 Energy + Carbon Reduction (C4) · I08 Net Positive Carbon CRITICAL ▶

I07 — ENERGY + CARBON REDUCTION REQUIREMENTS

⚠

New construction: zero combustion. No new combustion-based heating or cooling systems in new buildings. Existing buildings may maintain existing combustion but cannot install new combustion equipment. Zero combustion is the direction of travel for all typologies.

Typology	Energy Reduction vs Baseline EUI	Embodied Carbon Reduction	Zero Ready
New Building	−70%	−20% primary materials (A1–A5)	EV wiring + renewable infrastructure
Existing Building	−50%	−20% (in-situ materials count toward reduction)	Advocate if interior scope
Interiors	−40%	Lower-than-industry-avg carbon for interior products	Written advocacy to owner
Landscape + Infrastructure	Site-specific	Not applicable	Pre-install wiring and connections

Baseline tool: Zero Tool (Architecture 2030) or EDGE (World Bank). EPD data from EC3, mindfulMaterials, or International EPD System.

EMBODIED CARBON — 20% REDUCTION CALCULATION

Embodied Carbon ReductionLCA stages A1–A5

% Reduction = [(Baseline CO₂e − Project CO₂e) / Baseline CO₂e] × 100 ≥ 20% Scope: Foundation + Structure + Enclosure (primary materials) Interior materials: must be below industry average (where EPD data available) Approved tools: Athena, One Click LCA, Tally, EC3, eTool, GaBi, BHoM LCATk

Example — 21% reduction achieved

Baseline: 340t steel + 270t concrete + 150t enclosure = 760t CO₂e
Project: 310t (green steel) + 200t (low-cement) + 90t (local enclosure) = 600t CO₂e
[(760−600)/760] × 100 = 21% ✓ (meets 20% threshold)

I08 — NET POSITIVE CARBON

105% On-Site Renewable Energy

All projects must produce 105% of total annual energy needs from on-site renewables (net annual basis). No combustion. Allowed sources: PV, solar thermal, wind, water microturbines, direct geothermal, hydrogen fuel cells from renewable electrolysis only.

RECs: Cannot be purchased to meet Net Positive. Must be owned/contracted for minimum 15 years. Third-party PV ownership allowed if contract ≥15 years and feeds project directly.

Resilience strategy: Building must be habitable for 1 week via batteries/storage, OR participate in community disaster support.

Embodied Carbon Offset (One-Time)

All construction embodied carbon (A1–A5 + construction energy) must be offset via:

Carbon-sequestering materials (e.g. FSC timber, biochar)
ILFI-approved carbon offset purchase (one-time at project completion)
Surplus renewable energy exported to grid can partially offset (10-year extrapolation)

Standard lifespan for calculations: 60 years.

Sub-metering mandatory for all buildings except single-family residential. Single-family must develop method to troubleshoot energy use.

🌿 HEALTH + HAPPINESS PETAL — I09 Healthy Interior (C5) · I10 Performance · I11 Nature IAQ + DAYLIGHT ▶

I09 — HEALTHY INTERIOR ENVIRONMENT (Core C5)

Full ASHRAE 62.1 (commercial) or 62.2 (residential) compliance — OR international equivalent
No smoking within buildings or within 25 feet (7.6m) of any building opening
Direct exhaust (not recirculated) from: chemical storage, copy rooms, bathrooms, kitchens
Healthy Indoor Environment Plan (HIEP): cleaning protocols, IAQ strategies, CO detector if any combustion or enclosed parking
Views to outside AND daylight access for 75% of regularly occupied spaces

I11 — ACCESS TO NATURE (Core C11)

Occupants must have regular, meaningful interaction with the natural environment. Biophilic design elements must be incorporated. Views to living nature preferred over hardscape. Indoor plants, water features, and natural materials count. Connection to place, climate, and ecological cycles must be demonstrable.

I10 — HEALTHY INTERIOR PERFORMANCE (Core)

Requirement	Threshold
IAQ Test	1–6 months post-occupancy OR RESET-certified continuous monitoring
Views + Daylight	95% of regularly occupied spaces (remaining 5% must have access path to daylight)
Interior products (VOC emissions)	90% by cost must meet CDPH v1.1-2010 or equivalent
Cleaning products	EPA Safer Choice label or GHS equivalent
Occupant control (non-residential)	≥2 of: operable windows (6 months/yr), temperature/airflow control, flexible sit-stand/sensory options
Occupant control (residential)	Operable windows for 100% of occupants

IAQ MAXIMUM CONCENTRATIONS (Table 10-1)

Pollutant	Max Concentration
Formaldehyde	27 ppb (same as WELL)
PM2.5	15 μg/m³
PM10	50 μg/m³
CO	9 ppm
CO₂	1,000 ppm (L3–L6: outdoor + 500 ppm)
Ozone	51 ppb
Radon	0.148 Bq/L (4 pCi/L)
Total VOCs (IAQ test)	See Table 10-2 individual compound limits

Continuous monitoring (RESET Air Standard) may substitute for spot testing for PM2.5, TVOCs, CO, CO2. Single IAQ test still required for pollutants not monitored continuously.

🔩 MATERIALS PETAL — I12 Responsible Materials (C6) · I13 Red List · I14–I16 Sourcing/Waste RED LIST ▶

I13 — THE RED LIST (Core C6) — Chemical Classes BANNED

☠

90% of all project materials by cost must be free of Red List chemical classes. Disclosure at 100 ppm (0.01%) required. The Red List is organised by chemical class — CASRN numbers govern compliance. Updated annually each January.

Red List Chemical Class	Common Examples
Halogenated Flame Retardants (HFRs)	TBBPA, HBCD, PBDEs in insulation/electronics
PVC / Chlorinated Polymers	PVC pipe, CPVC, PVDC, chloroprene
PFAS / PFCs	Teflon coatings, waterproofing, stain resistance
Phthalates	Plasticisers in vinyl flooring, cables
Bisphenol A (BPA) + analogues	Polycarbonate, epoxy coatings
Formaldehyde (added)	Urea-formaldehyde in composite wood
Toxic Heavy Metals	Arsenic, cadmium, chromium VI, lead, mercury
CFCs + HCFCs	Refrigerants, spray foam blowing agents
Asbestos	Legacy insulation, floor tiles
PCBs (Polychlorinated biphenyls)	Old transformers, caulk in older buildings
Antimicrobials (with health claim)	Triclosan in furniture/coatings
Alkylphenols	Nonylphenol ethoxylates in surfactants
Organotin compounds	PVC stabilisers, antifouling coatings
Short/medium-chain chlorinated paraffins	Metal working fluids, PVC additives
VOCs (wet-applied products)	Limited not banned — CARB/SCAQMD limits apply

COMPLIANCE PATHWAYS

Documentation Level	Accepted Proof
Best: LPC Certified or Declare label	Active Declare “Red List Free” or “Red List Approved” — no additional docs needed
Good: HPD	Health Product Declaration with 100% disclosure to 100 ppm
Minimum: Ingredients list	100% ingredients + residuals at ≥100 ppm with CASRNs. Written manufacturer confirmation.

I12 — RESPONSIBLE MATERIALS (Core C6)

Declare labels: 1 per 200 m² gross area, up to 20 products from 5 manufacturers
Living Product Challenge: 1 LPC-certified product required (non-residential)
Wood: 50% FSC, salvaged, or on-site harvest. Remainder from low-risk sources.
Local sourcing: 20%+ of materials construction budget from within 500 km
Construction waste: 80% diverted from landfill
Ongoing operations: Dedicated recycling + compostable food scraps infrastructure

I15 — LIVING ECONOMY SOURCING (Full LBC)

20%+ of all materials by cost within 500 km of site. Declare products and salvaged materials may be counted at 2× cost. Manufacturer location = final fabrication/assembly.

I16 — NET POSITIVE WASTE (Full LBC)

80% construction waste diverted. Deconstruction plan required. All salvaged materials tracked. Permanent on-site collection infrastructure for recyclables and compostables.

⚖️ EQUITY PETAL — I17 Universal Access (C7) · I18 Inclusion (C8) SOCIAL JUSTICE ▶

I17 — Universal Access (Core C7)

All primary transportation/infrastructure and external public spaces equally accessible to all — including homeless and all socioeconomic backgrounds
Transects L3–L6 (except single-family): enhance public realm through street furniture, art, gardens, benches
ADA + ABA compliance (or international equivalent)
No blocking fresh air, sunlight, or natural waterways for any adjacent property or community
Waterway access: ≥3m wide public throughway to natural waterways (≥1.5m for single-family)
Solar shading: must not significantly impact majority of adjacent building occupants — demonstrate via winter solstice 10am–2pm shadow diagrams

I18 — Inclusion (Core C8)

JUST Labels: Minimum 2 project team organisations with JUST labels (integral design + construction roles). Additional 5 organisations complete JUST Self-Assessment.

THEN choose one of:

Option A — Diverse Stakeholder Involvement:

20% of design + construction contracts with JUST-certified or MWDBE organisations
10% of maintenance contracts with JUST-certified or MWDBE
10% of GC’s contracts/person-hours in registered apprenticeship or workforce development programs

Option B — Charitable Donation: 0.1% of total project cost to regional community-based nonprofit focused on equity and inclusion.

✨ BEAUTY PETAL — I19 Beauty + Biophilia (C9) · I20 Education + Inspiration (C10) BIOPHILIA ▶

I19 — Beauty + Biophilia (Core C9)

Mandatory: One full-day Biophilic Design Exploration producing a Biophilic Framework and Plan covering:

Environmental Features, Light and Space, Natural Shapes and Forms
Natural Patterns and Processes, Evolved Human-Nature Relationships
Place-Based Relationships — connecting to specific site ecology, climate, culture

Must include: Meaningful public art. Design features solely for human delight (must add value beyond building function). Celebration of culture, spirit, and place. Historical, cultural, and ecological study of site.

Biophilic design elements must provide additionality — cannot claim credit for features already required by another Imperative (e.g., windows for daylighting alone don’t satisfy biophilia unless intentionally designed for biophilic quality beyond minimum)

I20 — Education + Inspiration (Core C10)

1 Open Building Day per year — publicly accessible tour, free or low-cost. Must include all portions of the project (secure areas may restrict access but must provide educational equivalent). Single-family: 1 open day during performance period minimum.
O&M Manual (living document) — system set points, operation + maintenance, procurement guidelines, performance targets referencing specific LBC requirements. Starts early in design.
LFA (Living Future Accreditation) — at least one integral project team member (Architect of Record, MEP Engineer, etc.) must hold active LFA credential when project submits for audit.
Case study content for each targeted Imperative (uploaded to ILFI website at certification)
Educational website, brochure, and on-site interpretive signage (not required for single-family residential)

LBC 4.0 vs NCC 2022 vs Passive House vs WELL — Integration Comparison

⚡

LBC is the ceiling, NCC is the floor. Every LBC-certified building automatically exceeds NCC 2022 by a massive margin. The challenge is not double-compliance — it’s finding the regulatory pathway in Australia to permit LBC innovations (on-site water treatment, composting toilets, greywater reuse, rainwater to potable) which are often prohibited or restricted under State plumbing codes.

Requirement	NCC 2022	Passive House	WELL v1	LBC 4.0	LBC > others?
Energy efficiency	7★ NatHERS / 70% whole-of-home cap	≤15 kWh/m²a heating demand	ASHRAE 55 thermal comfort	−70% vs baseline EUI (new)	COMPARABLE to PH
Renewable energy	20% roof clear (J9D5)	PH Plus: ≥60 kWh/m²a	Not required	105% on-site renewables (I08)	LBC FAR EXCEEDS ALL
Embodied carbon	Not regulated	Not regulated	Not regulated	−20% primary materials + offset ALL construction carbon (I07/I08)	LBC ONLY standard
Water efficiency	Vol 3 (plumbing code only)	Not addressed	Water quality limits	−50% potable + 100% on-site supply (I05/I06)	LBC FAR EXCEEDS ALL
Red List materials	Not regulated	Not regulated	Partial (TVOC, formaldehyde)	90% by cost Red List free (I13)	LBC MOST RIGOROUS
IAQ testing	Not required	Not required	Performance verification (3rd party)	Mandatory post-occupancy test 1–6 months (I10)	LBC + WELL require testing
Biophilia	Not regulated	≥1 operable window per room	Biophilia Plan required (Feature 88)	Full-day Biophilic Design Exploration + Framework (I19)	LBC most comprehensive
Social equity	H8 accessible design	Not addressed	Accessible design (Feature 72)	JUST labels + diverse procurement + 0.1% donation pathway (I17/I18)	LBC unique requirement
Performance verification	NatHERS predicted + blower door	PHPP + blower door (actual)	Third-party site test	12 months ACTUAL performance required — no simulations accepted for final certification	LBC is performance-based

🇦🇺 LBC 4.0 in the Australian Context — Regulatory Barriers and Strategies AUSTRALIA ▶

LBC Requirement	Australian Regulatory Barrier	Strategy
I06 Rainwater to potable (Net Positive Water)	State health acts (NSW, VIC, QLD) typically prohibit rainwater to mains-connected potable supply without extensive approvals. SA + WA have better frameworks.	Seek State-specific exemptions or Living Building Pilot Program (used in Seattle-type programs). Engage WaterNSW/DHHS. Use Option 2 (municipal connection) or Option 3 (handprinting) if necessary. SA Part H9 most LBC-friendly jurisdiction.
I06 Composting toilets / on-site sewage	Volume 3 (PCA) and State plumbing codes mandate connection to municipal sewer in most urban areas. On-site systems require environmental permits.	Use NCC A2G2 Performance Solution pathway: demonstrate equivalent or better environmental performance. Environmental Protection Licences (EPA) may be required. Rural/peri-urban sites have significantly easier pathway via AS/NZS 1547 on-site wastewater systems.
I08 Net Positive + 105% renewables	Net metering limits vary by state. SA allows best export terms. NSW legacy FITS expired. VIC Solar Homes has caps.	Check DNSP (Distribution Network Service Provider) for export limits. Exception EC-012 (Off-Site Renewables) available for net-metering-limited projects. Battery storage + DNSP agreements as alternative to grid export.
I07 No new combustion (heating)	NCC allows and some States mandate certain gas connections (ACT had gas connections mandatory until recently — now reversed). VIC still has many gas-connected areas.	NCC 2022 fully permits all-electric buildings. LBC’s no-combustion stance is MORE stringent. Design all-electric from concept. ACT’s low-carbon grid makes this economically compelling.
I13 No PVC pipe	AS/NZS 3500 (Volume 3, PCA) typically defaults to PVC as standard specification. Some councils mandate PVC for stormwater.	Exception RL-005 (Red List + Code): document AHJ requirement, request variance, advocate for change. HDPE, copper, or polypropylene alternatives are technically acceptable. Many Australian projects have successfully substituted PVC with documented advocacy.
Performance Period	NCC requires design compliance only (NatHERS predicted performance). LBC requires 12 months actual operation.	LBC certification is applied for after the building is occupied — not at DA/building permit stage. Document both NCC compliance (for permit) and LBC performance (for certification) as parallel tracks. NatHERS certificate satisfies NCC; PHPP + measured data satisfies LBC.
eTool / Australian EPD data	ILFI-approved LCA tool eTool uses Australian environmental product data — ideal for LBC embodied carbon calculations in Australia.	Use eTool for Australian projects. Australian LCI data is built-in. Cross-reference with Building Product Declaration (BPD) Australia database for product-specific EPDs. EPD Australasia is the national EPD program operator.

Buildings for Human Health

WELL Building
Standard

The world’s leading building standard focused on human health. Seven concepts — Air, Water, Nourishment, Light, Fitness, Comfort, and Mind — rigorously measurable and third-party certified.

ℹ

About WELL v1: 100 features across 7 Concepts (Air, Water, Nourishment, Light, Fitness, Comfort, Mind). Focused entirely on occupant health and wellbeing — not environmental sustainability. Certified by GBCI (same body as LEED). Third-party Performance Verification by a WELL Performance Testing Agent required. Recertification every 3 years minimum. Designed to complement — not compete with — LEED, Green Star, and Passive House.

100

Total features (7 Concepts)

New & Existing Buildings

41

Preconditions (mandatory for Silver)

Must ALL be met

59

Optimizations (optional)

40%=Gold · 80%=Platinum

3

Years recertification cycle

Performance degrades over time

7

Concepts (wellness domains)

Air/Water/Nourishment/Light/Fitness/Comfort/Mind

3

Project types

New+Existing Bldg · Interiors · Core+Shell

Certification Levels

Level	SILVER	GOLD	PLATINUM
Preconditions required	`All applicable`	`All applicable`	`All applicable`
Optimizations required	`None`	`40% of applicable`	`80% of applicable`
NEB total features	41 P + 0 O	41 P + ~24 O	41 P + ~47 O

Project Types & Feature Counts

Project Type	Preconditions	Optimizations	Total	Best For
New and Existing Buildings (NEB)	41	59	100	Full owner-occupied buildings ≥90% same operator
New and Existing Interiors (NEI)	36	62	98	Tenant fitouts, partial floor occupancy
Core and Shell (C&S)	26	28	54	Base building infrastructure (≥75% tenant-occupied)

💨 Concept 1 — AIR · Features 01–29 (29 P/O) CRITICAL FOR GREEN BUILDING ▶

Air is the most technically demanding WELL concept and most relevant to green building design. 11 Preconditions must be met by all project types (where applicable). Key thresholds:

PRECONDITION 01 — AIR QUALITY STANDARDS (all project types)

Pollutant	WELL Limit	Notes
Formaldehyde	< 27 ppb	Measured during Performance Verification
Total VOCs (TVOCs)	< 500 μg/m³	Covers off-gassing from materials, furniture, cleaning products
Carbon monoxide (CO)	< 9 ppm	Combustion product — links to Feature 24 Combustion Minimization
PM₂.₅	< 15 μg/m³	Fine particulate — MERV 13 filter required (Feature 05)
PM₁₀	< 50 μg/m³	Coarse particulate
Ozone (O₃)	< 51 ppb	Also controls operable window opening (Feature 19)
Radon	< 0.148 Bq/L (4 pCi/L)	Lowest occupied floor at or below grade only

PRECONDITION 03 — VENTILATION EFFECTIVENESS

Part 1: Ventilation Design

Comply with ASHRAE 62.1-2013 (Ventilation Rate Procedure, IAQ Procedure, or Natural Ventilation Procedure). Or demonstrate ambient air within 1.6 km meets EPA NAAQS for 95%+ of hours.

Part 2: Demand Controlled Ventilation (DCV)

For spaces ≥46.5 m² with density >25 people/93 m²: DCV system must keep CO₂ < 800 ppm at 1.2–1.8m above floor. Alternatively, operable windows + demonstration of natural ventilation achieving same limit at maximum occupancy.

PRECONDITION 04 — VOC REDUCTION (materials)

Category	Standard Required	Applies To
Interior paints & coatings	CARB 2007 SCM or SCAQMD Rule 1113 (VOC content) OR 90%+ meet CDPH Standard Method v1.1	All newly applied
Adhesives & sealants	SCAQMD Rule 1168 OR 90%+ meet CDPH Standard Method v1.1	All newly applied
Flooring	CDPH Standard Method v1.1-2010 (emissions)	All newly installed
Thermal & acoustic insulation	CDPH Standard Method v1.1-2010 (emissions)	All newly installed (excl. ducts)
Furniture & furnishings	ANSI/BIFMA e3-2011 M7.1 OR CDPH Standard Method v1.1	≥95% by cost of new purchases

PRECONDITION 05 — AIR FILTRATION

✓

MERV 13 minimum for outdoor air filtration in recirculated air systems. Must have rack space for future carbon filters. Maintenance records submitted to IWBI annually. Note: WELL Feature 05 Part 2 = MERV 13; Passive House requires F7 intake filter (≈ MERV 13–16) — these are well-aligned.

KEY AIR OPTIMIZATIONS

Feature	Key Requirement	Type
13 Air Flush	4,266 m³ OA per m² floor area pre-occupancy (or 1,066 + 3,200 split)	O
14 Air Infiltration Mgmt	Envelope commissioning per ASHRAE Guideline 0-2005 — blower door equivalent	O
15 Increased Ventilation	Exceed ASHRAE 62.1 OA rates by 30% in all regularly occupied spaces	O
16 Humidity Control	HVAC maintains RH 30–50% at all times (or modelled for 95% of biz hours)	O
17 Direct Source Ventilation	Chemical storage, bathrooms, printer rooms: exhausted (not recirculated), self-closing doors	O
18 Air Quality Monitoring	Monitor 2+ of: PM, CO₂ (≤25 ppm resolution), O₃ — hourly, results to IWBI annually	O
19 Operable Windows	Every regularly occupied space has operable window; close if O₃>51ppb, PM₁₀>50μg/m³, or T±8°C of setpoint	O
24 Combustion Minimisation	Ban combustion appliances/heaters (gas stoves, fireplaces) — Optimization	O
25 Toxic Material Reduction	Limit PFCs, flame retardants, phthalates, isocyanate-PU, urea-formaldehyde	O

💧 Concept 2 — WATER · Features 30–37 PRECONDITIONS ▶

Feature	Parameter	Limit	Type
30 Fundamental Water Quality	Turbidity	< 1.0 NTU	P
30 Fundamental Water Quality	Total coliforms (incl. E.coli)	Not detected	P
31 Inorganic Contaminants	Lead	< 0.01 mg/L	P
	Arsenic	< 0.01 mg/L	P
	Antimony	< 0.006 mg/L	P
	Mercury	< 0.002 mg/L	P
	Nickel	< 0.012 mg/L	P
	Copper	< 1.0 mg/L	P
34 Public Water Additives	Residual chlorine	< 0.6 mg/L	P
34 Public Water Additives	Fluoride	< 4.0 mg/L	P
34 Disinfectant Byproducts	Total trihalomethanes	< 0.08 mg/L	P
34 Disinfectant Byproducts	Total haloacetic acids	< 0.06 mg/L	P
36 Water Treatment (O)	Activated carbon filter + sediment filter ≤1.5μm + UVGI or NSF cyst filter	All at point of consumption	O
35 Quarterly Testing (O)	Lead, Arsenic, Mercury, Copper tested quarterly	Records 3+ years	O

💡 Concept 4 — LIGHT · Features 53–63 CRITICAL ▶

☀

Key innovation in WELL Light: Feature 54 introduces Equivalent Melanopic Lux (EML) — a circadian-weighted metric measuring light as the body’s non-visual system (ipRGCs) perceives it. Peak sensitivity at ≈480nm (blue-teal). This is distinct from conventional photopic lux (peak sensitivity 555nm/green-yellow). High EML during business hours promotes alertness and healthy circadian entrainment.

Feature	Key Metric	Requirement	Type
53 Visual Lighting Design	Horizontal work plane illuminance	≥ 215 lux ambient (independently achievable). Task lights providing 300–500 lux on request if ambient <300 lux. Controls in zones ≤46.5 m².	P
54 Circadian Lighting Design	Equivalent Melanopic Lux (EML)	≥ 200 EML at 75%+ of workstations (vertical plane, 1.2m height, 9am–1pm). OR: ≥150 EML from electric lights at all workstations.	P
55 Electric Glare Control	Luminance / Shielding angle	20,000–50,000 cd/m²: shield α≥15°. 50,000–500,000: α≥20°. >500,000: α≥30°. Glare minimisation: UGR ≤19 or luminaires >53° above centre of view have <8,000 cd/m².	P
56 Solar Glare Control	Window shading	Interior/external blinds or variable opacity glazing (≥90% transmissivity reduction) for glazing <2.1m above floor. Upper glazing >2.1m: light shelves, micro-mirror film, or same blinds.	P (NEI/NEB)
58 Color Quality (O)	CRI Ra + R9	CRI Ra ≥ 80 AND R9 ≥ 50 for all electric lights	O
59 Surface Design (O)	Light Reflectance Value (LRV)	Ceilings: LRV ≥0.80 for ≥80% of area. Walls: LRV ≥0.70 for ≥50% of visible area. Furniture: LRV ≥0.50 for ≥50% of visible area.	O
61 Right to Light (O)	Distance to window	75% of regularly occupied space within 7.5m of view windows. 95% of workstations within 12.5m of atrium or exterior window.	O
62 Daylight Modelling (O)	sDA + ASE	sDA₃₀₀,₅₀% ≥ 55% of floor area AND ASE₁₀₀₀,₂₅₀ ≤ 10% of floor area	O
63 Daylighting Fenestration (O)	WWR + VT	WWR 20–60%. Upper glazing (>2.1m) VT ≥60%. Lower glazing VT ≥50%. Colour transmittance uniform (max 2× variation across 400–650nm).	O

🌡 Concept 6 — COMFORT · Features 72–83 ACOUSTIC + THERMAL ▶

THERMAL COMFORT REQUIREMENTS

Feature	Standard	Type
76 Thermal Comfort — Mechanically conditioned	ASHRAE 55-2013 §5.3 Standard Comfort Zone. PMV -0.5 to +0.5 for ≥80% of occupants.	P
76 Thermal Comfort — Naturally conditioned	ASHRAE 55-2013 §5.4 Adaptive Comfort Model	P
82 Individual Thermal Control — Free Address (O)	Buildings >200m²: thermal gradient ≥3°C across open workspaces. 50% free-address workstations.	O
83 Radiant Thermal Comfort (O)	Hydronic or electric radiant systems meeting ASHRAE 55. For ≥50% of occupied floor area.	O

ACOUSTIC REQUIREMENTS

Feature	Limit	Type
74 Exterior Noise Intrusion	≤ 50 dBA from outside (unoccupied, within 1hr of business hours)	P
75 Mech. Equipment Sound	Open office: NC ≤40. Enclosed office: NC ≤35. Conference: NC ≤30	P
78 Reverberation Time (O)	Conference rooms: RT60 ≤0.6s. Open workspace: RT60 ≤0.5s	O
79 Sound Masking (O)	Open workspace: 45–48 dBA. Enclosed offices: 40–42 dBA	O
80 Ceiling NRC (O)	Open workspace: NRC ≥0.9. Conference: NRC ≥0.8 on ≥50% ceiling	O
81 Wall STC (O)	Enclosed offices: STC ≥45 (no masking) or ≥40 (with masking). Conference: STC ≥53	O

ERGONOMICS — Feature 73 (Precondition)

All computer screens adjustable in height and distance from user (Part 1)
30% of seated-height workstations must offer sit-stand capability (adjustable desk, desk-top riser, or paired fixed heights) (Part 2)
Workstation chairs: height + seat depth adjustable per HFES 100 or BIFMA G1 (Part 3)

🧠 Concept 7 — MIND · Features 84–100 WELLBEING + BIOPHILIA ▶

Feature	Requirement	Type
84 Health & Wellness Awareness	WELL Standard guide provided to all occupants. Health and wellness library accessible in building.	P
85 Integrative Design	Stakeholder charrette during design. WELL development plan. Stakeholder orientation post-occupancy.	P
86 Post-Occupancy Surveys	Annual occupant surveys on: air, water, thermal comfort, acoustics, lighting, ergonomics, amenities, org. support.	P (NEI/NEB)
87 Beauty & Design I	Features for human delight, cultural celebration, spirit, place, and meaningful public art integration.	P
88 Biophilia I — Qualitative	Biophilia plan covering: nature incorporation (environmental elements, lighting, space layout), pattern incorporation (nature’s patterns in design), and nature interaction (inside + outside building).	P (NEI/NEB)
89 Adaptable Spaces	Stimuli management: loud/quiet zones programmed by research. Privacy spaces. Workplace sleep support (rest areas, reclinable seating, privacy screen, sleep-support lighting, acoustic treatment).	O
90 Healthy Sleep Policy	Written policy: flexible hours, support for consistent sleep/wake schedules, education on effects of light, caffeine, and shift work.	O

🌿

Biophilia in practice: Feature 88 requires a documented biophilia plan — not just plants. It must show how the project incorporates nature through: (a) environmental elements (plants, water features, materials), (b) lighting (mimicking natural light cycles), (c) space layout (views to nature, natural ventilation pathways), and (d) nature’s patterns in design motifs (fractals, organic geometry). This aligns well with passive solar design principles already required by PH and NCC.

🏃 Concept 5 — FITNESS + Concept 3 — NOURISHMENT · Key Features ACTIVE DESIGN ▶

KEY FITNESS PRECONDITIONS (NEB)

Feature	Requirement
64 Interior Fitness Circulation	In 2–4 storey projects: ≥1 staircase within 7.5m of main entry, clearly visible before elevators, ≥1.4m wide between handrails. Point-of-decision prompts at all elevator banks.
65 Activity Incentive Programs	Written organizational policy actively encouraging regular physical activity for all occupants.

FITNESS OPTIMIZATIONS

Feature	Requirement
69 Active Transport	Bicycle storage (1 per 5 regular cyclists), showers/lockers for commuters
70 Fitness Equipment	Cardio + strength equipment accessible to all occupants
71 Active Furnishings	Standing desks prevalent. Active workstations (treadmill desks, cycling workstations) available.

KEY NOURISHMENT PRECONDITIONS (NEB)

Feature	Requirement
38 Fruits & Vegetables	Fresh produce available daily within 200m of the building (cafeteria, on-site, nearby outlet)
39 Processed Foods	No trans fats. Sodium limits on processed foods. Calorie labelling ≥1 item on menus.
40 Food Allergies	Written allergen-labelling policy for the 8 major allergens for all catered/on-site food
41 Hand Washing	Soap dispensers and single-use towels at all handwashing sinks
52 Mindful Eating	Communal eating space seating ≥25% of occupants simultaneously, with fridge, microwave, sink, utensils

WELL + NCC 2022 + Passive House — Integration Strategy

⚡

The triple-standard opportunity: A WELL-certified building can simultaneously achieve NCC compliance and Passive House certification. The standards are complementary — each addresses a different dimension: NCC = legal minimum (energy + safety), Passive House = ultra-low energy + comfort, WELL = occupant health + wellbeing. Understanding the overlaps and gaps enables efficient, non-redundant design.

Design Element	NCC 2022 Requirement	Passive House Requirement	WELL v1 Requirement	Strategy
Air filtration	J5 building sealing (no filter mandate)	F7 outdoor intake filter (~MERV 13–16)	MERV 13 minimum (Feature 05)	PH F7 = WELL MERV 13 ✓ one spec covers both
CO₂ / ventilation monitoring	J9D3 energy monitoring only (>500m²)	Not required but DCV recommended	DCV <800 ppm CO₂ (Feature 03 — P)	WELL adds CO₂ DCV requirement beyond NCC. Design in from HVAC concept.
Airtightness	≤10 m³/hr.m² @ 50Pa blower door (H6V3)	≤0.6 ACH₅₀ (16× more stringent)	Feature 14 (O): ASHRAE Guideline 0 envelope commissioning	PH blower door exceeds NCC + satisfies WELL Feature 14. Pursing PH = free WELL O credit.
Thermal comfort	F8/H4V5 condensation (AIRAH DA07). No PMV mandate.	ΔT ≤4.2K surface to air. PMV -0.5 to +0.5 recommended.	ASHRAE 55 Comfort Zone (Feature 76 — P). PMV implied.	PH internal comfort criteria substantially satisfy WELL Feature 76. Align PHPP modelling with ASHRAE 55 set points.
VOC / material emissions	F8P1 condensation/mould. No VOC mandate in NCC.	No specific VOC limits (envelope focus)	TVOC <500 μg/m³ + CDPH/CARB compliant materials (Features 01, 04 — P)	WELL is the primary driver of low-VOC specification. Specify CDPH/CARB compliant products — independent of PH or NCC.
Circadian / melanopic lighting	J7 IPD limits (efficacy-focused, not circadian)	Not addressed	200 EML at workstations (Feature 54 — P)	WELL is the sole driver. Design lighting for 200 EML vertical plane. Favour 4000–5000K LED during daytime hours with tunable controls for evening.
Acoustic limits	F7 STC 45 between SOUs (Class 2/3). No NC limits in NCC.	HRV noise: ≤25 dBA habitable rooms	50 dBA exterior intrusion (P). NC ≤40 open office (P). Optional STC walls.	WELL adds interior acoustic requirements beyond NCC. Coordinate early with mechanical and acoustic engineers.
Operable windows	H4V5 / F6 natural ventilation pathway	Occupant satisfaction: ≥1 operable window per room	Feature 19 (O): operable window every regularly occupied space	PH occupant satisfaction clause = WELL Feature 19. Design operable windows as standard — satisfies both.
Biophilia / views to nature	Not addressed	Not addressed	Feature 88 Biophilia Plan (P for NEB). Feature 61 Right to Light (O).	WELL-only requirement. Design large, operable windows (also PH solar gain strategy) + biophilic interior palette as integrated approach.

WELL Certification Process — Steps & Documents PROCESS ▶

CERTIFICATION PATHWAY

Register with IWBI via WELL Online — do this at design start
Determine project type (NEB / NEI / C&S) — sets applicable features
WELL AP (Accredited Professional) engagement recommended
Design integration — address all Preconditions in design documents
Documentation submission to GBCI (plans, specs, policies)
Performance Verification — on-site visit by WELL Performance Testing Agent (1–3 days). Air quality sampling, water testing, light measurement, acoustic testing, spot checks.
Certification awarded (Silver / Gold / Platinum)
Recertification required every 3 years minimum

PERFORMANCE VERIFICATION — WHAT GETS TESTED ON-SITE

Parameter	Method
Air quality (TVOC, HCHO, CO, PM₂.₅, PM₁₀, O₃, CO₂)	On-site sampling + 3rd-party lab analysis
Water quality (metals, organics, agricultural, additives)	Sample to accredited lab
Illuminance (lux, EML)	In-situ measurement at workstations
Glare (luminance, UGR)	Spot measurement or luminaire data
Acoustic (dBA, NC, RT60, STC)	In-situ acoustic measurement
Thermal comfort	Temperature, humidity, air velocity measurement
Material compliance (VOC)	Documentation review + spot-check

⚠

Key risk: Air quality testing is done in-situ after fitout. Off-gassing from non-compliant materials will fail Feature 01. Specify CDPH/CARB-compliant products at procurement stage, not as an afterthought.

Working with Nature

Permaculture
Design

Geoff Lawton’s PDC 2.0 — a complete design methodology rooted in ecological principles. Zones, sectors, patterns, water harvesting, soil regeneration, and the ethics of regenerative practice.

🌿

Permaculture is an ethical design science that mimics nature to supply all human needs whilst benefiting the environment. It integrates land, resources, people and the environment into mutually beneficial, no-waste, closed-loop systems. It covers agriculture, forestry, water harvesting, renewable energy, eco-building, waste management, animal systems, economics, and community development. Sustainability is the minimum goal — the aim is regeneration.

The Three Ethics — Foundation of All Decisions

🌍

Care of the Earth

All designs consider living and non-living things — enhance and preserve rather than deplete or degrade

🤝

Care of the People

Promotes self-reliance and community responsibility — avoid structures of exploitation or abandonment

♻

Return of the Surplus

Abundance returned to the earth (compost, animal feed) or shared — the system cycles and improves

📐

What is sustainability? A sustainable system produces as much energy as it consumes so there is enough to retain and replace that system over the lifetime of its components. For permaculturalists, this is the minimum goal. The aim is systems that not only regenerate but actually improve upon themselves — creating surplus that increases diversity and fertility.

📊 MODULE 1 — Introduction: Energy Audit & Design Process FOUNDATION ▶

Energy Audit — Transition from Conventional to Permaculture (3–8 Years)

A key insight of permaculture is the dramatic shift in energy ratios. Contemporary industrial agriculture runs at a 10:1 energy loss (inputs vs. outputs). A mature permaculture system with firewood and fuels can reach 1:120 energy gain.

Accounting Category	Year 1 (Conventional)	Year 4 (Transitional)	Year 8 (Permaculture)
1. Farm income	Subsidised, over-produced	Reducing dependency	Real profit, no subsidies needed
2. Input costs	High: machinery, fertiliser, biocides	Declining	Minimal — system self-feeds
3. Oil calories (inputs)	10:1 loss ratio	Approaching balance	1:10 to 1:120 gain ratio
4. Energy produced	Minimal on-farm	Growing	Fuel oils, firewood, food, biogas, solar, wind, micro-hydro
5. Soil condition	Degrading, erosion	Stabilising	Building — humus, minerals, nutrients increasing
6. Water storage	Runoff dominated	Improving retention	Catchments, dams, swales, infiltration
9. Soil biodiversity	Low	Recovering	High — diverse soil life and mass
12. Employment	Machinery-dependent	Mixed	Human-skill based — more jobs per hectare
13. Food quality	Low nutrient density	Improving	High nutrient density

The Permaculture Design Process — 5 Stages

Stage 1: Consideration Process

Gather data across all system inputs: climate & weather, landscape & geology, socio-economics & laws, human needs, ecological interactions, energy flows, ethics & principles, potential risks.

Stage 2: Selection Process

Select elements and techniques that work under site-specific environmental constraints. Include elements useful for inhabitants AND that benefit the environment and are true to the ethics.

Stage 3: Design and Assembly Process

Assemble and position elements on the landscape based on: frequency of use, element interactions, and initial considerations. Use natural patterns to conserve energy, resources, and maximise efficiency. Key elements: water access & storage → access roads & paths → existing structures → earthworks & infrastructure → plants & animals → buildings & structures → energy & fuel production → legal structures.

Stages 4 & 5: Observation, Evaluation & Maintenance

The design is continuously altered based on future observation. Once the system matures, only maintenance is required. Key principle: design is living — unfolding interactions between elements, landscape, climate, and future human needs continuously refine it.

🔑

Design sequence rule: Always address water first, then access routes, then building sites. Water is the most critical element — all other design decisions flow from it.

🧠 MODULE 2 — Concepts & Themes in Design: Yields, Cycles, Diversity, Niches DESIGN FOUNDATIONS ▶

⚖

Core law of permaculture design: Put back into the system what you take from it. This is how designs create a surplus and constantly improve their own conditions. The goal is to foster systems that sustain themselves by producing more energy than they consume — achieved with the least amount of change necessary for the greatest positive effects.

Resources vs Yields

Resources are inputs (sun, rain, animals, plants). Yields are the surpluses of the system — what remains after it has maintained itself. Unlike commercial agriculture, permaculture measures yields holistically: energy, nutrition, social life, and more. Yields = totality of what a space produces, not just one crop.

Cycles in Design

Cycles are how time is read in permaculture: sun cycles (heat/shade homes), moon cycles (plant/harvest/transplant), weather cycles (compost/irrigate). By recognising time patterns in nature, we can predict — not infallibly but with probability — what will happen within designs.

Function, Diversity & Stability

Nature is diverse even in harsh conditions. With diversity, individual elements have multiple functions that maintain stable systems. Each component supplies the needs of others and processes abundance in a uniquely beneficial way. Through diversity and balanced function, systems self-regulate, providing constant yield while adapting to new conditions.

Complexity & Connections

Permaculture integrates disciplines from renewable energy to eco-construction. Designers find as many beneficial connections between elements as possible, creating complex systems that become more stable through being linked to so much. If one thing fails, many are there to step in. The amount of connections in natural systems is uncountable — permaculture systems behave the same way.

🌀

Order & Chaos: A prize-winning lawn requires constant external inputs because there are so few connections — it will die or give way to nature without intervention. A mature rainforest looks chaotic but plants and animals are all playing specific roles. The goal is the “edge of order and chaos” — where wild productivity is still within reach but manageability hasn’t escaped us.

Niches — Physical Sites and Conceptual Moments

Niches don’t just fill a physical space — they also operate on schedules (a day, a season, several years). Both space and time niches must be considered in designs. Physical niches include: vertical structures in space, aspects (direction things face), landscape zones, different soil types, varying water depths, degrees of slope, and patterns of flow.

Food Web — Pyramid vs Reality

Today’s food supply is presented as a pyramid (humans atop, then animals, insects, plants). In reality, things are more web-like: humans eat plants and insects, insects eat animals and plants, plants feed on the decaying of everything. Animals are integral to a self-maintaining ecosystem — they quickly convert inedible biomass into fertility, till, fertilise, clear, and maintain systems.

Designing to Catch and Store Water

Harvest water on high ground first — that is where it has highest energy potential and can be moved downhill by gravity for free. Rather than flowing straight down slope, move water slowly along contour lines with periodic storages at strategic locations. This supports tree and plant growth, which stores solar energy and pacifies water flows — fewer floods, fewer droughts, broader storage capacity on lower slopes.

📐 MODULE 3 — Methods of Design: Zones, Sectors, Guilds, Flow Diagrams DESIGN METHODS ▶

🔍

Design begins with analysis: List components to be included (what is already there), consider how best to put them together, think largely about connections between components so arrangements create mutually beneficial environments for humans, animals, plants, and buildings.

Zoning System — Energy Concentrated at Centre

Zone	Description	Size / Intensity
Zone 0	Home — locally sourced, uses natural components (sun, wind, plants) to moderate climate	Centre of all activity and origination of projects
Zone 1	Highly trafficked area around home — very controlled, most food per sq ft	~¼ to ½ acre; 25+ planned species
Zone 2	Food forests, main crop gardens, small-scale animal systems; more natural process	1–2 acres surrounding Zone 1
Zone 3	Grazing pastures, large windbreaks, major woodlots, hardy trees	Can get much larger
Zone 4	Loosely managed wild forest; fungi or lumber production	Extremities of acreage
Zone 5	Intentionally undisturbed wilderness — learn from it; full expression of local natural systems	Extends outward into larger wilderness

Sectors — External Energy Mapping

Zones yield to energy sectors and patterns of use. Sectors include: midwinter/midsummer sun paths, wind entry directions, fire threat corridors, unpleasant smells or views, flood-prone areas, frost hollows. Design with sectors accounted for — use elements to either accept or block the energy. Each element performs multiple functions (supply crop, block wind, provide shade); each function is performed by multiple elements.

Guilds — Plants, Animals, Elements Working Together

Guilds are congregations of plants, animals, and elements that provide assistance for one another. Often designed around a central element (e.g. a large fruit tree). That tree benefits from: mineral-mining plants, pest-repelling plants, soil-protecting groundcovers, nitrogen-fixers, frost/sun blockers, and later animal elements (chickens to scratch/fertilise, ducks for snails, bees to pollinate).

Broad Humid Landscape — Best House Site

Best house site: mid-slopes, just below the key/inflection point, between night condensation mists and winter frost line. High dam for gravity-fed water; forest uphill (convex slopes) stabilises landscape and protects house. Diversion drain at base of steep slope pushes runoff away. Productive gardens + food forests on concave slopes below key point.

Urban Garden Design

Urban sites can include: perimeter trees (deciduous = winter sun / summer shade), small productive ponds, mandala vegetable gardens, vine crops, small animal enclosures (bees, chickens). Roofs for solar + rainwater catchment. All five zones apply even on tiny urban sites — Zone 5 may be just one large existing boundary tree housing birds.

Working With Time — Succession Strategy

Natural successions lead to forests. Design into systems all elements to move quickly but with the same stability: fast groundcovers → perennial covers with nitrogen-fixing trees → permanent fruit and nut trees. In complete systems, weeds are not a problem — fill all niches with desired plants from the start. Small trials first in Zones 1 & 2; extend to larger systems based on feedback.

🌀 MODULE 4 — Pattern Understanding: Shapes, Edges, Flow, Fractals DESIGN LANGUAGE ▶

🔢

Patterns are events of form created by pressure between two or more media (wind + water, water + sand). They occur in familiar core arrangements: waves, spirals, lobes, branches. Energy flows that move through these patterns supply huge design potentials. Pattern is central to design; design is central to permaculture.

Edges — Boundaries Enhance Productivity

Boundaries are places of friction that produce change. The ecotone between grassland and forest is vastly more diverse and productive than either alone — energies, resources, inhabitants, and flows merge. In permaculture, we enhance shapes to create more edges for more interactions. Example: a crenelated pond border has far more perimeter (edge habitat) than a smooth circle of the same area — shrimp, crayfish, insects, aquatic plants thrive in edge pockets.

Toroidal / Branching Patterns

The torus (3D Overbeck jet) occurs throughout natural systems — mushroom caps, tree forms (trunk expanding to branches above and roots below), Earth’s electromagnetic field. Branching patterns (rivers, trees, lungs, lightning) operate fractally: larger, fewer branches = efficient for concentrated energy flows; smaller, more numerous branches = ideal for collecting and releasing. This guides pathway design within properties.

Flow Patterns

Flow includes water, gases, airstreams, and even solid formation. As velocity increases, flows may wave or spiral until too much velocity creates chaos. Prior to chaotic events, flows are usefully measurable and predictable. Life forms adapt to the forces around them — seagull wings are shaped by wind to keep the bird aloft. Growing a windbreak shaped like an airfoil smoothly lifts damaging winds over a housing site.

Traditional Cultures and Pattern

Traditional cultures managed land for centuries by observing natural patterns. Stable systems: Hawaiian Ahupua’a, Mexican chinampas, date palm oases, circular swidden in tropical forests, wet terraces of SE Asia, pannage systems in Europe, Australian Aboriginal seed crop systems. Knowledge embedded in songs, tattoos, star navigation, shadow calendars (Anasazi 18.6-year moon cycle).

Events in Time — Pulse and Cycle

Natural events tend to happen in pulses — cycles of ebb and surge (agricultural cycles: daily, seasonal, annual, decadal). By linking to natural cycles we can grow forms, save energy, and create functional patterns. A seed is part of the pattern that becomes a tree; the tree part of a pattern that becomes fruit and another generation of seed. Looking forwards and backwards in time over our gardens helps us take better advantage of each succeeding cycle.

🌤 MODULE 5 — Climatic Factors: Climate Zones, Latitude, Wind, Radiation, Precipitation SITE ANALYSIS ▶

🌐

Knowing how to understand climate is integral to creating an effective, efficient design for every unique site. The module explores how altitude, latitude, large bodies of water, and distance inland alter the climatic profile of a region, country, and particular piece of property.

Three Major Climatic Zones

Zone	Sub-categories	Characteristics
Tropics	Equatorial, Wet/Dry, Dry, Subtropics	High heat and moisture; plants overwhelmed by sun intensity — use smaller fields with productive shade trees (papaya, fruiting palms)
Temperate	Deep snow, little snow, no snow, Mediterranean	Subpolar: shorter seasons but efficient (longer days, low-light photosynthesis, fertile soils after long winter rest) — larger crop fields possible
Arid	Evaporation exceeds precipitation	Deserts — small gardens with overstory trees to handle heat + evaporation; every drop of water critical

Altitude Effect

Every 100 m of altitude increase = temperature behaves as if 1° of latitude further from equator (while daylight hours remain the same as sea level at same latitude). Allows cooler-climate crops to be grown at latitudes normally dominated by warmer species.

Precipitation

Precipitation is more than just rainfall — includes snowmelt, hail, direct condensation on surfaces, dew, and fog. Deforestation has a massive effect on total precipitation. Through intentional design, sites can harvest, store, and conserve water even in drier times.

Windbreaks

For maximum efficiency, windbreaks should be ~40% permeable and planted to multi-functional trees (food forest style, though focusing on support and biomass species). Well-placed windbreaks: save energy in homes, reduce animal stress, provide wildlife barriers, supply domestic animal forage, reduce erosion, increase garden yields. Up to 30% of land can be used for windbreaks without losing productivity overall.

Radiation (Solar Gain)

Solar gain is the biggest energy input to Earth. Understanding how light and heat operate is crucial for passive energy dwellings. Designers can heat homes with the sun, aid plant germination, and prepare for extreme events (frost, heat waves) using design techniques suited to each environment.

🌳 MODULE 6 — Trees & Their Energy Transactions: Biomass, Wind, Rain, Climate CRITICAL SYSTEMS ▶

🌲

Trees are the largest contributor of energy entering, absorbed, and dispersed by natural systems. They affect local climate, water flow, wind, light, soil, and all animal and insect life. Trees are central to ecosystems — not in a botanical sense but in their role as energy transaction engines.

Three Biomass Zones of a Tree

Crown & Trunk

Intercepts rain (diffusing erosive energy), lifts 60% of wind over the canopy, evaporates water (cooling air beneath), condenses moisture on leaves at night (warming air). Leaves up to 86% water — a single tree’s leaves can have up to 40 acres of surface area interacting with air. Sheds its own weight in biomass multiple times over its lifetime.

Detritus Zone

Area beneath the crown. Receives falling organic matter, decomposing into soil nutrients. Humus here holds up to ⅓ of its dry weight of extra water. Fungi and bacteria capture and hold even more. Nutrient-enriched rainwater (from washing leaf/branch surfaces) is absorbed here. Starting point for the soil nutrient cycle.

Root Zone

~90% of roots are within 60 cm of soil surface. Takes in nutrient-rich water from the detritus zone, uses the nutrients, and later transpires water back into atmosphere. Rich soils under trees can hold up to 30 cm of rain in 30 cm of soil — allowing it to slowly percolate into streams (enabling continuous flow, not just post-rain flow).

Trees and Wind

Effect	Detail
Wind adaptation	Trees reduce leaf surface area (aerodynamics), lean away from wind, spread roots wider for anchoring, thicken/strengthen trunks — observable in tree ring shape and thickness. Edge trees have thicker trunks than interior trees (more wind exposure).
Wind reduction	Trees lift ~60% of wind force up over canopy. The other 40% is absorbed by the forest, gradually slowed. At about 1 km into forest, wind disappears totally.
Temperature effects	Day: evaporation from crown cools air beneath. Night: leaves condense moisture, warming surrounding air. Clumps of trees upwind of a house keep it cool in summer and warm in winter.

Trees, Rain, and Atmosphere

Rain can erode dozens of tonnes of soil per hectare if unmitigated. Tree crowns diffuse rain impact, reduce erosive energy, and the forest replaces any minor erosion with new soil. For a healthy atmosphere, landscapes need to be ~70% forest. Trees warm cold air, dry humid air, and create conditions ideal for life. Forests introduce cloud-seeding bacteria into the air (promoting more rain). At sea-facing coasts, condensation from moist sea air can account for 86% of total precipitation in some areas. Deforestation destroys this effect and advances desertification.

💡

Design application: Tree placement is a powerful climate modifier. Leaf colour, light reflectivity, and canopy density all affect temperatures — these are factors in species selection. Thoughtful tree placement in designed systems has a huge impact on energy inputs needed to maintain comfortable shelter.

🧠 MODULE 2 — Concepts & Themes in Design: Yields, Cycles, Diversity, Niches DESIGN FOUNDATIONS ▶

⚖

Core law of permaculture design: Put back into the system what you take from it. This is how designs create a surplus and constantly improve their own conditions. The goal is to foster systems that sustain themselves by producing more energy than they consume — achieved with the least amount of change necessary for the greatest positive effects.

Resources vs Yields

Resources are inputs (sun, rain, animals, plants). Yields are the surpluses of the system — what remains after it has maintained itself. Unlike commercial agriculture, permaculture measures yields holistically: energy, nutrition, social life, and more. Yields = totality of what a space produces, not just one crop.

Cycles in Design

Cycles are how time is read in permaculture: sun cycles (heat/shade homes), moon cycles (plant/harvest/transplant), weather cycles (compost/irrigate). By recognising time patterns in nature, we can predict — not infallibly but with probability — what will happen within designs.

Function, Diversity & Stability

Nature is diverse even in harsh conditions. With diversity, individual elements have multiple functions that maintain stable systems. Each component supplies the needs of others and processes abundance in a uniquely beneficial way. Through diversity and balanced function, systems self-regulate, providing constant yield while adapting to new conditions.

Complexity & Connections

Permaculture integrates disciplines from renewable energy to eco-construction. Designers find as many beneficial connections between elements as possible, creating complex systems that become more stable through being linked to so much. If one thing fails, many are there to step in. The amount of connections in natural systems is uncountable — permaculture systems behave the same way.

🌀

Order & Chaos: A prize-winning lawn requires constant external inputs because there are so few connections — it will die or give way to nature without intervention. A mature rainforest looks chaotic but plants and animals are all playing specific roles. The goal is the “edge of order and chaos” — where wild productivity is still within reach but manageability hasn’t escaped us.

Niches — Physical Sites and Conceptual Moments

Niches don’t just fill a physical space — they also operate on schedules (a day, a season, several years). Both space and time niches must be considered in designs. Physical niches include: vertical structures in space, aspects (direction things face), landscape zones, different soil types, varying water depths, degrees of slope, and patterns of flow.

Food Web — Pyramid vs Reality

Today’s food supply is presented as a pyramid (humans atop, then animals, insects, plants). In reality, things are more web-like: humans eat plants and insects, insects eat animals and plants, plants feed on the decaying of everything. Animals are integral to a self-maintaining ecosystem — they quickly convert inedible biomass into fertility, till, fertilise, clear, and maintain systems.

Designing to Catch and Store Water

Harvest water on high ground first — that is where it has highest energy potential and can be moved downhill by gravity for free. Rather than flowing straight down slope, move water slowly along contour lines with periodic storages at strategic locations. This supports tree and plant growth, which stores solar energy and pacifies water flows — fewer floods, fewer droughts, broader storage capacity on lower slopes.

📐 MODULE 3 — Methods of Design: Zones, Sectors, Guilds, Flow Diagrams DESIGN METHODS ▶

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Design begins with analysis: List components to be included (what is already there), consider how best to put them together, think largely about connections between components so arrangements create mutually beneficial environments for humans, animals, plants, and buildings.

Zoning System — Energy Concentrated at Centre

Zone	Description	Size / Intensity
Zone 0	Home — locally sourced, uses natural components (sun, wind, plants) to moderate climate	Centre of all activity and origination of projects
Zone 1	Highly trafficked area around home — very controlled, most food per sq ft	~¼ to ½ acre; 25+ planned species
Zone 2	Food forests, main crop gardens, small-scale animal systems; more natural process	1–2 acres surrounding Zone 1
Zone 3	Grazing pastures, large windbreaks, major woodlots, hardy trees	Can get much larger
Zone 4	Loosely managed wild forest; fungi or lumber production	Extremities of acreage
Zone 5	Intentionally undisturbed wilderness — learn from it; full expression of local natural systems	Extends outward into larger wilderness

Sectors — External Energy Mapping

Zones yield to energy sectors and patterns of use. Sectors include: midwinter/midsummer sun paths, wind entry directions, fire threat corridors, unpleasant smells or views, flood-prone areas, frost hollows. Design with sectors accounted for — use elements to either accept or block the energy. Each element performs multiple functions (supply crop, block wind, provide shade); each function is performed by multiple elements.

Guilds — Plants, Animals, Elements Working Together

Guilds are congregations of plants, animals, and elements that provide assistance for one another. Often designed around a central element (e.g. a large fruit tree). That tree benefits from: mineral-mining plants, pest-repelling plants, soil-protecting groundcovers, nitrogen-fixers, frost/sun blockers, and later animal elements (chickens to scratch/fertilise, ducks for snails, bees to pollinate).

Broad Humid Landscape — Best House Site

Best house site: mid-slopes, just below the key/inflection point, between night condensation mists and winter frost line. High dam for gravity-fed water; forest uphill (convex slopes) stabilises landscape and protects house. Diversion drain at base of steep slope pushes runoff away. Productive gardens + food forests on concave slopes below key point.

Urban Garden Design

Urban sites can include: perimeter trees (deciduous = winter sun / summer shade), small productive ponds, mandala vegetable gardens, vine crops, small animal enclosures (bees, chickens). Roofs for solar + rainwater catchment. All five zones apply even on tiny urban sites — Zone 5 may be just one large existing boundary tree housing birds.

Working With Time — Succession Strategy

Natural successions lead to forests. Design into systems all elements to move quickly but with the same stability: fast groundcovers → perennial covers with nitrogen-fixing trees → permanent fruit and nut trees. In complete systems, weeds are not a problem — fill all niches with desired plants from the start. Small trials first in Zones 1 & 2; extend to larger systems based on feedback.

🌀 MODULE 4 — Pattern Understanding: Shapes, Edges, Flow, Fractals DESIGN LANGUAGE ▶

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Patterns are events of form created by pressure between two or more media (wind + water, water + sand). They occur in familiar core arrangements: waves, spirals, lobes, branches. Energy flows that move through these patterns supply huge design potentials. Pattern is central to design; design is central to permaculture.

Edges — Boundaries Enhance Productivity

Boundaries are places of friction that produce change. The ecotone between grassland and forest is vastly more diverse and productive than either alone — energies, resources, inhabitants, and flows merge. In permaculture, we enhance shapes to create more edges for more interactions. Example: a crenelated pond border has far more perimeter (edge habitat) than a smooth circle of the same area — shrimp, crayfish, insects, aquatic plants thrive in edge pockets.

Toroidal / Branching Patterns

The torus (3D Overbeck jet) occurs throughout natural systems — mushroom caps, tree forms (trunk expanding to branches above and roots below), Earth’s electromagnetic field. Branching patterns (rivers, trees, lungs, lightning) operate fractally: larger, fewer branches = efficient for concentrated energy flows; smaller, more numerous branches = ideal for collecting and releasing. This guides pathway design within properties.

Flow Patterns

Flow includes water, gases, airstreams, and even solid formation. As velocity increases, flows may wave or spiral until too much velocity creates chaos. Prior to chaotic events, flows are usefully measurable and predictable. Life forms adapt to the forces around them — seagull wings are shaped by wind to keep the bird aloft. Growing a windbreak shaped like an airfoil smoothly lifts damaging winds over a housing site.

Traditional Cultures and Pattern

Traditional cultures managed land for centuries by observing natural patterns. Stable systems: Hawaiian Ahupua’a, Mexican chinampas, date palm oases, circular swidden in tropical forests, wet terraces of SE Asia, pannage systems in Europe, Australian Aboriginal seed crop systems. Knowledge embedded in songs, tattoos, star navigation, shadow calendars (Anasazi 18.6-year moon cycle).

Events in Time — Pulse and Cycle

Natural events tend to happen in pulses — cycles of ebb and surge (agricultural cycles: daily, seasonal, annual, decadal). By linking to natural cycles we can grow forms, save energy, and create functional patterns. A seed is part of the pattern that becomes a tree; the tree part of a pattern that becomes fruit and another generation of seed. Looking forwards and backwards in time over our gardens helps us take better advantage of each succeeding cycle.

🌤 MODULE 5 — Climatic Factors: Climate Zones, Latitude, Wind, Radiation, Precipitation SITE ANALYSIS ▶

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Knowing how to understand climate is integral to creating an effective, efficient design for every unique site. The module explores how altitude, latitude, large bodies of water, and distance inland alter the climatic profile of a region, country, and particular piece of property.

Three Major Climatic Zones

Zone	Sub-categories	Characteristics
Tropics	Equatorial, Wet/Dry, Dry, Subtropics	High heat and moisture; plants overwhelmed by sun intensity — use smaller fields with productive shade trees (papaya, fruiting palms)
Temperate	Deep snow, little snow, no snow, Mediterranean	Subpolar: shorter seasons but efficient (longer days, low-light photosynthesis, fertile soils after long winter rest) — larger crop fields possible
Arid	Evaporation exceeds precipitation	Deserts — small gardens with overstory trees to handle heat + evaporation; every drop of water critical

Altitude Effect

Every 100 m of altitude increase = temperature behaves as if 1° of latitude further from equator (while daylight hours remain the same as sea level at same latitude). Allows cooler-climate crops to be grown at latitudes normally dominated by warmer species.

Precipitation

Precipitation is more than just rainfall — includes snowmelt, hail, direct condensation on surfaces, dew, and fog. Deforestation has a massive effect on total precipitation. Through intentional design, sites can harvest, store, and conserve water even in drier times.

Windbreaks

For maximum efficiency, windbreaks should be ~40% permeable and planted to multi-functional trees (food forest style, though focusing on support and biomass species). Well-placed windbreaks: save energy in homes, reduce animal stress, provide wildlife barriers, supply domestic animal forage, reduce erosion, increase garden yields. Up to 30% of land can be used for windbreaks without losing productivity overall.

Radiation (Solar Gain)

Solar gain is the biggest energy input to Earth. Understanding how light and heat operate is crucial for passive energy dwellings. Designers can heat homes with the sun, aid plant germination, and prepare for extreme events (frost, heat waves) using design techniques suited to each environment.

🌳 MODULE 6 — Trees & Their Energy Transactions: Biomass, Wind, Rain, Climate CRITICAL SYSTEMS ▶

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Trees are the largest contributor of energy entering, absorbed, and dispersed by natural systems. They affect local climate, water flow, wind, light, soil, and all animal and insect life. Trees are central to ecosystems — not in a botanical sense but in their role as energy transaction engines.

Three Biomass Zones of a Tree

Crown & Trunk

Intercepts rain (diffusing erosive energy), lifts 60% of wind over the canopy, evaporates water (cooling air beneath), condenses moisture on leaves at night (warming air). Leaves up to 86% water — a single tree’s leaves can have up to 40 acres of surface area interacting with air. Sheds its own weight in biomass multiple times over its lifetime.

Detritus Zone

Area beneath the crown. Receives falling organic matter, decomposing into soil nutrients. Humus here holds up to ⅓ of its dry weight of extra water. Fungi and bacteria capture and hold even more. Nutrient-enriched rainwater (from washing leaf/branch surfaces) is absorbed here. Starting point for the soil nutrient cycle.

Root Zone

~90% of roots are within 60 cm of soil surface. Takes in nutrient-rich water from the detritus zone, uses the nutrients, and later transpires water back into atmosphere. Rich soils under trees can hold up to 30 cm of rain in 30 cm of soil — allowing it to slowly percolate into streams (enabling continuous flow, not just post-rain flow).

Trees and Wind

Effect	Detail
Wind adaptation	Trees reduce leaf surface area (aerodynamics), lean away from wind, spread roots wider for anchoring, thicken/strengthen trunks — observable in tree ring shape and thickness. Edge trees have thicker trunks than interior trees (more wind exposure).
Wind reduction	Trees lift ~60% of wind force up over canopy. The other 40% is absorbed by the forest, gradually slowed. At about 1 km into forest, wind disappears totally.
Temperature effects	Day: evaporation from crown cools air beneath. Night: leaves condense moisture, warming surrounding air. Clumps of trees upwind of a house keep it cool in summer and warm in winter.

Trees, Rain, and Atmosphere

Rain can erode dozens of tonnes of soil per hectare if unmitigated. Tree crowns diffuse rain impact, reduce erosive energy, and the forest replaces any minor erosion with new soil. For a healthy atmosphere, landscapes need to be ~70% forest. Trees warm cold air, dry humid air, and create conditions ideal for life. Forests introduce cloud-seeding bacteria into the air (promoting more rain). At sea-facing coasts, condensation from moist sea air can account for 86% of total precipitation in some areas. Deforestation destroys this effect and advances desertification.

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Design application: Tree placement is a powerful climate modifier. Leaf colour, light reflectivity, and canopy density all affect temperatures — these are factors in species selection. Thoughtful tree placement in designed systems has a huge impact on energy inputs needed to maintain comfortable shelter.

💧 MODULE 7 — Water: Cycles, Earthworks, Dams, Purification CRITICAL FOR LBC I05/I06 ▶

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Core principle: Use water multiple times before letting it leave a site. The goal is to hydrate the landscape, enhance life and biodiversity, address water harvesting and storage, and deal with all soiled water productively. Soil can store far more water than streams — hydrated soil = drought-resistant landscape.

Water Storage — Dam Types

Dam Type	Location & Geometry	Best For
Saddle Dam	Ridgeline between two peaks; two walls impound water between hills	Catching water high in landscape; gravity-feed down
Ridge Point Dam	Boomerang-shaped wall at shallow ridges; relies on connected catchment	Expanding catchment area across broad ridges
Keypoint Dam	Just below keypoint in valley — where slope changes from convex to concave	Starting gravity-fed catchment systems; usually small but high-value
Valley Dam	Most common; position as high as possible on site	General water storage; foundation of most water systems
Contour Dam	Shallow landscapes; wall parallel to contour	Pairing with swales for food forests
Turkey Nest Dam	Flat land or hilltop; excavated circle with surrounding wall	Flat sites with no natural valley; acts as earthen storage tank
Check Dam	Stone or concrete across a flow; creates pool behind wall	Slowing & storing water in gullies; sediment capture

Earthen Dam Construction — Key Rules

Soil must have ≥50% clay content for wall construction
Dig a key trench down into clay subsoil where the wall centre will be anchored
Inside wall slope: 3:1 ratio (width to height). Outside wall: 2:1 ratio
Install oversized level-sill spillway beside the wall or via connected swale system
Spillway must allow ≥1 metre freeboard (permanently above water level)
Dress dam wall with stored topsoil; plant with grasses or non-taproot trees only
Ponds vs dams: Ponds = sub-surface excavations; dams = walls holding water back

Other Water Catchment Earthworks

Technique	What It Does	Best For
Swales	Long, level on-contour excavations that stop flow, spread water, allow soil infiltration	Reforesting slopes; extending dam catchments; using dam overflow
Gabions	Rock-filled cages that pacify water flows in floods; build fertile silt traps	Dryland & high-erosion areas; protecting against flood events
Diversion Banks	Direct runoff into storages without requiring tree installation	Increasing catchments without swale constraints
Rooftop Tanks	Concrete/zinc/plastic tanks collect roof water for drinking	Potable supply; size catchment + storage for year-round supply

Swale — Critical Clarification

A swale is NOT a drain — it is designed to slow, spread, and sink water into the soil. It runs exactly on contour (level) so water spreads evenly along its length. Trees are planted on the downslope berm. Swales are not appropriate in all landscapes — they fail in clay-dominant soils that don’t drain, on very steep slopes, or in high-rainfall saturated areas. Gravity-feed systems: catch water as high as possible so it flows down naturally without pumping energy.

Sewage, Greywater, and Natural Water Purification

System	How It Works	Output
Dry Composting Toilet (Humanure)	Lock up pathogens with carbon material	Compost — no water used
Bio-digester	Anaerobic digestion of waste	Methane (fuel) + liquid fertiliser
Greywater to toilet flush	Sink basin water plumbed to fill toilet tanks	Eliminates potable water for flushing
Septic + Reed Bed Filtration	Biological filtration through reed systems → leach field	Productive leach field; returns nutrients to landscape
Natural Swimming Pool	Water pumped from bottom through aquatic plant system, aerates back in. Solar-powered pump. Fish & crayfish assist cleaning.	Chemical-free water; life-rich system; indicator species show water quality
Reed Beds with Floating Plants	Plants filter water biologically — better than any machinery	Purified water; nutrient-sequestering biomass
Shellfish	Continuous water filtration; monitor acidity and toxicity levels	Dual-purpose: clean water + food production

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LBC I06 / WELL water connection: Permaculture water systems — composting toilets, greywater reuse, reed bed filtration, rainwater harvesting — directly implement LBC Net Positive Water (I06) strategies. All align with the LBC prohibition on chlorine treatment. The LBC water permitting challenge in Australia is precisely addressed by permaculture’s biological treatment approaches (septic + reed beds, constructed wetlands).

🪱 MODULE 8 — Soils: Classification, Nutrients, Biota, Erosion, Rehabilitation CRITICAL FOR ALL SYSTEMS ▶

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Without increasing the quantity and quality of soils, our systems cannot be sustainable. On average, soil is created at ~4 tonnes/acre/year — and lost to erosion at roughly the same rate. Modern agriculture with tilling loses ~30 tonnes/acre/year. Industrial annual agriculture can completely deplete soil in 60–70 years (the American dust bowl).

Soil Composition — Three Primary Components

Component	Characteristics	Design Use
Sand	Largest, heaviest particle; drains very readily	Sandy soils with low organic matter: improve with mulch and manure; acidic sands: add dolomite
Silt	Between sand and clay in size/weight; can be quite fine	Mid-range drainage; adjust with organic matter
Clay	Smallest, lightest; acts like glue, binding things together; ideal for compacting and shaping	Water-resistant clays: low ridges to control surface flow; add gypsum; or cover with 4 in. sand + pioneers

Primary Nutrients (NPK) — Natural Sources

Nitrogen (N)

Sequestered by legumes (Fabaceae) — symbiotic bacterial colonies on roots fix N into soil. When legumes die or are pruned, a flush of nitrogen-rich exudates is released. Not too much N in deserts — over-greening causes drought stress.

Phosphorus (P)

Tends to be deficient globally. Abundant in bird manure (including domestic birds). Palms and casuarina partner with fungi to fix phosphate into soil. Bird manure + casuarina/palm mulches are key desert P sources.

Potassium (K)

Often readily available — present in all green material. Also available via sea products, rock dust, manure, composting, and vermiculture. These are all natural ways of increasing mineral content and integrating outside nutrient sources into the system.

Soil pH Scale

pH scale centres on 7 (neutral). Each whole number = 10× more acidic or alkaline. Mostly determined by parent rocks and underlying mineral subsoil. As numbers move beyond 4 and 10, few lifeforms survive. Gardens function best at pH 6–7. Adjustments: add sulphur to alkaline soils; add lime or dolomite to acidic soils. Humid places often slightly acidic; new volcanic, coastal, and arid places tend alkaline.

Soil Food Web — The “Poop Loop”

Bacteria and fungi are the two primary soil decomposers. Bacteria: feed on N-rich organic materials (fresh green leaves, manures) — high in nitrogen. Fungi: specialise in carbon-rich materials (wood, fibrous/ligneous matter) — high in carbon, useful for carbon sequestration and long-term soil structure. Bacteria produce alkaline glues creating micro-aggregates; fungi wrap these into macro-aggregates → crumb structure. Protozoa, amoebas, and nematodes predate on bacteria and fungi, depositing concentrated nutrients in the root zone — the primary nutrient cycling mechanism in healthy soil.

40–200

Tonnes soil life per acre

Well-maintained conditions

25,000

Species per m² old-growth forest soil

Plus km of mycelium storing carbon

3–5 yrs

Degraded soil restoration timeline

With full soil food web present and active

Crumb Structure — Key to Healthy Soil

Healthy soils form a crumb structure allowing water and air to permeate beneath the surface — creating conditions for proper soil respiration. Produced by microorganisms; cannot be replicated by machinery. Lost with any soil disturbance: perennial plant removal, organic matter burning, compaction, chemical use, mechanised tillage. Maintain with: perennial systems, minimal soil disturbance, and deep mulches (150 mm layer of mulch over compost inoculation).

Reading Plants as Soil Indicators

Plant / Symptom	Indicates
Willows	Underground water source nearby
Deep-rooting trees in sandy soil	Clay deposits deep below surface
Thistles	Iron and copper lacking or locked up (overly acidic soil)
Ferns or blade grasses	Recently burned soils
Marsh grasses / reeds	Waterlogged soil
Plants with deep-tapping roots	Compacted soil
Strawberries	Acidic soil (they thrive there)
Brassicas	Prefer alkaline environments

Seed Pelleting and Erosion Control

Seed pellets preserve seeds until conditions are right for germination. Primary material: clay. Additions: rock dust, calcium, phosphate (balance nutrients), bitter tea/neem powder/green dye (protect seeds). Soil erosion prevention: add windbreaks, plant trees and fast-spreading grasses (stabilise with roots), create diversions and catchment systems. Rehabilitate degraded soils by ripping lines to open to air + water, planting with pioneer species, then chopping/grazing cycles over a year → spongy, rich soil.

🚜 MODULE 9 — Earthworks & Earth Resources: Dams, Swales, Machinery, Slopes LANDSCAPE SURGERY ▶

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Earthworks are rehabilitative landscape surgery. Well-planned earthworks can mitigate extreme climates, provide safe shelters, reduce energy needs, and repair landscapes. Permaculture relies on rehabilitative earthmoving to speed systems into stable production. Always plan and plot before machinery arrives.

Key Earthwork Principles

Always remove and set aside topsoil for reapplication after earthworks; use subsoil as earthworks material
Reapply topsoil immediately and plant densely with local cover crop varieties
Compacted dirt will settle after machinery work — allow for this in house sites
Drainage is crucial when creating house sites
Survey landscape, mark out plan, and confirm on site before machinery arrives — maps alone are insufficient

Machinery Selection

Blade machines (bulldozers, graders, wheel tractors + back blades): ideal for benching, terracing, levelling
Bucket machines (drotts, excavators): better for deep holes
Compactors (sheepsfoot rollers): necessary for stabilising roadbeds, dam walls, pathways, spillways

Earth Materials Reference

Material	Depth	Uses
Topsoil	<20 cm	Dark, full of organic matter and life — preserve and reapply
Peat	Up to 9 m	Rich organic material for soil amendment
Clay	0.5–6 m	Dam walls, pond liners, earthworks structures
Sand	Varies	Grinding powder, potting mix component
Gravel	Varies	Roads, drains, filters
Shingle	Varies	Road building, natural swimming pools
Slate / Boulders	Varies	Excellent building materials

Levelling Devices

Level information is needed for: spillways, swales, drains (with fall rate), house sites, roadways, dam sites. Devices: water/bunyip levels (clear tubing + two sticks); A-frame levels (3 pieces of wood, weighted hanging line); transit/dumpy levels (scope + marked staff); laser levels; simple pocket eye levels (assessment only, not survey).

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Planting after earthworks: After disturbing soil, plant immediately and densely with cover crops to prevent erosion and weed invasion. Add pioneers, clumpers, trees. Dam walls: stabilise with hairnet-root trees (willows, bamboo) — NOT taprooted species which can damage the wall. Steep back cuts: cultivate with net-and-pan systems.

🌴 MODULE 10 — The Humid Tropics: Soils, House Design, Polycultures, Land Management TROPICAL DESIGN ▶

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The humid tropics is a dynamic climate with heavy rains, shallow soils, many layers of life, and rapid decomposition. Rapid life cycles = great potential AND great capacity to damage the landscape quickly. Most biomass is held in living plants rather than soil — nutrient leaching is rapid when forest cover is removed.

Three Sub-Climates of the Humid Tropics

Sub-climate	Earth Coverage	Key Characteristics
Wet Tropics	~10%	Acidic soils (anaerobic from extensive rainfall); dense forests; no native large grazers; rainfall near-daily; rapid continuous growth; soils vulnerable when cleared
Wet/Dry Tropics	~15%	Dry clear winters; hot wet summers; large grasslands with diverse grazers; slightly more fertile soils (alkaline near deserts); most brittle climates poised to slip into desert are wet/dry tropics
Monsoon Tropics	~10%	Summer onshore winds bring serious rains; winter winds blow offshore; erratic but major rain events; dry deciduous forests; supports large human populations → deforestation risk

Tropical Soils — Key Priorities

Geologically old — leached of nutrients by precipitation and time
Create soil with green manures + nitrogen-fixing legumes (top priority)
Other amendments: rock dust, poultry manure, deep mulches (20–25 cm)
Apply compost frequently in small amounts rather than large seasonal doses
Termites and ants (not worms) are primary animal soil creators in tropics
Avoid clearing and burning — devastating to tropical soils and ecosystems
Traditional perennial polycultures dominated by palms continually replenish humus

Tropical House Design

Cooling elements essential: adequate shade, cool thermal masses, open to breezes
Design elements: shade houses, underground pipes, solar chimneys (direct airflow)
Kitchens should be outside or detached (heat source)
Houses don’t need to be sealed; orient to invite wind and leverage shade
Midday sun must never touch the walls
Steep roofs + walls in full shade (wet tropics)
Drinking water from metal or tile rooftops; dry composting toilets most sanitary

Tropical Earth-Shaping

Swales: install on slopes of 2–8° with hedgerows for stability. Mounds: form on flat, wet sites to increase drainage, or in wet/dry tropics alternate between mound tops (wet season) and pits (dry season). Narrow terraces: work best on steep slopes but break them up with treelines every few levels for stability. Wet terraces: require constant water input and carefully installed drainage; dry terraces: mulch heavily.

Tropical Polycultures — From Start to Finish

Begin on compacted grasslands. Start with water harvesting elements (gravity-fed). Plant fast-growing hardy tree legumes, fast-turnover groundcovers, mulch species to build biomass. Designed polycultures imitate the forest (extremely diverse, dominated by palms). Large polycultures should be simple guilds of low-maintenance, high-yielding crops tested from smaller complex village systems (up to 400 species). Palm species: planted in clumps around mulch pile, opening space for inter-cropping and grazing. Productive palms replaced individually as yields reduce (≤6% of plantation at a time).

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Hawaiian Ahupua’a model: Traditional Polynesian watershed management — forests on steep upper slopes, terraces cultivated as slopes flatten to ~15%, human settlements on flat elevated areas (protected from hurricanes/tsunamis), gardens moving towards waterline including aquaculture ponds and palms. Used top-down layering and long-term planning that worked for generations.

🏜 MODULE 11 — Dryland Strategies: Water Harvesting, Settlement, Desert Vegetation ARID DESIGN ▶

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Primary design strategy in drylands: reduce evaporation. In deserts, 88% of water is lost to evaporation and runoff. A designer’s objective is to harvest this water and store it effectively — using it to establish plants and trees which will reduce evaporation further by providing shade and adding moisture to the air locally.

Dryland Conditions

Temperature Patterns

Heat peaks 12:00–15:00; drops quickly after sundown; coldest just before dawn. Soil holds more heat than air but effect is less dramatic deeper — little effect at 30 cm below surface; virtually none at 2 m. Humidity in dryland soils increases with depth; potentially complete saturation at only 20 m below surface.

Dryland Soils

Tend to be alkaline, especially near waterways. High nutritional content but minerals inaccessible due to high pH. Detect trace mineral absence via leaf analysis; address with foliar sprays. Lower pH with sulphur and mulch pits. Biocides extremely dangerous in desert climates — lack of water + decomposing matter means they persist and concentrate in water tables.

Three Desert Formation Types

Ergs — sand dune formations
Hamada — rocky pavements with large scattered boulders
Regs — extensive gravel landscapes

Desert Landscape Features

Scarps & Wadis: fault-line fractures; water flows down cliffs, gathers in wadis, empties into plains (leaving salt). Slow flows with concrete/stone dams + low rock walls.
Inselbergs (dome rocks): produce 100% runoff — harvest with concrete gutters
Sand dunes: can have water lenses within; stabilise by adding vegetation
Gilgais: small features from clay swelling/shrinking
Flood-outs: continually widening valleys; become gullies when overgrazed

Water Harvesting in the Drylands

Water must contain <700 ppm salt. Catch freshwater before it mixes with salty water below, or before running off hard surfaces (which pick up salt concentrations). System stability target: 70–80% of landscape to forestry + water harvesting; 20–30% integrated crop production.

Technique	Application
Rooftop catchment → tanks/sealed wells	Drinking water supply; 1 mm rain on 1 m² hard surface = 1 litre water
Swales	Spread water over kilometres, hydrating landscape; unlike dams can reach permanent springs over time
Drip irrigation (beneath mulch)	Most efficient method; minimises evaporation; reduce “clothesline effect” first with windbreaks
Ollas (buried unglazed pots)	Slowly weep water into soil at root level
Reed beds	Clean greywater with minimal evaporative losses
Dry composting toilets	Significantly reduce household water consumption at point of use
Qanats	Underground irrigation channels bringing constant flow to surface without a pump (recharged systems)

Dryland Settlement Design

Design for the worst years; resist over-expansion in good years. Position settlements in foothills to catch rain runoff from upslope. A tree belt 300–400 m wide should be planted as shelter (irrigated with greywater) — it also supplies fuel, mulch, forage, and fodder. Fruit trees cultivated on swales within the belt. Dust storm mitigation: seal roads along wind lines, fence them, establish windbreaks, pit and vegetate open landscapes.

Desert Vegetation — Trees First

Trees are valuable functionally before any yield of fruit, forage, or seed. Systems should only be extended with time-tested trees. Nurseries are vital — have trees ready when climatic conditions are most favourable. Plant at coolest time of year, at coolest time of day, after rain events. Key desert fruit trees: date palms, olive, fig, pomegranate, citrus, mulberry, guava, carob, quince, grape, apricot. Wide swales (5–10 m) with compost pits every 10–20 m can act as nuclei for desert forests using nursery-grown pioneer trees.

🌨 MODULE 12 — Humid Cool to Cold Climates: Buildings, Food Systems, Fire RELEVANT AU: Zones 6–8 ▶

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Applies to: Melbourne (Zone 6), Canberra/ACT (Zone 7), Tasmania, alpine regions. Characteristics: rainfall exceeds evaporation, frosts and fogs common, coldest period averages below freezing, warmest period averages ≥10°C. Summers dry and hot, winters wet and cold. Heating and water consume ~80% of energy used in this climate.

Passive Building Design — Cool/Cold Climate

Strategy	Implementation	NCC/PH Alignment
Settlement orientation	Site on sun-facing hillsides; streets East–West; housing North–South orientation	Aligns with NatHERS solar gain optimisation
Housing density	Close together, 2–4 storeys — better insulation per occupant	Reduces surface-area-to-volume ratio; reduces heat loss
Window strategy	More double-glazed windows on sun side; fewer western; balanced eastern and poleward	Passive House solar gain strategy; NCC H6 orientation
Plan geometry	Buildings longer East–West, shallower South–North	Maximises solar gain; same principle as PH compact form
Thermal mass wall	Central thermal mass wall; insulated roofs, walls, floors	Passive House thermal mass strategy
Air-lock entries	Space between two doors; attached glasshouses; connected barns/outbuildings	PH/NCC draught-proofing; reduces infiltration
Forest placement	Elevated water storage & forests on slopes above settlement; sun-trap windbreaks; deciduous trees as seasonal solar filters	Microclimate design; reduces heating demand
Pipe protection	Insulate or bury below frost line	Zone 7/8 requirement

Glasshouses — Cool/Cold Climate Design

Ground and poleward wall insulated
Double-glazed glass sloped to shed snow on the sun side
Thermal mass water tanks and/or ponds near the poleward wall
Small domestic animals inside contribute body heat
Active compost provides supplemental heat
Air-lock entries prevent warm air loss
Simple construction: install glass over a trench OR site between two existing buildings for added insulation and shelter

Wildfire Design — Mediterranean Zones (SE Australia)

Wildfire Frequency

Ecosystem	Fire Return Interval
Wet forests	Every 30 years
Dry savannas	Every decade
Grasslands	Potentially every year

Wildfire Design Principles

Never site houses uphill from fire-prone areas
Fuel reduction: mow/graze grasses, compost flammable materials
Include safety dams (water storage) as part of ALL developments
Fire/radiation refuge: 300L water tank, buckets, blankets, indirect entry
Smoke and radiant heat are bigger hazards than the fire itself
Large solid objects provide triangular shelter from radiant heat
After fire: soil damaged — no organic matter, nutrients from ash leach away rapidly, mudslide risk

Small Garden Systems — Cool/Cold Climate

Emphasis on annual crops more than warm climates. Quick-yielding spring gardens + large-harvest autumn storage crops. Key strategies:

Perennialise annual crops using locally-produced heirloom varieties
Harvest own seeds; propagate from cuttings
Berries for every forest niche and edge — prefer acidic, high-organic mulched soil
Berry polyculture: espalier fruit trees + strawberries + rambling crops + insectivorous birds
Blackberry control: shade out with fruit trees OR cattle trampling

Orchards & Forestry

Food forest: sun-facing slopes, good drainage preferred; slightly shaded slopes for frost protection of late-bloomers
Guilds to out-compete grasses: groundcovers, bulbs, mineral accumulators, N-fixers, pollinator attractors, pest herbs
Devote up to 20% of landscape to shelter forests without production loss — drought, cold, wind moderated
Livestock sequencing: poultry first into food forest; cows/sheep only into fully mature systems
Coppicing for firewood: choose species for fuel value and regrowth

Grasslands, Rangelands, and Lawn Replacement

Perennial grasslands: 97% of biomass underground (vs 50:50 in forests). Rangelands managed correctly produce more protein than improved pastures with zero inputs. Key principles: choose appropriate breeds, encourage plant AND animal diversity, supply free-standing water. Rangeland water infiltration: groundcovers + valley-to-ridgeline fencing at 300–500:1 fall distributes water across landscape. Lawns can consume more energy per unit area than broad-scale agriculture — replace with productive systems.

Poultry Stocking Rates

Stocking Rate	System Impact
800 chickens/ha	Nothing left for other animals to forage
350–400 chickens/ha	Sheep and cattle can share range
120–180 chickens/ha	Orchard windfall cleaned; trees fertilised — ideal orchard integration
Free-range birds: 130–150 eggs/year; up to 200 in optimal conditions. Productive for 4–6 years. Natural flock: 20–30 birds. Maximum penned flock: 30–50.

🐟 MODULE 13 — Aquaculture: Ponds, Fish Systems, Chinampas LBC URBAN AGRICULTURE ▶

🌊

Aquaculture productivity: Wetlands are the highest-yielding ecosystems on Earth. Permaculture aquaculture targets low-energy ponds with few inputs and diverse outputs. Potential: ~30× the protein potential of cattle in the same space. Kangkong is the fastest-growing leaf vegetable. Chinese water chestnuts are the most productive human food by weight.

Pond Size and Productivity by Scale

Pond Size	Best Use
1–10 m²	Shallow plant-producing water systems; habitat for frogs, small fish, crustaceans
10–100 m²	Fish production + plant nurseries, firebreaks, irrigation
100–500 m²	Ideal fish ponds for continuous yields
500 m² – 5 ha	Family-supporting aquaculture
50+ ha	Lake ecosystem — income for several families
Starting figure: ~200 kg fish/hectare. Carrying capacity greatly increases with oxygen, edge, and nutrients.

Pond Depth Zones

Depth	Function
Wet mud	Grow crops in saturated soil
≤6 cm	Crustaceans and aquatic plants
≤100 cm	Anchoring plants; small fish production
≤200 cm	Typical fish production zone
4–5 m hollows	Fish refuges in mature ponds
>5 m	Little to no life — cold, clear, anoxic
Productive fish species rarely go deeper than 2.6 m. pH must stay between 3.7 and 10.5 to prevent fish die-off. Adjust with dolomite/oyster shells (raise pH) or sulfur (lower pH). Cold-tolerant fish: <21°C; warm-weather fish: >21°C.

Trophic Ladder — Fish Pond Balance

Level	Species Role	Relative Population
Base	Algae (fed by sunlight + organic matter)	—
1	Zooplankton (feed on algae)	Largest
2	Plankton-feeding fish	3× insectivores
3	Insectivorous fish	2× omnivores
4	Omnivorous fish	2× predators
5	Predatory fish	Fewest
Mussels continuously pump water, removing phosphorus and injecting into pond bottom. Edge, floating, and underwater plants filter water. Plants harvested for mulch; pond bottom dredged for nutrient-rich soil.

Low-Input Fish Food Systems

Mounds of compostable materials → attract insects → sieve as fish feed
Worm farms beside or floating on ponds — direct feed
Hanging containers of rotting carcasses → cultivate maggots → fall into pond
Mulberry trees near pond — leaves and fruit fall as fish food
Comfrey cut and throw — fast-growing mineral accumulator as fish food
Light traps attract insects at night → fall into water

Landscape Mosaic Proportions (where climate allows)

15%

Ponds

15%

Marshes

60%

Forests

10%

Prairies, crops, pasture

Chinampas — Most Productive System in History

Shallow lakes or swamps are dredged into deeper canals and higher banks, creating a dynamic aquaculture + land-based growing system. Land edges grow crops and forests; productive trellises stretch over canals; canal systems grow aquatic products (plants, shellfish, fish). Harvest by boat — far higher carrying capacity than wheelbarrows. Historically supported entire civilisations (Mexico, Peru, Iraq).

🌐 MODULE 14 — Strategies of an Alternative Global Nation: Economy, Villages, Bioregions COMMUNITY + ECONOMICS ▶

🏘

Core premise: Permaculture can also be applied to the human landscape. Creating small, ethical systems of abundance — clean food, nurturing environment, efficient shelters, real community — without being fettered by the current economic power structure. Define problems locally, solve locally, share globally.

Bioregional Organisation

A bioregional organisation connects people sharing a watershed, town borders, or tribe. People identify with their regions and feel local responsibility. A bioregional office can be run by just 4–6 consultants tasked with: understanding local resources, identifying open niches, creating inter-community trade and infrastructure, monitoring successful systems, troubleshooting failing ones.

Ethical Village Design

Ideal village size: 300–500 persons — large enough to meet needs, small enough to know each other
30–100 houses easier to achieve outcomes than individually
Must provide: land, infrastructure, clean water, sewage, production, commerce, plus campsites, workshops, reception areas
100% waste recycling — all organics to compost; other waste creates jobs
Two trust structure: risk-free investments (schools, roads, forestry) + trade/leasing investments
After financial self-reliance: surplus used to help other communities

Charitable Trusts and Village Finance

Small charitable trusts can provide services (schools, hospitals, research institutes, aid programs) and be self-funded by a business or non-profit wing. Administration should be only 4–8% of investment — the rest goes to development. Projects: threatened wildlife habitat, conserving lands, energy-efficient technology, nurseries, aquaculture, clean transportation.

Money, Finance, and Economy

Real wealth: plants, solar energy, clean air, quality water — not money
Invest in generative assets (tools, gardens) not degenerative assets (fossil fuels)
Informal economy: barter, LETs (Local Employment Trades/green dollars), volunteer exchanges
Local currencies prevent hoarding and promote local business
Formal: legal cooperatives with limited liability; elected administrators; surpluses shared
Long-term principle: the longer and slower money flows, the more productivity it creates

Permaculture + LBC + WELL Integration — The Village Model

Permaculture Principle	LBC 4.0 Connection	WELL/NCC Connection	Implementation
Water multiple-use cascade	I05/I06 Net Positive Water — 100% on-site supply, greywater reuse	WELL Feature 36 Water Treatment; NCC Vol 3 WSP systems	Reed beds + constructed wetlands + composting toilets = LBC-compliant water system
Earthworks — keypoint dams + swales	I06 stormwater management; pre-development hydrology + 15% climate uplift	NCC H7P5 bushfire; stormwater detention on CSO systems	Permaculture earthworks design = best-practice LBC I05 stormwater strategy
Urban agriculture by transect	I02 Urban Agriculture percentages (L3=15%, L4=5%, L5=2%)	WELL Feature 38 Fruits & Vegetables; LBC emergency food resilience (75% FTE × 3 days)	Permaculture food system design directly satisfies LBC I02 — rooftop/vertical/aquaponic systems for urban contexts
Ecology of place / Reference Habitat	I01 Ecology of Place — Reference Habitat, no petrochemicals, net positive ecology	WELL Feature 88 Biophilia Plan; LBC Beauty + Biophilia I19	Permaculture site analysis methodology = LBC I01 Step 1/2 (Reference Habitat + baseline ecological condition)
Passive solar building design	I07 Energy reduction (-70% new) + I09 Healthy Interior Environment	NCC H6P1 NatHERS 7★; Passive House ≤15 kWh/m²a heating demand	Cool-climate permaculture building principles = NatHERS/PH design overlap: orientation, thermal mass, glazing strategy, shading
Bioregional economy + local sourcing	I15 Living Economy Sourcing: 20%+ within 500km; I16 Net Positive Waste: 80% diverted	LBC I18 Inclusion: JUST labels, MWDBE contracts, community benefit	Permaculture bioregional trade = direct implementation of LBC I15 local sourcing requirements
Natural pools + aquaculture ponds	I06 on-site water treatment (no chemicals); I02 Urban Agriculture (aquaculture counted)	WELL water quality standards (Feature 30–34) for drinking water	Natural swimming pools satisfy LBC I06 chemical-free treatment. Aquaculture ponds count toward LBC I02 urban agriculture area.

Inclusive & Accessible Homes

SDA Disability
Design

NDIS Specialist Disability Accommodation requirements — four design categories from Improved Liveability to High Physical Support, with detailed specifications for every dwelling element.

⚠

Mandatory from 1 July 2021: All new SDA dwelling enrolments require design + final as-built certification by an Accredited SDA Assessor. The SDA Design Standard replaces previous SDA Price Guide minimum criteria. Does NOT apply to Existing or Legacy SDA. Reviewed by NDIA in 2023.

The Four SDA Design Categories

🏠 IMPROVED LIVEABILITY

Reasonable physical access + enhanced features for people with sensory, intellectual or cognitive impairment. Bedrooms may be on a step-accessed floor level. Min 1000mm accessway width. Min 820mm door clear opening.

🔴 ROBUST

Reasonable physical access + very resilient construction reducing reactive maintenance and risk. High-impact wall linings, vandal-proof fittings, solid-core timber doors, laminated glass, sound-insulated bedrooms, recessed lighting. Breakout room optional.

♿ FULLY ACCESSIBLE

High level of physical access for significant physical impairment. All key facilities on entry level or lift-served floor. Min 1200mm accessway width. Min 900mm door clear opening. Full AS1428.1 bathroom compliance. 1550mm kitchen clearance.

🔆 HIGH PHYSICAL SUPPORT

Highest level — significant physical impairment requiring very high support. All FA requirements plus: 950mm doors, ceiling hoist provision (250kg min), emergency power (2hr min), reverse-cycle A/C, intercom/video system, height-adjustable kitchen benchtop.

Implementation Timeline & Certification Process CRITICAL ▶

Date	Milestone	Notes
Oct 2019	SDA Design Standard launched (Ed. 1.1)	Developed by Livable Housing Australia for NDIA
1 Jan 2020	Dwelling enrolment transferred to NDIA (from NDIS Commission)	Subject to SDA Rules amendment
30 Apr 2020	New SDA enrolments accepted with accredited assessor report OR old process	Old process continues for completions by 30 Jun 2021
1 Jul 2021	MANDATORY — all new build SDA requires Accredited SDA Assessor certification	Design (provisional) + final as-built certification required
1 Dec 2022	Committed/commenced exemptions expire (non-Class 2)	Dwellings built under previous guidelines lose exemption
1 Jul 2023	Class 2 building exemptions expire	All apartment SDA must comply with Design Standard

PROVISIONAL (Design) CERTIFICATION

Issued when design is submitted for building approval. Assessor confirms design meets the nominated design category. Not sufficient for NDIS enrolment alone — signals pipeline to market. Design certification not available for dwellings seeking enrolment under previous guidelines.

FINAL AS-BUILT CERTIFICATION

Issued upon certificate of occupancy (or equivalent). Assessor confirms built dwelling meets all requirements. Mandatory for SDA enrolment from 1 July 2021. Structural engineer sign-off required for ceiling hoist capacity (High Physical Support).

ℹ

Multi-category enrolment: A single dwelling may be certified under multiple design categories. All shared areas must comply with the minimum requirements of ALL enrolled design categories. Dwellings must contain at minimum: kitchen, bathroom, living/dining area, entrance/exit, and at least one bedroom per participant. Studio/bedsit designs are not permitted.

Design Requirements by Element — All Categories REFERENCE ▶

1. Pedestrian Access & Accessways (Cl. 2)

Requirement	Improved Liveability / Robust	Fully Accessible / High Physical Support
Step-free from site boundary	Optional — may use car park accessway instead	MANDATORY from front boundary
Min accessway clear width	1000mm	1200mm
Curved accessway width	—	1500mm min, radius per AS1428.1
Crossfall max	1:40	1:40
Grade 1:20 walkway	Permitted with 1200mm landings every 15m	Same + curved 1500mm width
Step ramp (1:10)	Max 190mm rise / 1900mm length, P5/R12 slip	Same — applies all categories
Ramp (1:14)	Max grade where level diff >190mm, P4/R11 slip	Same — landings at 9m intervals
Vertical clearance	2000mm min all paths	2000mm min all paths
Surface transition	Max 3mm vertical / 5mm bevelled	Max 3mm vertical / 5mm bevelled

2. Car Parking (Cl. 3)

Requirement	Improved Liveability / Robust	Fully Accessible / High Physical Support
Parking space dimensions	3200mm (W) × 5400mm (L)	3800mm (W) × 5400mm (L)
Roof over space	Not required	Required — clear height per AS2890.6
Surface	Even, firm, P4/R11, max 1:40 gradient	Even, firm, P4/R11, max 1:40 gradient
Step-free to entry	From car park (if front boundary not achievable)	From BOTH front boundary AND car park

3. Entrance, Doorways & Door Hardware (Cl. 4)

Requirement	Improved Liveability / Robust	Fully Accessible	High Physical Support
Min clear door opening	820mm	900mm	950mm
External entry landing	1200×1200mm, max 1:40	1500×1500mm + AS1428.1 circulation	1500×1500mm + AS1428.1 circulation
Covered roof at entry	Required — all categories	Required	Required
Door circulation spaces	Not specified beyond landing	AS1428.1 both sides (except bedrooms)	AS1428.1 both sides (except bedrooms)
Threshold step-free	Required — all categories. Max 35mm with 1:8 threshold ramp (280mm max length)	Required	Required
Door handle height	900–1100mm above FFL — all categories	900–1100mm	900–1100mm
Door handle type	Per AS1428.1 (lever/bar, 35–45mm projection)	AS1428.1 compliant	AS1428.1 compliant
Cabling for automation	—	—	Capped GPO at head of bedroom + external entry doors
Robust doors	—	—	Solid core timber; laminated/polycarbonate glazing

4. Corridors (Cl. 5)

Category	Min Clear Width (skirting to skirting)
Improved Liveability / Robust	1000mm
Fully Accessible / High Physical Support	1200mm (increased as required by AS1428.1 door circulation)

5. Windows (Cl. 6)

Requirement	Applicable Categories	Detail
Window sill height	FA + HPS	≤1000mm above FFL in living areas & ≥1 bedroom window. Concession in kitchen/bathroom/utility.
Window controls reach	FA + HPS	600–1100mm above FFL
Cabling for blind automation	HPS only	Capped GPO at window head — bedrooms and living areas
Lockable windows	All categories	Required

6. Sanitary Facilities (Cl. 7)

Requirement	Improved Liveability / Robust	Fully Accessible / High Physical Support
Minimum facilities	WC pan + shower + hand wash basin on entry/lift level — all categories	Same + must be in same bathroom (FA/HPS)
WC clear space (forward)	900mm (W) × 1200mm (L) clear of door swing	1900×2300mm AS1428.1 unisex accessible toilet circulation
WC pan c/l to side wall	Not specified	450–460mm
WC front edge from back wall	Not specified	800±10mm
WC cistern clearance	Not specified	Min 600mm from front edge of pan
WC pan type	Not AS1428.1 required	AS1428.1 compliant (unisex accessible, not ambulant). Grabrails NOT provided unless participant requires.
Peninsular WC option	—	HPS only: 900mm clearance both sides × 2300mm deep
Shower size	Hobless, min 900×900mm clear of screens	Hobless, min 1160×1100mm + AS1428.1 circulation
Shower fittings	Corner location	Vertical grabrail only + height-adjustable head + lever tap 900–1100mm above FFL, 300–800mm from corner. No shower screen. Shower curtain rail.
Hand wash basin	Not AS1428.1 specified	AS1428.1: min 430mm depth, knee/toe clearance 850mm wide centred, sensor/lever tap ≤300mm from basin edge
Wall reinforcement	All categories: min 12mm plywood/fibre cement sheeting floor to 2100mm height (for future grabrails). Masonry exempt.	Same + 600mm forward of WC pan (both sides or at least one)
Floor slip resistance	P3 or R10 minimum — all categories	P3 or R10

7. Kitchen (Cl. 8)

Requirement	Improved Liveability / Robust	Fully Accessible / High Physical Support
Minimum fixtures	Fixed cooktop (with rangehood) + in-built oven + sink + dishwasher — all categories	Same
Clearance in front of benches	1000mm	1550mm
Accessible benchtop	—	Min 900mm W × 440mm D clear under (knee/toe per AS1428.1), adjacent to cooktop and oven latch side
Height-adjustable benchtop	—	HPS: 720–1020mm clear underneath adjustment range, 900mm W × 440mm D, 600mm depth
Cooktop type	—	Electric or induction only (not gas). Min 300mm from internal corner.
Cooktop controls location	—	Side of accessible benchtop or near front edge
Wall oven	—	Side-hinged door, latch side next to benchtop. Handle 600–1100mm FFL. Telescopic shelf.
Dishwasher	Standard or drawer style	Drawer style only (seated operation)
Tapware	—	Lever/sensor, operable part ≤300mm from bench edge
Pantry	—	Wheelchair accessible (pull-out basket or extendable shelves)
GPO location	—	Double GPO ≤300mm from bench front edge, max 1100mm FFL
Cabinet handles	D-pull, overhanging lip (20mm min), or push-to-release — all categories	Same
Task lighting	Min 300lux tested every 1500mm over benchtops — all categories	Same
Floor slip resistance	P3 or R10 — all categories	P3 or R10
Robust materials	Robust only: kitchen benchtop and cabinetry must be robust materials	—

8. Bedroom (Cl. 10)

Requirement	Improved Liveability / Robust	Fully Accessible / High Physical Support
Bedroom size	3100×3100mm (wall to wall)	Accommodates Queen bed 1530×2100mm + circulation spaces
Bed clearance (FA/HPS)	—	1540mm on one side + 1000mm on other two sides (Option 1) OR 1540mm at base + 1000mm both sides (Option 2)
Internal door circulation	—	1540mm W × 1450mm D clear of bed and robes. External per AS1428.1 or min 1200mm corridor.
Wardrobe/robe	Min 1400mm wide, clear of bedroom area	1400mm wide, 1540mm clear space in front
GPOs (FA/HPS)	—	3× double GPO on headboard wall + 1× double GPO on opposite wall
Robust — sound insulation	Robust only: bedroom sound insulated	—

9. Living Area, Switches, Flooring (Cl. 11–13)

Element	Requirement	Categories
Living area free space	Min 2250mm diameter clear of furniture	FA + HPS only
Light switch height	900–1000mm above FFL, aligned horizontally with door handle — all categories	All
GPO height	600–1100mm above FFL	FA + HPS
Switch/GPO type	Rocker/toggle/push-pad, min 35mm wide — all categories	All
Dimmable lighting	Living areas and bedrooms — all categories	All
Internal floor slip resistance	P3 / R10 all internal floors (incl. wet areas) — all categories	All
Floor transition	Max 3mm vertical / 5mm bevelled between abutting surfaces — all categories	All
Carpet pile limit	Max 11mm pile + 4mm backing = 15mm total	FA + HPS

10. Specialist Elements (Cl. 18–25)

Element	Requirement	Category
Ceiling hoists	Bedroom structure & power for 250kg min constant-charge hoist. Can be ceiling or wall-mounted. Range across AND down bed. Structural engineer certification at final stage.	HPS only
Emergency power	Min 2-hour backup to ≥2 double GPOs in participant bedrooms + automated entry/egress doors.	HPS only
Reverse-cycle A/C	Living areas and bedrooms. Controls 900–1100mm FFL, ≥500mm from internal corner.	FA + HPS
Ducted A/C zoning	Habitable rooms individually zoned.	FA + HPS
Internet/Wi-Fi	High-speed stable connection throughout all areas.	FA + HPS
Intercom/video system	Communication between participant and supports when not in line of sight.	HPS only
Luminance contrast	All doorways: ≥30% luminance contrast between door leaf/jamb/architrave/adjacent wall. Min 50mm width band. Bowman-Sapolinski formula: 125(Y2-Y1)/(Y1+Y2+25).	IL only for doors
Glazing contrast strip	75mm solid contrasting strip at 900–1000mm FFL for glazed areas mistaken for openings.	IL + Robust
Toilet seat contrast	≥30% luminance contrast with background (pan/wall/floor).	IL only
Smoke alarms	Home-appropriate alarms in bedrooms and living spaces — all categories.	All
Evacuation plan	Provided to occupier/supports. Required at final as-built stage only.	All
Lifts (if provided)	Min 900mm clear door opening. Min car size 1100×1400mm. NCC Clause E3.6 compliant. No stairway platform lifts.	All (where needed)
Storage cupboard	Min 600mm wide with adjustable shelves (separate from bedroom robe).	All categories
Breakout room	Optional: separate room tailored to disability-related needs. NOT a study, living area, or seclusion room.	Robust only (optional)

11. Robust Design — Additional Requirements (Cl. 25)

STRUCTURE & FINISHES

High-impact wall lining — full height or min 2400mm from FFL
High-impact/vandal-proof fittings (door handles, fixtures)
Solid core timber doors
Laminated glass or polycarbonate resin to all glazed areas
Recessed lighting fixtures only
Sound-insulated participant bedrooms

SAFETY & EGRESS

Design drawings showing egress and retreat zones for staff/other residents
Required only at final as-built certification stage
Document provided to site manager
Breakout room optional — tailored to resident needs (activities, lighting, sound)
Robust cabinetry and benchtop materials in kitchen

SDA Design Standard vs NCC — Relationship & Precedence COMPLIANCE ▶

⚖

NCC takes precedence: The dwelling must comply with all applicable NCC requirements (waterproofing, fire, structural, termite protection etc.). Where there is a conflict between NCC and the SDA Design Standard on spatial requirements, the NCC takes precedence. SDA Design Standard requirements are IN ADDITION to NCC minimums.

Topic	NCC 2022	SDA Design Standard	Which Governs
Disability access (Class 1b, 3, 9c)	D4 access provisions apply	SDA categories go beyond NCC D4	SDA more stringent — follow SDA
Accessible parking (AS2890.6)	Required by NCC/LGA based on building class	SDA Cl. 3.5 — full AS2890.6 if NCC mandates it	NCC triggers AS2890.6; SDA adds dimension requirements
Fire safety	Full NCC fire provisions apply	SDA adds smoke alarms + evacuation plan	Both must be met
Floor slip resistance	AS4586 requirements	SDA: P3/R10 internal, P4/R11 external, P5/R12 steep ramps	SDA may be more stringent — follow SDA
Stairways	Handrails, risers, treads per NCC	Adds: continuous handrail both sides, 1000mm clear width, closed risers, no winders	Both — SDA additional requirements
Lifts	NCC Clause E3.6	Min 900mm door, 1100×1400mm car, no platform lifts	SDA specifies within NCC E3.6 framework
Energy efficiency	H6P1/P2 (Class 1), J1 (Class 2+)	Not addressed in SDA Design Standard	NCC governs energy — SDA silent on this
Spatial requirements	Generally less prescriptive	SDA more stringent — room sizes, clearances, circulation	SDA governs spatial requirements where more stringent

High Physical Support — Complete Compliance Checklist HPS ▶

SITE & EXTERNAL ACCESS

☐ Step-free from front boundary to entry door
☐ Accessway ≥1200mm clear width
☐ Curved paths ≥1500mm wide, radius per AS1428.1
☐ Car park: 3800×5400mm, roofed, P4/R11, 1:40 max grade
☐ Landings ≥1200×1200mm at gates/ramps with AS1428.1 circulation
☐ Vertical clearance ≥2000mm all paths

ENTRY & DOORS

☐ All doors ≥950mm clear opening
☐ External entry landing 1500×1500mm + AS1428.1 circulation
☐ Covered roof over entire entry landing
☐ Step-free threshold (max 35mm with 1:8 ramp)
☐ Door handles 900–1100mm FFL, lever style, AS1428.1
☐ AS1428.1 door circulation both sides (or door automation)
☐ Capped GPO at head of bedroom + external entry + outdoor area doors

INTERNAL CIRCULATION

☐ Corridors ≥1200mm clear (wider at door junctions per AS1428.1)
☐ All key facilities on entry level OR lift-served floor
☐ Lift: ≥900mm door, ≥1100×1400mm car, no platform lifts
☐ Internal floors P3/R10 slip resistance
☐ Carpet ≤15mm total (11mm pile + 4mm backing)

BATHROOM

☐ WC, shower, basin all in same room
☐ WC pan: AS1428.1, c/l 450–460mm from wall, front edge 800±10mm from back wall
☐ WC: min 600mm clear cistern to front of pan; 1900×2300mm circulation
☐ Shower: hobless, 1160×1100mm + AS1428.1 circulation, curtain rail
☐ Shower: vertical grabrail only, height-adjustable head, lever tap 900–1100mm
☐ Basin: AS1428.1, 430mm min depth, knee/toe clearance, lever/sensor tap
☐ Wall reinforcement: 12mm sheeting floor to 2100mm, 600mm forward of WC
☐ Floor: P3/R10 minimum

BEDROOM

☐ Accommodates 1530×2100mm queen bed + 1540mm one side + 1000mm two sides
☐ Internal door circulation 1540×1450mm clear of bed
☐ Wardrobe 1400mm wide, 1540mm clear in front
☐ 3× double GPO on headboard wall + 1× opposite wall
☐ Ceiling hoist: 250kg provision, power, wall/ceiling mount, covers across + down bed
☐ Structural engineer certificate for hoist structure (final stage)
☐ Windows with sill ≤1000mm FFL; controls 600–1100mm FFL
☐ Capped GPO at window head (blind automation)

SERVICES & SPECIALIST

☐ Reverse-cycle A/C: living + bedrooms, controls 900–1100mm FFL, ducted zones
☐ Emergency power: ≥2hr backup, ≥2 double GPOs in bedroom + automated doors
☐ High-speed Wi-Fi throughout
☐ Intercom/video system for participant-support communication
☐ Living area: 2250mm diameter free space
☐ Light switches 900–1000mm FFL; GPOs 600–1100mm FFL; rocker/toggle/pad style
☐ Dimmable lighting in living areas and bedrooms
☐ Kitchen: 1550mm clearance, accessible benchtop, height-adjustable section, drawer dishwasher, electric/induction cooktop, wall oven with side-hinged door
☐ Smoke alarms in bedrooms + living spaces
☐ Emergency evacuation plan (final stage)

Key Definitions & Glossary REFERENCE ▶

Term	Definition
SDA	Specialist Disability Accommodation — the physical dwelling (not the support services) funded under NDIS for participants with extreme functional impairment or very high support needs
NDIA	National Disability Insurance Agency — administers NDIS and SDA enrolment
Accredited SDA Assessor	Suitably qualified professional who has completed NDIA-accredited assessor training via RTO. Engaged by developer to certify dwellings.
Provisional Certification	Design-stage certification confirming plans comply with nominated design category. Not sufficient for enrolment alone.
Final As-Built Certification	Post-occupancy-certificate certification. Mandatory for SDA enrolment from July 2021.
Hobless shower	Wheelchair-accessible shower with no hob, setdown, or shower screen frame
FFL	Finished Floor Level
TFA	Treated Floor Area (Passive House context) — note: SDA uses gross floor area

Term	Definition
Accessway	Continuous accessible path of travel as defined in AS 1428.1
Circulation space	Clear unobstructed area enabling persons using mobility aids to manoeuvre
GPO	General Purpose Outlet (powerpoint)
WC pan	Toilet pan (Water Closet pan)
Luminance contrast	Light reflected from one surface vs another, expressed as a percentage. Formula: 125(Y2-Y1)/(Y1+Y2+25) where Y2 = LRV lighter, Y1 = LRV darker. Minimum 30% for SDA doorways.
LRV	Light Reflectance Value — measured with calibrated colorimeter/luminance meter. Smartphones not acceptable.
TGSI	Tactile Ground Surface Indicator — only provided if specifically required by participants (or NCC mandates)
Breakout room	Optional room for Robust dwellings — enhances learning/mood through activities, lighting, sound. NOT a seclusion room.

IS Rating Scheme v2.0

Infrastructure
Sustainability

ISCA’s Infrastructure Sustainability Scheme — governance, economic, environment, and social credits aligned to the SDGs. The standard for measuring sustainability in infrastructure projects.

🏗

About IS v2.0: Australia’s only comprehensive rating system for evaluating sustainability across planning, design, construction and operation of infrastructure. Developed by ISCA (Infrastructure Sustainability Council of Australia). Evidence-based assessment across 4 Themes, ~40 credits, rated out of 100 points (+ 10 Innovation bonus). Applies to roads, rail, water, energy, buildings, ports, airports and more. Design rating is interim — superseded by final Design & As Built rating.

5

Award Levels

Bronze → Diamond

100

Points (+ 10 bonus)

Innovation credits extra

4

Themes

Governance · Economic · Environment · Social

3

Achievement Levels

Per credit (L1 → L3)

477

Page Technical Manual

ISv2.0 D&AB · July 2018

4

Rating Phases

Planning · Design · As Built · Operations

Rating Award Levels — Rated out of 100 Points

Award	BRONZE	SILVER	GOLD	PLATINUM	DIAMOND
Score Range	`20–39.9`	`40–59.9`	`60–79.9`	`80–94.9`	`95–110`
No Rating	Score <19.9 — no award issued

📐

Scoring formula: Points per level = (Credit weighting) ÷ (Number of levels). Level achieved × points per level = points awarded. E.g. 6-point credit at Level 2 = 6 × (2/3) = 4 pts. Materiality assessment adjusts default weightings per project. Credits below materiality threshold are scoped out and remaining credits renormalized to 100 total.

Credit Structure — All Themes, Categories & Default Weightings

🏛 GOVERNANCE THEME — Total: 26 pts (+ 10 Innovation bonus) 5 Categories · 10 Credits ▶

Category	Credit	Title	D&AB Wt.	Rating Phases
Context	Con-1	Strategic Context	Planning only	P
Context	Con-2	Urban & Landscape Design Context	2.5	P D AB O
Leadership & Management	Lea-1	Integrating Sustainability	4.0	P D AB O
	Lea-2	Risks and Opportunities	2.5	P D AB O
	Lea-3	Knowledge Sharing	2.5	P D AB O
Sustainable Procurement	Spr-1	Risk & Opportunity Assessment and Procurement Strategy	3.0	P D AB O
	Spr-2	Supplier Assessment and Selection	2.5	P D AB O
	Spr-3	Contract and Supplier Management	2.5	P D AB O
Resilience	Res-1	Resilience Strategy	4.0	P D AB O
Resilience	Res-2	Climate and Natural Hazard Risks	2.5	P D AB O
Innovation	Inn-1	Innovation	10 bonus	P D AB O

💡

Lea-1 Integrating Sustainability is the most important governance credit — it triggers the materiality assessment that sets all other credit weightings. Spr credits apply to procurement of major suppliers and subcontractors. Inn-1 bonus points require exceeding Level 3 by at least the same increment as L2→L3.

💰 ECONOMIC THEME — Total: 8 pts 2 Categories · 6 Credits ▶

Category	Credit	Title	D&AB Wt.	Rating Phases
Options Assessment & Business Case	Ecn-1	Options Assessment	4.0	P D AB O
	Ecn-2	Valuing and Considering Externalities	Planning only	P
	Ecn-3	Equity and Distributional Impacts	Planning only	P
	Ecn-4	Economic and Financial Sustainability	2.0	P D AB O
Benefits	Ecn-5	Benefits Mapping	2.0	P D AB
Benefits	Ecn-6	Post Project Evaluation	Planning only	P

📊

Ecn-1 Options Assessment requires a multi-criteria or cost-benefit analysis comparing options across all three sustainability pillars — not just financial metrics. Ecn-2 and Ecn-3 are Planning-phase-only credits addressing externalities and social equity — important for triple-bottom-line business cases.

🌿 ENVIRONMENT THEME — Total: 44 pts (AU) 6 Categories · 17 Credits ▶

Category	Credit	Title	AU Wt.	NZ Wt.
Energy & Carbon	Ene-1	Energy Efficiency	2.75	2.75
	Ene-2	Renewable Energy	2.75	2.75
	Ene-3	Offsetting	2.0	2.0
Green Infrastructure	Gre-1	Green Infrastructure	2.0	2.0
Environmental Impacts	Env-1	Receiving Water Quality	1.63	1.63
	Env-2	Noise	1.63	1.63
	Env-3	Vibration	1.62	1.62
	Env-4	Air Quality	1.62	1.62
	Env-5	Light Pollution	1.0	1.0
Resource Efficiency	Rso-1	Resource Strategy Development	2.0	2.2
	Rso-2	Contamination Remediation Material	1.0	1.2
	Rso-3	Management of Acid Sulfate Soil	1.0	N/A
	Rso-4	Resource Recovery	2.0	2.2
	Rso-5	Adaptability	2.0	2.2
	Rso-6	Material Lifecycle Impact Measure & Management	4.5	4.6
	Rso-7	Environmentally Labelled Products & Supply Chains	1.5	1.6
Water	Wat-1	Water Use	3.0	3.0
Water	Wat-2	Appropriate Use of Water Sources	3.0	3.0
Ecology	Eco-1	Ecological Assessment and Risk Management	3.5	3.5
Ecology	Eco-2	Ecological Monitoring	3.5	3.5

⚠ Rso-3 (Acid Sulfate Soil) not applicable in New Zealand. Resource Efficiency total: 14 pts (AU). Env-1 to Env-5 sum to 7.5 pts. Ecology total: 7 pts. Water total: 6 pts.

👥 SOCIAL THEME — Total: 22 pts 5 Categories · 10 Credits ▶

Category	Credit	Title	D&AB Wt.	Rating Phases
Stakeholder Engagement	Sta-1	Stakeholder Engagement Strategy Development	3.5	P D AB O
Stakeholder Engagement	Sta-2	Stakeholder Engagement Strategy Implementation	3.5	P D AB O
Legacy	Leg-1	Leaving a Lasting Legacy	2.25	P D AB O
Heritage	Her-1	Heritage Assessment and Monitoring	2.5	P D AB O
Workforce Sustainability	Wfs-1	Strategic Workforce Planning	2.0	P D AB O
	Wfs-2	Jobs and Skills	2.0	P D AB O
	Wfs-3	Workforce Culture and Wellbeing	2.25	D AB O
	Wfs-4	Diversity and Inclusion	2.0	D AB O
	Wfs-5	Sustainable Site Facilities	2.0	D AB O

SDG Alignment — Key Linkages by Category

SDG	Aligned IS Categories
SDG 3 — Good Health	Stakeholder Engagement, Workforce
SDG 4 — Quality Education	Workforce (Jobs & Skills)
SDG 5 — Gender Equality	Workforce (Diversity), Stakeholder Engagement
SDG 6 — Clean Water	Water, Environmental Impacts
SDG 7 — Affordable & Clean Energy	Energy & Carbon
SDG 8 — Decent Work	Workforce, Legacy, Benefits, Options Assessment, Leadership, Procurement, Stakeholder
SDG 9 — Industry & Innovation	Innovation, Options Assessment, Energy, Green Infra, Resource Efficiency, Resilience, Context
SDG 10 — Reduced Inequalities	Stakeholder Engagement, Legacy, Heritage, Workforce
SDG 11 — Sustainable Cities	Context, Green Infra, Ecology, Resource Efficiency, Water, Energy, Stakeholder, Legacy, Heritage, Workforce
SDG 13 — Climate Action	Resilience, Energy & Carbon, Ecology, Green Infrastructure
SDG 15 — Life on Land	Ecology, Green Infrastructure, Water, Resource Efficiency, Environmental Impacts
SDG 16 — Peace & Justice	Leadership & Management, Resilience, Stakeholder, Procurement
SDG 17 — Partnerships	Procurement, Stakeholder Engagement, Innovation, Leadership, Benefits, Energy

Rating Process — Key Stages

① Registration

Submit Registration of Interest (RoI) to ISCA. Execute Rating Agreement. Case Manager assigned. Project Detail Form populates IS Ratings Directory.

② Assessment

Kick-off workshop. Materiality & weightings assessment (via Lea-1). Self-assessment against all credits. Technical Clarifications (TCs) and Credit Interpretation Requests (CIRs) submitted as needed.

③ Verification

Independent Verifiers review self-assessment in 2 rounds. Round 1: verified score + recommendations. Round 2: revised evidence reviewed. Dispute process available.

④ Certification

Technical Rating Committee certifies final score and award level (Bronze to Diamond). Certificate issued. Design rating is interim — superseded by final D&AB rating.

Key Roles

Role	Responsibility
Assessor	Primary contact; organises and submits all evidence. IS AP recommended.
Case Manager	ISCA staff member; supports assessor throughout, facilitates kick-off workshop.
Verifier	Independent panel specialist; verifies materiality assessment and self-assessment.
Technical Rating Committee	ISCA Board sub-committee; certifies final ratings and reviews TCs/CIRs.
Rating Partner	All parties involved — proponent, designer, contractor, owners, operators.

📋

Base Case Proposal: Each project must define a base case — the minimum compliance baseline against which sustainability improvements are measured. The base case is verified by the independent Verifier alongside the materiality/weightings assessment at the start of the rating process. Evidence naming convention: Lea-3 b. Monitoring Report [Section 3.1, p45]

Modelling for SD · IISD 2019

Sustainable Development
Modelling

Three-pillar sustainable development modelling — environmental, social, and economic. Causal Loop Diagrams, integration, scenario and sensitivity analysis, and communicating results.

📊

About this resource: Published by the International Institute for Sustainable Development (IISD) in 2019. A practical framework for using integrated, multi-pillar models to inform public policy and private sector decisions. The core argument: models should integrate all three pillars of sustainable development — environmental, social and economic — and serve as tools for structured conversation between stakeholders, not just number generators.

3

Pillars of SD

Environmental · Social · Economic

17

UN SDGs

Indivisible — all must be considered

9

Chapters

Intro → Resourcing

3

Integration modes

Expand · Combine · New model

3

Robustness checks

Scenario · Sensitivity · Monte Carlo

4

Model user roles

Decision-maker · Commissioner · Developer · User

The Three-Pillar Approach — SD Requires All Three

🌍 Environmental

Climate change, pollution, ecosystems, biodiversity, natural resource depletion, land use, emissions. Often quantifiable but difficult to monetise. Bio-physical models focus here — but must be linked to other pillars.

👥 Social

Employment, health, education, inequality, gender equity, migration, community wellbeing. Complex political dimensions. Often qualitative — progressive monetisation using hedonic valuation, shadow prices, SEEA.

💰 Economic

GDP, revenues, taxes, royalties, investment returns, employment costs. Traditional financial models focus here alone. Key challenge: capturing externalities (environmental damage, social harm) that the market ignores.

⚠

The silo problem: Most models today analyse each project or policy in isolation — financial model measures profits and taxes; climate model measures mitigation cost; neither captures interconnections. A sustainable development model must break down these silos and force consideration of all three pillars simultaneously, quantifying both costs and benefits across all dimensions.

Modelling as a Conversation — Not a Black Box

✗ Wrong — Model as Answer from On High

Single modeller produces numbers in isolation. Technical process hidden from stakeholders. Results presented as definitive truth. Community, environment and social interests excluded from structured conversation. Government relies on investor’s model uncritically.

✓ Right — Model as Enabler of Conversation

Stakeholder mapping first. All interests translated into indicators. Model assumptions are visible and debated. Results frame the discussion — not end it. Group model-building creates ownership. Inclusive process contributes to SDG 16 (Strong Institutions) and SDG 17 (Partnerships).

📋 CH 3 — Using Models for Better Decision Making Fit model to question · Timing · Stakeholders ▶

Factor	Guidance
Understand decision-maker needs	If government has already decided to build a road, model should assess how to build it best — not whether to build it. Decision-makers set target → model identifies required actions.
Choose the right time	Most important success factor. Know the political cycle. Decision within weeks → use existing model or don’t model. Decision spans lifecycle → identify multiple entry points.
Engage stakeholders early	Those who can block execution must be involved throughout. Diverse stakeholders = diverse interests = better model legitimacy.
Select the right model	Generic models suit broad policy questions. Customised models suit specific contexts (System Dynamics used for climate adaptation in Mauritius and Cambodia).
Publish the model	Benefits: tests robustness, validates data assumptions, grows knowledge community, rebalances stakeholder asymmetries, avoids disinformation.

🔄

Model reuse: Models can be reused (same model at different lifecycle stage with updated assumptions), recycled (adapted from broad policy to specific project), or repurposed (distributed to different agencies for monitoring, tax forecasting, auditing).

🏗 CH 4 — Building a Model Stakeholder map · Quantify · Discount rate · CLD ▶

Step 1 — Causal Loop Diagram (CLD) / System Map

Before quantitative modelling begins, build a qualitative system map with all stakeholders. Graphically represents causal links between indicators. Reveals unexpected dynamics (e.g. road → deforestation → reduced water → limited agriculture = undermines the road’s economic benefit). Defines model boundaries: what’s in scope vs out of scope.

Step 2 — Quantifying and Converting to Common Value

Variable Type	Quantification	Monetisation	Examples
Easy both ways	✓ Straightforward	✓ Market prices	Income flows, costs, tax revenues, royalties
Easy to quantify, hard to monetise	✓ Quantifiable	⚠ Needs conversion factor	CO₂ emissions (→ ETS price), water quality, noise levels
Difficult both ways	⚠ Frontier science	✗ No consensus yet	Antimicrobial resistance, nature-based infrastructure, ecosystem services, gender inequality distribution

Step 3 — Discount Rate (Time + Risk Adjustment)

Concept	Detail
Time value of money	PV = FV ÷ (1 + r)^n. Higher discount rate = lower present value of future outcomes. Road jobs now vs. decades of pollution — must be converted to common present value.
Risk-adjusted rate	Risk preference (risk aversion) added to discount rate. E.g. 5% risk-free → 15% risk-adjusted. $100 risky future → $87 PV at 15%.
SD debate	Nordhaus (Nobel, economics): 2.5% rate — much lower than typical financial 10–15%. Some scientists argue for negative discount rate. Choice dramatically affects comparison of long-term environmental vs short-term economic options.

⚙ CH 4 — Modelling Methods Reference Econometric · Optimisation · Simulation · System Dynamics ▶

Method Type	How It Works	Best For	Limitations
Econometric	Statistical relationships from current/historical data	Estimating relationships; informing forecasting assumptions	Limited for forward-looking policy questions
Optimisation	Finds optimal outcome for target given constraints (e.g. min cost to end hunger within CO₂ budget)	Quantifying cost of a goal; investment allocation	Requires well-defined objective function; less useful for multi-stakeholder trade-offs
Simulation (What-if)	Models likely impact of policy/project options	Scenario analysis; comparing interventions	Results quality depends on quality of structural assumptions
System Dynamics	Feedback loops, delays, non-linear effects; stocks and flows	Complex adaptive systems; long-term policy; causal mechanisms	Data-intensive; requires expertise; can be opaque
General Equilibrium (CGE)	Economy-wide model capturing cross-sector feedbacks	Economy-wide policy impacts (e.g. carbon tax across all sectors)	Complex; aggregated; harder to interpret
Partial Equilibrium	Single sector model; assumes no economy-wide feedback	Sector-specific impacts (e.g. impact of carbon tax on oil industry only)	Misses economy-wide effects; may show only negatives of a tax, missing positives elsewhere

Model Dimensions

Top-Down vs Bottom-Up
Top-Down	Macro-level aggregation → disaggregated by scaling. Good for national-level policy outcomes.
Bottom-Up	Tracks micro-level variables → aggregates up. Good for local dynamics; e.g. where to build a road for health access.

Structural vs Reduced Form
Structural	Describes causal process explicitly (engine mechanics). Supports understanding but requires theory.
Reduced Form	Uses observed correlation (pressing pedal → speed). Simpler but a black box — doesn’t explain mechanism.

⚠

Discontinuity warning: Most linear models generate overly optimistic/pessimistic results because they cannot capture tipping points, irreversibilities and extreme events (financial crises, civil conflict, mass extinction). Bear this limitation in mind when communicating results.

📥 CH 5 — Choosing Model Inputs Data · Parameters · GIGO · Uncertainty ▶

Input Types

Type	What It Is	Key Risk
Data	Measurements, observations, estimates translated to numbers (e.g. census count of 8.4M)	Historical = more accurate; future = more uncertain
Technical Parameters	Exogenous coefficients: international conventions (kg→lb), laws of nature (carbon content of coal), social practices (working hours/day)	May change over time due to technological trends
Behavioural Parameters	Endogenous — estimated statistically from data (e.g. savings rate 5% for <$10k income). Guide how variables respond to each other	Higher uncertainty; must be based on broad literature review, not one study

Dealing with Incomplete Data

Option	When to Use
1. Acquire	Collect new data or purchase. High importance + budget available.
2. Approximate	Use comparable proxy. Be transparent about assumptions.
3. Free-ride	Find partner who needs same data — share cost.
4. Sensitivity analysis	Report honestly with range of results. If missing data could cause catastrophic irreversible outcomes, must acquire.

🗑

GIGO — Garbage In, Garbage Out: The numerical character of data/parameters makes them easy to confuse with facts. All data involves interpretation. Data quality threshold depends on use — a doctor needs better health data than a friend asking “how are you?”. Independently verified data complying with published standards increases model result quality.

🔗 CH 6 — Integrating Models Horizontal · Vertical · Standards ▶

Horizontal Integration — Combining the Three Pillars

Option	How	Advantage	Disadvantage
1. Expand existing model	Add environmental and social indicators to existing financial model	Builds on trusted, existing model; lower cost	No feedback loops between new indicators and financial core
2. Combine multiple models	Agriculture model ↔ Economy-wide model ↔ Climate model — outputs of one become inputs of another	Captures cross-pillar feedbacks; uses existing expertise	Can become opaque and complex; models may not interact coherently
3. Develop new integrated model	Build single model capturing all three pillars simultaneously with feedback loops, delays, non-linearity	Most theoretically complete; captures true integration value	Data-intensive; difficult to document and explain; may reduce uptake

⚠

Ghana gold mining case: Traditional modelling focused on tax revenues from gold mining. An integrated model found that losses to local farmers from mine pollution exceeded the tax revenues collected. Had social and environmental pillars been included from the start, the government could have better regulated mine pollution or increased taxes to fund cleanup.

Vertical Integration — Linking Policy to Project

Policy → Project

National emissions model sets reduction target → informs project-level decision (don’t build coal plant; choose renewable). Policy defines project boundaries.

Project → Policy

Food storage facility model + rural road model → feed into national 20% rural income increase policy. Project results justify or refine the policy target.

✅ CH 7 — Checking Modelling Results External checks · Scenario · Sensitivity · Monte Carlo ▶

External Checks

Compare results against other models, studies, expert opinion. If very different, investigate why:

Different question being answered
Different level (policy vs project)
Different assumptions made
Mistakes in inputs, assumptions or code

📏

World hunger example: 5 models estimated cost to end hunger at $7B–$265B/yr. Different approaches (sectoral vs economy-wide), assumptions about sector roles, and targets (ending poverty 2030 vs undernutrition 2050) explained the entire 38× range.

Internal Checks — Three Methods

Method	How It Works
Scenario Analysis	Define plausible sets of assumptions: base case + better case + worse case. Multiple assumptions varied per scenario — must remain internally consistent. Communicates “what if things go better/worse than expected”.
Sensitivity Analysis	Change ONE key parameter at a time, over a broader range than scenario analysis. Identifies which assumptions most affect results. Runs BEYOND plausible range — stress testing.
Monte Carlo	Run model many times with randomly generated assumptions (within probability distribution). Produces a distribution of plausible results rather than a single number. Shows uncertainty range visually.

🎯

False accuracy warning: It is better to be broadly right across all three sustainability dimensions than precisely accurate in just one but wrong in the others. The notion of a model’s accuracy should be treated with care — context, indicator definitions, and acceptable margins all matter.

📣 CH 8–9 — Communicating Results & Resourcing Audience · Simplicity · In-house vs Outsource ▶

Communicating to Different Audiences

Audience	What They Need
Minister / Decision-maker	High-level carbon, revenue, economy and equity impacts. Simple clear message. No technical detail unless asked. Certainty communicated through scenarios not buried uncertainty.
Other ministries	Results relevant to their specific interests — energy ministry wants energy impacts; treasury wants revenue impacts.
Environmental CSOs	Carbon and ecosystem impacts. Less interested in tax revenues.
Households	Personal cost impact. What does this mean for my bill?
Business	Profit impact. Competitive effects. Compliance cost.

💬

Principle — Less is More: Communicate key messages only. Too much detail loses people. Be prepared to answer technical questions but don’t volunteer them upfront. Publish the model (or an online interface) to empower stakeholders to produce their own results — this improves accountability while risking misuse.

In-House vs Outsourcing Decision

Scenario	Recommended Approach
Routine, core business, decisions made repeatedly	High internal resourcing
One-off decision	Outsource more of the process
Low internal capability + high cost of poor decision	Outsource (better than no model at all)
Building organisational capacity	Retain in-house — learn by doing (acceptable if poor-decision costs are low/correctable)

⚙

Modelling culture: Team-based, open, transparent culture vs individualistic black-box culture. Standards (FAST Standard, Best Practice Spreadsheet Modelling, Financial Modelling Code, SMART Guidelines) enable readability, sharing and capacity building. Models are living documents — treat modelling capacity as a long-term organisational asset requiring maintenance.

Key Definitions

Model

f(variables) → simplified reality

A set of mathematical equations describing relationships between variables. Provides a realistic yet simplified representation of reality.

Discount Rate

PV = FV ÷ (1 + r)^n

Translates future value to present day. Higher rate → lower future value. Nordhaus: 2.5% for SD modelling vs 10–15% typical finance.

GIGO

Bad Input → Bad Output

Garbage In, Garbage Out. A model cannot transform bad-quality inputs into reliable results. Data quality is a prerequisite for model validity.

CLD

Causal Loop Diagram

System map visualising causal interconnections between system elements. Used for qualitative modelling before quantitative work begins. Defines model boundaries.

Externality

Cost or benefit not in market price

Effects on parties not in the transaction. Environmental damage, social harm. Traditional models exclude these — SD models must include them explicitly.

Vertical Integration

Policy ↔ Project

Linking project-level models to policy-level models in both directions. National emissions target → project choice. Project results → refine national policy.

PHI v9f · Complete Engineering Reference

Passive House
Technical Suite

The complete Passive House technical reference — PHI v9f criteria for all climate types, EnerPHit retrofit, engineering formulas, materials λ-values, NCC integration, and interactive calculators.

Critical Numbers — Know These Cold

The most-referenced values for Passive House and NCC 2022 compliance. All per treated floor area (TFA) unless noted.

≤ 15

PH Heating demand kWh/m²a

or ≤10 W/m² peak load

≤ 15

PH Cooling + dehum demand kWh/m²a

+ dehumidification contribution

≤ 0.6

PH Airtightness n₅₀ h⁻¹

EnerPHit: ≤1.0 h⁻¹

≥ 75%

HRV heat recovery efficiency

Elec demand ≤0.45 Wh/m³

≤ 60

PH Classic PER demand kWh/m²a

Plus ≤45 · Premium ≤30

≤ 120

PH Classic PE demand kWh/m²a

Legacy non-renewable method

7 ★

NCC min NatHERS avg — Class 2

Individual min 6 stars

70%

NCC H6P2 whole-of-home energy cap

vs 3★ heat pump + 5★ gas HWS ref

100%

Class 2 carpark EV-ready spaces

7kW Type 2 · J9D4

20%

Commercial roof clear for solar PV

J9D5 · switchboard pre-wired

0.33

Heat capacity of air cp,air Wh/m³K

Constant — used in all HVAC calcs

0.13

Internal surface resistance Rsi m²K/W

Vertical walls (most common)

Standard Comparison — PH vs NCC vs NCC Highly Sealed

Parameter	NCC 2022 Minimum	NCC Highly Sealed Trigger	PHI Low Energy	PH Classic	PH Plus	PH Premium
Airtightness n₅₀	≤ 10 m³/hr.m²	≤ 5 m³/hr.m²	≤ 1.0 h⁻¹	≤ 0.6 h⁻¹	≤ 0.6 h⁻¹	≤ 0.6 h⁻¹
Heating demand (Class 1)	7-star NatHERS ~≤45 kWh/m²a	—	≤ 30 kWh/m²a	≤ 15 kWh/m²a	≤ 15 kWh/m²a	≤ 15 kWh/m²a
Heating demand (Class 2)	J1P2 per Spec 44	—	≤ 30 kWh/m²a	≤ 15 kWh/m²a	≤ 15 kWh/m²a	≤ 15 kWh/m²a
Primary energy	H6P2: 70% of ref bldg	—	≤ 75 PER	≤ 60 PER	≤ 45 PER	≤ 30 PER
Renewable generation	Roof ready (J9D5)	—	—	—	≥ 60 kWh/m²a footprint	≥ 120 kWh/m²a footprint
Mechanical ventilation	If n₅₀ <5 m³/hr.m²	MANDATORY if <5 m³/hr.m²	HRV required	HRV ≥75% eff.	HRV ≥75% eff.	HRV ≥75% eff.
Overheating limit	Not specified by NCC	—	<10% hrs >25°C	<10% hrs >25°C	<10% hrs >25°C	<10% hrs >25°C
Humidity limit	AIRAH DA07 mould idx 3	—	<20% hrs >12 g/kg	<20% hrs >12 g/kg	<20% hrs >12 g/kg	<20% hrs >12 g/kg

PH Component Criteria — Cool Temperate (Sydney, Adelaide, Melbourne)

Component	PH Criterion	Unit	Notes
Roof / ceiling	≤ 0.15	W/m²K	Exterior insulation preferred
Walls (exterior)	≤ 0.15	W/m²K	Interior insulation ≤0.35
Ground floor slab	≤ 0.25	W/m²K	Against ground (exterior)
Windows (installed Uw,inst)	≤ 0.85	W/m²K	Including frame + install TB
Windows (overall Uw)	≤ 1.00	W/m²K	EnerPHit Table 2
Windows (glazing Ug)	≤ 1.10	W/m²K	Overall criterion: 0.85
Glazing solar criterion	Ug − g×1.6 ≤ 0	—	Ensures balance for heated buildings
g-value (SHGC)	0.50 – 0.55	—	Typical PH window target
Linear thermal bridge free	Ψ ≤ 0.01	W/mK	Per connection detail
Point thermal bridge free	χ ≤ 0.01	W/K	Per fixing, anchor etc.
TB-free building test	Σ(l×Ψ) + Σ(n×χ) ≤ 0.0 W/K	—	PHPP Areas check
HRV heat recovery	≥ 75%	η	System-level including duct losses
HRV electricity demand	≤ 0.45	Wh/m³	Fan + controls
HRV imbalance	≤ 10%	%	ODA vs EHA flow
Min surface temp factor	fRsi ≥ 0.70	—	Cool-temperate moisture protection
Interior surface ΔT	≤ 4.2 K	K	Below operative temp (comfort)
Floor surface temp	≥ 19°C	°C	Comfort requirement

Essential Formulas at a Glance

U-VALUE

U = 1 / (Rsi + Σ(d/λ) + Rse) [W/m²K]

Rsi=0.13 (wall), 0.10 (ceil), 0.17 (floor) · Rse=0.04 (vented)

AIRTIGHTNESS n₅₀

n₅₀ = V₅₀ / V_building [h⁻¹]

V₅₀ = measured flow at 50Pa · V_building = net air volume (finish to finish)

HEAT ENERGY TRANSPORT (Magic Formula)

H_ET = D × P_D × f × C [kWh/a or W]

D=dimension · P_D=performance · f=correction · C=climate (G_T kKh/a or ΔT K)

WINDOW ENERGY BALANCE

Q_H,window = Q_T,window − Q_S Q_S = A_g × g × r × G_S r = r_sh × r_dirt × r_inc

r defaults: shading 0.75 · dirt 0.95 · incidence 0.85

VENTILATION SIZING

SA = N × 30 m³/h EA = Ki×60 + Ba×40 + WC×20 MA = TFA × 2.5 × 0.3 × 1.3 VDA = max(SA, EA, MA)

HEAT PUMP COP

COP_HP = W_T / W_E,HP [-] q_P = q_H / COP [kWh/m²a] q_PER = q_P × PER_factor [kWh/m²a]

PER factors: heating 1.80 · cooling 1.05 · DHW 1.30 · elec 1.30

Surface Resistances Rsi / Rse [m²K/W]

Component	Direction of heat flow	Rsi (internal)	Rse (external)	Notes
Vertical wall	Horizontal	0.13	0.04	Most walls, partitions
Ceiling / roof	Upward	0.10	0.04	Heat rising in summer
Floor slab	Downward	0.17	0.04	Habitable floor, heat loss
Ventilated cavity / rainscreen	—	0.13	0.13	Both faces treated as internal

💡

Engineer’s shortcut: For vertical walls (the most common case) use Rsi = 0.13 and Rse = 0.04. Total surface resistance = 0.17 m²K/W. Add to Σ(d/λ) for RT, then U = 1/RT.

📋

Document basis: PHI Criteria for Passive House, EnerPHit and PHI Low Energy Building Standard, version 9f, revised 15.08.2016. All criteria verified using PHPP (Passive House Planning Package). Reference area = TFA (Treated Floor Area), except: renewable energy generation = projected building footprint; airtightness = net air volume.

Passive House — Three Classification Tiers

Criterion	CLASSIC	PLUS	PREMIUM	Alternative Criteria
Heating demand	`≤ 15 kWh/m²a`	`≤ 15 kWh/m²a`	`≤ 15 kWh/m²a`	OR: Heating load ≤10 W/m²
Cooling + dehumidification demand	`≤ 15 + dehum contribution`	`≤ 15 + dehum contribution`	`≤ 15 + dehum contribution`	OR: Variable limit (PHPP) / Cooling load ≤10 W/m²
Airtightness n₅₀	`≤ 0.6 h⁻¹`	`≤ 0.6 h⁻¹`	`≤ 0.6 h⁻¹`	No alternative
PER demand	`≤ 60 kWh/m²a`	`≤ 45 kWh/m²a`	`≤ 30 kWh/m²a`	±15 kWh/m²a if compensated by different generation. Classic: legacy PE ≤120 also accepted.
Renewable energy generation (per footprint)	`—`	`≥ 60 kWh/m²a`	`≥ 120 kWh/m²a`	Off-site systems allowed if owner-held + new

ℹ

PER vs PE: PER (Primary Energy Renewable) is the new method introduced in 2015. It accounts for the renewable fraction of the energy mix. PE (non-renewable primary energy) ≤120 kWh/m²a is still valid for Classic only (transitional). PHI may specify national PE values. ACT, for example, has near-zero-carbon grid — this dramatically shifts which pathway is optimal.

General Minimum Criteria — All Standards (Section 2.4) NON-NEGOTIABLE ▶

OVERHEATING (2.4.1)

Scenario	Max hours >25°C per year
Without active cooling	≤ 10%
With active cooling	Cooling system must be adequately dimensioned

HUMIDITY (2.4.2)

Scenario	Max hours absolute humidity >12 g/kg per year
Without active cooling/dehumidification	≤ 20%
With active cooling	≤ 10%

MOISTURE PROTECTION — fRsi (2.4.3)

Climate Zone	Min fRsi	Meaning
Arctic	0.80	Most stringent
Cold	0.75	—
Cool-temperate	0.70	Sydney, Melbourne, Adelaide
Warm-temperate	0.65	—
Warm	0.55	—
Hot	—	No fRsi requirement
Very Hot	—	No fRsi requirement

fRsi = Rsi / RT — applies to each individual component; no averaging. Condensation risk at surface temp <9.3°C; mould risk <12.6°C (per psychrometric chart).

THERMAL COMFORT — Minimum Surface Temperatures (2.4.3)

For arctic to warm-temperate climates: Interior surface temperatures of walls and ceilings may not be more than 4.2 K below operative indoor temp. Floor surface may not fall below 19°C. Checked at 22°C indoor with minimum outdoor temp from climate data. For warm-to-very-hot: ceiling U-values only (≤ EnerPHit window requirement for same inclination).

OCCUPANT SATISFACTION (2.4.4)

All rooms with prolonged occupancy must have ≥1 operable window
User must be able to operate lighting and temporary shading. User control takes priority over automation.
With active heating/cooling: user must be able to regulate interior temperature per utilisation unit
Heating/cooling system must be suitably dimensioned for all expected conditions
Ventilation: adjustable flow, ≤25 dB(A) in supply air rooms (residential), ≤30 dB(A) in functional rooms, no uncomfortable draughts
If RH <30% predicted: humidification or moisture recovery required

PH Component U-Value Criteria by Climate Zone — All Climates Worldwide DESIGN ▶

Climate Zone	Roof/Wall (ext. ins.)	Wall (int. ins.)	Against Ground	Window Overall Uw	Window (installed Uw,inst)	HRV Heat Recovery	Cool Colours?
Arctic	0.09	0.25	Det. PHPP	0.50	0.60	≥80%	No
Cold	0.12	0.30	Det. PHPP	0.70	0.80	≥80%	No
Cool-temperate ★	0.15	0.35	Det. PHPP	1.00	1.10	≥75%	No
Warm-temperate	0.30	0.50	Det. PHPP	1.10	1.20	≥75%	No
Warm	0.50	0.75	Det. PHPP	1.30	1.40	≥100%	No
Hot	0.50	0.75	Det. PHPP	1.30	1.40	≥100%	YES (SRI flat ≥90, sloped ≥50)
Very Hot	0.25	0.45	Det. PHPP	1.10	1.20	≥100%	YES

★ Cool-temperate = Sydney, Melbourne, Adelaide, Perth, ACT — the most common Australian context. “Interior insulation” only applies to exterior walls; not roofs/floors/slabs. Average U-value across whole building is sufficient — area-weighted mean, not average thickness.

⚠

Glazing solar criterion — heated buildings: Ug − g × 1.6 ≤ 0 (cool-temperate). This means: for Ug = 1.0, need g ≥ 0.625. Ensures glazing contributes net solar gain in winter. For cooling-dominated buildings (>15 kWh/m²a sensible cooling), a maximum specific solar load during cooling period also applies.

PHPP Boundary Conditions for Calculation PHPP ▶

Parameter	Value
Indoor heating setpoint (residential)	20°C (no night setback)
Cooling / dehumidification setpoint	25°C / 12 g/kg absolute
Internal heat gains (residential)	2.1 W/m² (default)
Internal heat gains (assisted living)	4.1 W/m²
Internal heat gains (offices)	3.5 W/m²
Internal heat gains (schools)	2.8 W/m²
Internal moisture (residential)	100 g/person·h
Internal moisture (offices)	10 g/person·h
DHW demand (residential)	25 L/person/day at 60°C
Ventilation (residential)	20–30 m³/h per person, min 0.30 ACH TFA×2.5m
Ventilation (non-res)	15–30 m³/h per person (project specific)

PER FACTORS (Location-dependent)

End Use	Typical PER Factor
Household electricity	1.30
Domestic hot water	1.30
Heating	1.80
Cooling	1.05
Dehumidification	1.25

💡

Practical implication: Heating has the highest PER factor (1.80). 15 kWh/m²a heating demand × COP 3 heat pump = 5 kWh/m²a electricity × 1.80 = 9 kWh/m²a PER. This is why super-efficient envelopes matter more than system efficiency alone.

GERMAN vs SYDNEY REFERENCE DATA

Parameter	Germany (PHPP default)	Sydney
Heating degree hours G_T	82 kKh/a	49 kKh/a
Heating days H_T	219 d/a	168 d/a

PHI Certification Process — Documents Required (Section 3.2) CERTIFICATION ▶

REQUIRED PHPP WORKSHEETS

Verification (property data, summary)
Climate (dataset selection)
U-values (regular building components)
Areas (areas + thermal bridges)
Ground (if applicable)
Components (database)
Windows (Uw values)
Shading (coefficients)
Ventilation (air quantities, HRV, n50)
Heating + Heating Load
SummVent + Summer (overheating)
Cooling + Cooling Units + Cooling Load (if active)
DHW + Distribution
SolarDHW (if applicable)
PV (if applicable)
Electricity (residential)
Aux Electricity
IHG (internal heat gains)
PER and PE value

MANDATORY NON-PHPP DOCUMENTS

Site plan + orientation + shading elements
Floor plans, sections, elevations with dimensions
TFA calculation (treated floor area)
All connection/junction details (insulation + airtight layer shown)
Thermal bridge Ψ + χ values with evidence (EN ISO 10211)
Window location plans + frame/glazing data sheets
Ug to EN 673, g-value to EN 410, Uf to EN ISO 10077-2
HRV system plans + commissioning report (flow rates, balance ≤10% imbalance)
Heating/cooling/DHW system description + data sheets
Airtightness test report (EN 13829 Method A or ISO 9972 Method 1)
Photographs of construction progress
Construction manager’s declaration

⚠

Airtightness test: Both positive AND negative pressure required. Independent tester preferred. Must test only the heated envelope (exclude porches, unheated conservatories). Recommend testing while airtight layer still accessible.

🔄

EnerPHit is for retrofits only. Cannot be issued for new builds. Where Passive House is uneconomical or impossible due to existing building constraints (heritage, physical limitations, cost), EnerPHit provides a certified upgrade pathway using Passive House components.

EnerPHit — Two Compliance Methods (meet ONE)

METHOD 1: Component Method (Table 2)

Each building component meets the climate-zone-specific U-value criterion. Must comply as an average across the whole building (area-weighted mean U-values). Higher U-value in one area compensated by better performance elsewhere.

Key advantage: No PHPP energy demand modelling required. Simpler to document. Suitable for incremental retrofits.

METHOD 2: Energy Demand Method (Table 3)

Whole-building heating demand meets climate-specific threshold in PHPP. More flexible for buildings where component criteria are genuinely impossible.

Key advantage: Can compensate poor components with excellent others. Better for complex existing buildings.

EnerPHit — Component Method U-Value Criteria by Climate Zone

Climate Zone	Roof/Wall (ext.ins.)	Wall (int.ins.)	Against Ground	Window Uw (overall)	Window (installed)	Window glazing criterion	Solar load max
Arctic	0.09	0.25	Det. PHPP	0.50	0.60	Ug − g×0.7 ≤ 0	—
Cold	0.12	0.30	Det. PHPP	0.70	0.80	Ug − g×1.0 ≤ 0	—
Cool-temperate ★	0.15	0.35	Det. PHPP	1.00	1.10	Ug − g×1.6 ≤ 0	—
Warm-temperate	0.30	0.50	Det. PHPP	1.10	1.20	Ug − g×2.8 ≤ −1	—
Warm	0.50	0.75	Det. PHPP	1.30	1.40	—	—
Hot (cool colours)	0.50	0.75	Det. PHPP	1.30	1.40	—	60% (humid)
Very Hot (cool colours)	0.25	0.45	Det. PHPP	1.10	1.20	—	60% (humid)

EnerPHit — Energy Demand Method (Alternative to Component Method)

Climate Zone	Max Heating Demand kWh/m²a	Max Cooling + Dehum Demand
Arctic	35	Equal to Passive House requirement
Cold	30
Cool-temperate ★	25
Warm-temperate	20
Warm	15
Hot	—	Equal to PH requirement
Very Hot	—	Equal to PH requirement

EnerPHit Exemptions — When U-Value Limits Can Be Exceeded RETROFITS ▶

U-value limits may be exceeded in the following circumstances. Each exemption requires documented evidence and must be the minimum deviation possible.

Exemption Trigger	Requirement if Exempted
Heritage preservation authority requires it	If insulation thickness is restricted, use high-performance material λ ≤ 0.025 W/mK if cost-effective + damage-free. For floor slabs/basement ceilings, add perimeter insulation skirt if economically viable.
Cost-effectiveness no longer assured (exceptional circumstances)
Legal requirements prevent compliance
Would unacceptably restrict use of building or adjacent outdoor areas
Special fire safety requirements + no compliant product exists
Window U-value increased due to high Ψ of window installation in interior-insulated wall
Damage-free construction only possible with thinner interior insulation
Other compelling construction reasons

⚠

If exemptions result in failure to achieve any reduction in heating/cooling demand, the certifier may issue written confirmation of the value achieved rather than an EnerPHit certificate. The airtightness n₅₀ ≤1.0 is still required even with exemptions.

EnerPHit AIRTIGHTNESS

n₅₀ Result	Status	Additional Requirement
≤ 0.6 h⁻¹	Meets Passive House standard	None beyond standard test
0.6 to 1.0 h⁻¹	EnerPHit acceptable	Leakage detection mandatory: search at negative pressure, seal all significant leaks, written confirmation signed by responsible person
> 1.0 h⁻¹	FAIL EnerPHit	Must improve before certification

Pre-Certification for Stepwise Retrofit (Section 3.3) STAGED WORKS ▶

Multi-stage retrofits can be pre-certified after the first step, giving owners and financiers certainty the final standard will be achieved. Requires an EnerPHit Retrofit Plan (ERP).

Pre-certification triggers (any one of):

ERP and first step documents submitted + first step completed per ERP
≥20% reduction of PER or PE primary energy demand, OR
≥20% or 40 kWh/m²a reduction of heating or cooling+dehum demand (whichever was higher initially)
At least one complete unit retrofitted in multi-owner building
New extension erected per ERP
Leakage detection completed after any work affecting airtightness

Retrofit sequence flexibility:

Components in any order: e.g. Step 1: wall insulation → Step 2: windows + HRV → Step 3: roof + heating system. OR by building sections. Key constraint: moisture risk must not increase at any intermediate state.

PHI Low Energy Building Standard

ℹ

The PHI Low Energy Building Standard is a certified intermediate level — suitable where full PH is not achievable. Thermal comfort criteria (2.4.3) do NOT apply, but moisture protection requirements (2.4.3) DO still apply.

Criterion	Limit	Unit	Alternative
Heating demand	≤ 30	kWh/m²a	—
Cooling + dehumidification demand	≤ PH requirement + 15	kWh/m²a	—
Airtightness n₅₀	≤ 1.0	h⁻¹	—
PER demand	≤ 75	kWh/m²a	Exceeding up to +15 permitted if compensated by additional generation. Legacy: PE ≤120.
Renewable energy generation	—	—	No minimum requirement (vs PH Plus/Premium)

U-Value Calculation — λ, R, RT, U FOUNDATION ▶

Thermal Conductivity λmaterial property

λ = d / R [W/(mK)]

d = thickness [m]
R = thermal resistance [m²K/W]
λ is a fixed material property — does NOT change with thickness

R-Value (Heat Transfer Resistance)single layer

R = d / λ [m²K/W]

Example

200mm of mineral wool (λ=0.040): R = 0.20 / 0.040 = 5.0 m²K/W

Total Heat Transfer Resistance RTfull assembly

RT = Rsi + R₁ + R₂ + R₃ + Rse RT = Rsi + (d₁/λ₁) + (d₂/λ₂) + (d₃/λ₃) + Rse [m²K/W]

Rsi = 0.13 (vertical wall, horizontal heat flow)
Rsi = 0.10 (ceiling, upward flow)
Rsi = 0.17 (floor, downward flow)
Rse = 0.04 (exterior exposed to ambient air)
Rse = 0.13 (ventilated cavity — treat as internal)

U-Value (Heat Transfer Coefficient)final result

U = 1 / RT = 1 / (Rsi + Σ(d/λ) + Rse) [W/m²K]

Worked Example — Wall: 110mm concrete + 300mm mineral wool + 20mm plaster

RT = 0.13 + (0.11/1.00) + (0.30/0.040) + (0.02/0.70) + 0.04
RT = 0.13 + 0.11 + 7.5 + 0.03 + 0.04 = 7.81 m²K/W
U = 1/7.81 = 0.128 W/m²K ✓ (PH cool-temperate: ≤0.15)

Thermal Bridges — Ψ (psi) Linear + χ (chi) Point BRIDGES ▶

Linear Thermal Bridge Ψwindow edge, floor junction

Ψ = ΔU / l [W/mK] Q_T = l × Ψ × ft × GT [kWh/a] (demand) P_T = l × Ψ × ft × ΔT [W] (load)

PH thermal bridge free: Ψ ≤ 0.01 W/mK
Negative Ψ = credit (e.g. external corner)
GT = heating degree hours [kKh/a]
ft = correction factor (1.0 ambient, ~0.5-0.7 against ground)

Example — Annual heat loss

Ψ=0.2 W/mK, l=20m, GT=80 kKh/a, ft=1
Q_T = 20 × 0.2 × 1 × 80 = 320 kWh/a

Point Thermal Bridge χ (chi)balcony anchor, fixing

χ = ΔU / A [W/K] Q_T = n × χ × ft × GT [kWh/a] (demand) P_T = n × χ × ft × ΔT [W] (load)

PH thermal bridge free: χ ≤ 0.01 W/K
n = quantity of point bridges [-]
A = area of building element [m²]

Example — Balcony anchors

4 anchors × χ=0.05 W/K × 1 × 78 kKh/a
Q_T = 4 × 0.05 × 1 × 78 = 15.6 kWh/a

TB-Free Building CheckPHPP verification

Σ(l × Ψ) + Σ(n × χ) ≤ 0.0 W/K

Sum of ALL linear and point TBs must equal zero or negative. Negative TBs (external corners) provide credits.

ESTIMATING A THERMAL BRIDGE FROM U-VALUE CHANGE

Point TB from U-value change

χ = ΔU / A = (U_old − U_new) × A / A

Linear TB from U-value change

Ψ = ΔU / l = (U_old − U_new) × A / l

Increase / Decrease Insulation Thickness — 4-Step Method DESIGN TOOL ▶

FROM HEATING DEMAND (kWh/a)

Step 1: ΔU = ΔQ_T / (A × ft × GT) [W/m²K] Step 2: U_new = U_old − ΔU (improve: subtract) Step 3: ΔR = 1/U_new − 1/U_old [m²K/W] Step 4: Δd = ΔR × λ [m]

Example — compensate thermal bridge

ΔQ_T=250 kWh/a, A=100m², ft=1, GT=80 kKh/a
ΔU = 250/(100×1×80) = 0.0313 W/m²K
U_new = 0.12 − 0.031 = 0.089 W/m²K
ΔR = 1/0.089 − 1/0.12 = 2.903 m²K/W
Δd = 2.903 × 0.040 = 0.116m → +11.6cm insulation

FROM HEATING LOAD (W)

Step 1: ΔU = ΔP_T / (A × ft × Δt) [W/m²K] Step 2: U_new = U_old ± ΔU Step 3: ΔR = 1/U_new − 1/U_old [m²K/W] Step 4: Δd = ΔR × λ [m]

Example — reduce thickness due to internal gain

ΔP_T=100W gain, A=200m², ft=1, Δt=20−(−5)=25K
ΔU = 100/(200×1×25) = 0.02 W/m²K
U_new = 0.12 + 0.02 = 0.14 W/m²K (can relax)
ΔR = 1/0.14 − 1/0.12 = −1.19 m²K/W
Δd = −1.19 × 0.040 = −0.048m → −4.8cm

Window U-Values, Solar Balance & Inside Surface Temperature WINDOWS ▶

Window Geometry

w_g = w_w − (2 × w_f) h_g = h_w − (2 × h_f) A_w = w_w × h_w A_g = w_g × h_g A_f = A_w − A_g l_g = 2 × (w_g + h_g) (glazing perimeter = spacer) l_w = 2 × (w_w + h_w) (window install perimeter)

Overall Window U-Value Uw

U_w = [(A_g×U_g) + (A_f×U_f) + (l_g×Ψ_g)] / A_w U_w,inst ≈ [(A_g×U_g)+(A_f×U_f)+(l_g×Ψ_g)+(l_w×Ψ_w)] / A_w

U_g = glazing U-value [W/m²K]
U_f = frame U-value [W/m²K]
Ψ_g = glazing edge (spacer) thermal bridge [W/mK]
Ψ_w = window installation thermal bridge [W/mK]

Example — 1.2×2.4m window

U_g=0.60, U_f=0.70, Ψ_g=0.02, Ψ_w=0.03
A_g=2.074m², A_f=0.806m², l_g=6.24m, l_w=7.2m, A_w=2.88m²
U_w = (2.074×0.60 + 0.806×0.70 + 6.24×0.02) / 2.88
U_w = 0.671 W/m²K | U_w,inst = 0.746 W/m²K

Window Energy Balancenet annual

Q_H,window = Q_T,window − Q_S Q_T = A_w × U_w × ft × GT [kWh/a] Q_S = A_g × g × r × G_S [kWh/a] r = r_shading × r_dirt × r_incidence = 0.75 × 0.95 × 0.85 = 0.605 (all defaults)

Example — west window, cool-temperate (GT=79 kKh/a)

A_w=2.6m², U_w=1.2, g=0.5, r_f=0.70, G_west=233 kWh/m²a
Q_T = 2.6×1.2×1×79 = 246.5 kWh/a (loss)
A_g = 2.6×0.70 = 1.82m²
r = 0.70×0.95×0.85 = 0.565
Q_S = 1.82×0.5×0.565×233 = 119.8 kWh/a (gain)
Net = 246.5 − 119.8 = 126.7 kWh/a loss

Inside Surface Temperaturemould / condensation check

T_si = T_i − (U × R_si × ΔT) ΔT = T_i − T_e

Example

T_i=20°C, T_e=−10°C, U=2.8 W/m²K, R_si=0.13
T_si = 20 − (2.8 × 0.13 × 30) = 20 − 10.92
T_si = 9.08°C — WARNING: <12.6°C mould risk!

THE MAGIC FORMULA — Heat Energy Transport (Demand & Load) MASTER FORMULA ▶

Universal Heat Energy TransportH_ET = D × P_D × f × C

H_ET = D × P_D × f × C → DEMAND [kWh/a] h_ET = (D × P_D × f × C) / TFA → SPECIFIC DEMAND [kWh/m²a] h_ET = (D × P_D × f × C) / TFA → SPECIFIC LOAD [W/m²]

EXPANDED FORMS BY ELEMENT TYPE

Element	Demand Form [kWh/a]	Load Form [W]	C (climate)
⊙ Point TB	Q = n × χ × ft × GT	P = n × χ × ft × ΔT	GT [kKh/a] or ΔT [K]
│ Linear TB	Q = l × Ψ × ft × GT	P = l × Ψ × ft × ΔT	GT or ΔT
□ Building element (wall/roof/floor)	Q = A × U × ft × GT	P = A × U × ft × ΔT	GT or ΔT
□ Solar gains (glazing)	Q = A_g × g × r × G_S	P = A_g × g × r × G_1or2	G_S [kWh/m²a] or G_1or2 [W/m²]
⬡ Ventilation + infiltration	Q = V_vent × c_p,air × ft × GT	P = V_vent × c_p,air × ft × ΔT	GT or ΔT

Annual Space Heat Demand QH (Total)WINTER [kWh/a]

Q_H = (Q_TX + Q_TΨ + Q_TU) + (Q_VDA + Q_V50) − η × (Q_Sg + Q_i) Losses: transmission TBs + opaque elements + ventilation + infiltration Gains: solar gains (glazing) + internal heat gains η = utilisation factor (typically 0.9–1.0 for well-balanced PH)

Airtightness — Blower Door Test, n₅₀, Leakage Area TESTING ▶

n₅₀ Air Change Rate

n₅₀ = V₅₀ / V_building [h⁻¹]

V₅₀ = measured airflow at 50 Pa [m³/h]
V_building = net air volume — finish to finish, excluding internal walls, internal doorways, separating floor levels [m³]

Example

V₅₀ = 262.845 m³/h, V_bldg = 405 m³
n₅₀ = 262.845/405 = 0.649 h⁻¹ ✓ (just compliant)

Estimate n₅₀ from Different Pressure

n₅₀ = (n_x / x) × 50 [h⁻¹] V₅₀ = (V_x / x) × 50 [m³/h]

Example — measured at 40Pa

n_40 = 0.8, x = 40
n₅₀ = (0.8/40) × 50 = 1.0 h⁻¹ (linear estimate only)

Effective Leakage Area

A_50leak = 0.5 [cm²h/m³] × V₅₀ [m³/h] [cm²]

Example — PH with 98 m³/h leakage

A_50leak = 0.5 × 98 = 49 cm² (≈7cm × 7cm square)

BLOWER DOOR QUALITY CHECKLIST

n₅₀ > 40: likely error — check windows/volume
Building Leakage Curve exponent: 0.5 < n < 1.0
Correlation coefficient r²: > 0.98
Air Leakage Graph: straight line, good spread
Positive vs negative pressure difference: <15%
Envelope area > 3× footprint area (sanity check)
No artificial sealing (taping holes etc.)

Ventilation Sizing, HRV, Supply Air Heating/Cooling HVAC ▶

Design Air Flow Rate

SA = N × 30 m³/h (supply — by persons) EA = Ki×60 + Ba×40 + WC×20 (extract — by room) MA = TFA × 2.5m × 0.3 × 1.3 (minimum — by volume) VDA = max(SA, EA, MA) [m³/h] (Design = 100%) Standard = VDA × 0.77 (commissioning) Basic = VDA × 0.54 (holiday mode)

Example — 150m² home, 5 people, 1B/2WC/1Ki

SA=150 · EA=160 · MA=146.25
VDA = 160 m³/h (EA governs)

Max Supply Air Heating/Cooling Power

p_heating = V × c_p,air × ft × ΔT / A ΔT = T_supply,max − T_supply,min (max 52°C supply) p_cooling = V × c_p,air × ft × ΔT / A ΔT = T_supply − T_room (e.g. 15°C supply, 25°C room → ΔT=10K)

Example — heating check

V=30m³/h per person, c_p=0.33, ΔT=52−20=32K, A=30m²
p = (30×0.33×1×32)/30 ≈ 10.6 W/m² ≈ 10 W/m²
This is why PH heating load limit is 10 W/m² — it’s the max deliverable via supply air!

HRV SYSTEM REQUIREMENTS (PH)

Parameter	Requirement
Heat recovery efficiency	η ≥ 75%
Electricity demand	P_el ≤ 0.45 Wh/m³
Imbalance ODA/EHA	≤ 10%
Intake filter (outdoor air)	F7 (HEPA-class)
Extract air filter	G4
Noise — habitable rooms	≤ 25 dB(A)
Noise — functional rooms	≤ 30 dB(A)
Noise — unit room	≤ 35 dB(A)
Frost protection	Required: air, subsoil, brine, or electric pre-heater
Min supply air temp	T_SUP ≥ 16.5°C

Heat Pump COP + Profitability Calculations ECONOMICS ▶

Heat Pump COP

COP_HP = W_T / W_E,HP [-] COP_system = (COP_HP × W_E,HP) / (W_E,HP + W_E1 + W_E2 …)

Example — 1500W thermal load, COP 3

W_E,HP = 1500/3 = 500W = 0.5 kW
With 50W extra pump:
COP_system = (3×500)/(500+50) = 2.72

Profitability — Project Comparison

C_convent = Q_H,convent × C_E [$/a] C_PH = Q_H,PH × C_E + a_loan × (I_add − R) + ΔZ [$/a] Profitable if: C_PH ≤ C_convent

Example — 200m² PH vs conventional

Conventional: 20,000kWh×$0.25 = $5,000/a
PH: 2,000×$0.25 + 0.0512×(50,000−18,958)
C_PH ≈ $2,089/a < $5,000/a ✓ profitable

QUICK FINANCE FORMULAS

Formula	Equation	Use
Future value	K_n = K_0 × (1+p)^t	Compounding investment
Present value	K_0 = K_n × (1+p)^−n	Discounting future cash
Net present value of annuity	K_0 = A × (1−(1+p)^−n) / p	What is annual saving worth today?
Annuity factor a	a = p / (1−(1+p)^−n)	Annual payment from lump sum
Real interest rate	p_real = (1+p_nom)/(1+i) − 1	Inflation-adjusted rate
Residual value	R = (1 − a_life × B_invest) × I_add	Remaining value at end of loan

All λ values in W/(mK). Lower = better insulator. Colour coding: excellent (<0.025) / great (0.025–0.045) / good (0.045–0.08) / standard / poor (>0.5)

HIGH PERFORMANCE INSULATION

Vacuum Insulated Panel (VIP)0.002–0.008

Aerogel blanket0.017–0.021

Rigid PUR/PIR foam boards0.023–0.040

XPS (Extruded Polystyrene)0.030–0.040

EPS (Expanded Polystyrene)0.035–0.040

Mineral wool (rock/fibreglass batt)0.035–0.045

Sheep wool0.035–0.045

Fibre insulating material0.035–0.050

Fibreglass (blown fibres)0.038–0.039

Cellulose (blown fibres)0.039–0.050

Flax / hemp board0.040

Coconut fibre0.040–0.050

Wooden softboard0.040–0.050

Corkboard0.042

Cellular glass0.045–0.060

NATURAL / ALTERNATIVE MATERIALS

Strawbale (baled straw)0.060–0.075

Carpet0.060

Plywood0.080–0.110

MDF (medium density fibreboard)0.070–0.180

Chipboard / particleboard0.100–0.180

OSB (oriented strand board)0.130

Softwood (pine, spruce)0.130

Hardwood (oak, jarrah)0.180

Rammed earth / adobe0.300–1.0 (varies)

BUILDING STRUCTURE MATERIALS

Lightweight concrete0.150–0.300

Gypsum plasterboard0.250

Gypsum plaster0.180–0.560

Vert. perforated lightweight masonry0.300–0.450

Solid clay brick masonry0.800–1.200

Sand-lime masonry1.000

Float glass1.000

Cement screed1.400

Natural stone1.500–3.500

Concrete (reinforced)2.100

METALS (thermal bridges)

Stainless steel17

Mild / structural steel50

Aluminium160

Copper380

GROUND / SOIL TYPES (PHPP)

Soil Type	λ [W/mK]	Heat Capacity pc [MJ/m³K]
Silt / Clay	1.5	3
Peat	0.4	3
Dry Sand / Gravel	1.5	1.5
Wet Sand / Moist Clay	2.0	2
Saturated Clay	3.0	3
Rock	3.5	2

💡

Key relationship: To achieve PH wall U ≤ 0.15 W/m²K with mineral wool (λ=0.040): R needed = 1/0.15 − 0.17 = 6.5 m²K/W. Thickness = 6.5 × 0.040 = 0.26m (260mm) of mineral wool, excluding surface resistances. With aerogel (λ=0.018): same U in only 117mm.

✓

Key legal basis: A certified Passive House building complies with NCC 2022 Section J/H6 via the Performance Solution pathway (A2G2). Passive House performance substantially exceeds all NCC minimum energy requirements. The NCC blower door threshold of 10 m³/hr.m² ≈ 10 ACH50 — Passive House requires ≤0.6 ACH50, which is 16× more stringent.

Compliance Bridge — Which NCC Clause Each PH Element Satisfies

PH Element / Criterion	NCC Vol 2 Clause	NCC Vol 1 Clause	Compliance Path	NCC Threshold	PH Standard	Verdict
Heating demand ≤15 kWh/m²a	H6P1 / Spec 44	J1P2	Performance Solution via PHPP	~30–45 kWh/m²a (7★)	≤15 kWh/m²a	EXCEEDS ✓
Whole-of-home energy ≤70%	H6P2	J1P3	Performance Solution or NatHERS software	70% of ref bldg	PER ≤60 kWh/m²a	EXCEEDS ✓
Airtightness n₅₀ ≤0.6 h⁻¹	H6V3 test	J1V4 test	DtS + blower door test per AS/NZS ISO 9972	≤10 m³/hr.m² (~10 ACH50)	≤0.6 h⁻¹ (ACH50)	16× BETTER ✓
HRV with ≥75% efficiency	If n₅₀<5 m³/hr.m²: H6V3(2) — mandatory MVHR	J1V4(2)	MVHR at PH level satisfies NCC mech. vent. requirement	Q ≥ 0.05A+3.5(N+1)/p	30 m³/h per person	EXCEEDS ✓
Solar PV readiness	—	J9D5	DtS — switchboard + 20% roof clear	20% roof area + switchboard	PH Plus: ≥60 kWh/m²a gen.	PH Plus EXCEEDS ✓
EV charging infrastructure	—	J9D4	DtS — must comply regardless of PH certification	100% Class 2 spaces EV-ready	Not a PH criterion	SEPARATE OBLIGATION
Livable housing design	H8P1	—	DtS — ABCB LHD Standard	Step-free entry, accessible WC/shower	Not a PH criterion	SEPARATE OBLIGATION
Bushfire construction HAL	H7P5 / AS 3959	—	DtS — AS 3959 BAL rating	BAL determined by site	Not a PH criterion	SITE DEPENDENT
Condensation / mould risk	H4P7 / H4V5 (AIRAH DA07)	F8P1	PH moisture protection (fRsi) more rigorous	Mould index ≤3 (AIRAH DA07)	fRsi ≥0.70 (cool-temp), T_si ≥12.6°C	PH MORE STRINGENT ✓
Thermal bridges	J3D5/J3D6 (thermal breaks)	J4D3 (general)	PH TB-free approach far exceeds NCC thermal break minimum	R0.2 thermal breaks only	Ψ ≤ 0.01 W/mK all connections	EXCEEDS ✓

Development Type Recommendations

NEW RESIDENTIAL — Class 1a (Houses)

Target NatHERS ≥ 8 stars (NCC min = 7 avg / 6 individual)
Prioritise: envelope U-values → airtightness → glazing → thermal bridges
Consider PH Classic certification via Performance Solution A2G2
All-electric + HPWH + solar PV → easily beats H6P2 70% cap
H8 livable housing: design in from day 1 — floor level access, 820mm clear doorways, grab rail-ready walls
If bushfire zone: HAL assessment early → affects wall construction, window type
Climate zone dictates insulation and glazing strategy before any other decisions

NEW RESIDENTIAL — Class 2 (Apartments)

NatHERS: 7★ average, 6★ minimum per SOU — model each individually
100% carpark EV-ready (J9D4) — design electrical infrastructure from concept
Solar PV switchboard pre-wiring (J9D5) — specify day 1
Centralised HPWH system beats distributed gas for H6P2 compliance
Consider NABERS 4★ apartments or Green Star pathway for premium projects
>2500m² common area: full BMS sub-metering mandatory
Cross-ventilation design: PH HRV system in SOUs + natural vent strategy in corridors

COMMERCIAL — Class 5 Office

Energy budget: ≤43 kJ/m².hr conditioned — achieve via good envelope + HVAC
NABERS 5.5★ Base Building Commitment Agreement = NCC J1P1 compliance (J1V1)
Green Star Design & As-Built = NCC J1P1 compliance if GHG <90% of reference (J1V2)
IPD: office 4.5 W/m² — daylight sensors reduce to effective ~2.25 W/m²
EV: 10% of carpark spaces pre-wired to 7kW Type 2
BMS mandatory at >2500m²: HVAC, lighting, appliances, renewables all sub-metered
PH Classic for offices is achievable — used in European office campuses

RETROFIT — EnerPHit Strategy

Choose Component Method or Energy Demand Method — whichever suits existing building
Cool-temperate: wall U ≤0.15, windows ≤1.00 Uw, airtightness ≤1.0 h⁻¹
Stage works under EnerPHit Retrofit Plan — pre-certification available after first step
Heritage buildings: document why components can’t meet criteria — exemptions available
Airtightness 0.6–1.0 h⁻¹: leakage detection mandatory, seal all significant leaks
NCC: Performance Solution with PHPP evidence satisfies both BCA and PH criteria
Window upgrades deliver largest payback in cool-temperate — prioritise south-facing insulation and north-facing solar gain

Common Design Conflicts & Resolutions

Conflict	NCC Requirement	PH Requirement	Resolution
HRV + NCC ventilation rates	H6V3(2): If <5m³/hr.m², must provide MVHR with formula Q=0.05A+3.5(N+1)/p	30 m³/h per person, min 0.3 ACH × VV × 1.3	Design MVHR for the greater of NCC formula and PH VDA. Usually PH governs for residential. Document both calculations.
Gas combustion appliances in sealed buildings	H6V3(2)(c): Gas appliances need permanent openings ≥ half flue cross-section	PH discourages combustion in sealed envelope	Remove all gas from sealed PH envelope. All-electric MVHR approach. If gas fireplace is design requirement: specify room-sealed balanced flue unit. Document ventilation opening per AS/NZS 5601.1.
Solar PV roof clearance vs green roof	J9D5: 20% of roof clear for PV unless exemptions apply	PH Plus/Premium: ≥60/120 kWh/m²a generation from building footprint	Exemption applies if PV installed on ≥20% of roof OR if >50% of roof is “roof garden”. Design integrated PV + green roof zones. Facade-mounted PV counts for PH generation metric.
Thermal mass vs insulation layer order	NCC J3D7(4): Vapour permeance of continuous insulation ≥ primary insulation layer (when n₅₀<5 m³/hr.m²)	Exterior insulation preferred — maintains thermal mass inside envelope	Design exterior-insulated walls with thermal mass inside. Continuous insulation above primary layer: ensure vapour permeance ≥ primary layer (no vapour trap). Document with dew point analysis per AIRAH DA07.
NatHERS vs PHPP — which governs?	H6D2: NatHERS certificate required for DtS Option 1	PHPP required for PHI certification	Run both. PHPP is the primary design tool. Run NatHERS to generate the NCC-required NatHERS certificate (A5G9). Results will differ — NatHERS tends to be more conservative on infiltration assumptions. PHPP result used for PHI; NatHERS certificate used for building approval.

U-VALUE CALCULATOR

Add up to 5 layers. Surface resistances auto-applied for vertical wall.

Rsi Rse

INSULATION THICKNESS FOR TARGET U-VALUE

How thick does insulation need to be to achieve a target U-value?

Target U [W/m²K]

λ insulation [W/mK]

R of other layers [m²K/W]

Rsi + Rse total [m²K/W]

n₅₀ AIRTIGHTNESS CALCULATOR

Measured V₅₀ [m³/h]

Net air volume V_bldg [m³]

WINDOW ENERGY BALANCE CALCULATOR

Window area A_w [m²]

U-value Uw [W/m²K]

g-value (SHGC) [-]

Glazing fraction r_f [-]

G_S solar radiation [kWh/m²a]

Degree hours G_T [kKh/a]

Adding New Documents to This Knowledge Base

HOW TO EXPAND THIS KNOWLEDGE BASE

This document is designed as a living knowledge base. To add new green building systems, standards, or technical references:

Upload the new document and request it be “added to the knowledge base”
New content will be analysed and integrated as new tabs or sections in the appropriate category
Currently integrated: NCC 2022 (Vols 1–3 + Amdt 2) · PHI Passive House Criteria v9f · CPHD Formula Sheet (Michael McElligott)
Planned additions: PHPP worksheets detail · NatHERS climate data · Green Star scorecard · NABERS methodology · EnerPHit retrofit case studies · Australian climate zone maps

National Construction Code · Australia

NCC 2022
Building Code

The National Construction Code — Australia’s legal minimum for construction. Thermal performance, energy efficiency, airtightness, EV-readiness, and the 2025 Amendment 2 updates. Presented independently of any green building analysis.

⚠

Amendment 2 in force from 29 July 2025: AS 1428.1–2021 replaces 2009 edition. Affects D3D22 (handrails), D4D4 (ramps/stairways — carpet thickness requirements DELETED), E1D2 (Vol 3). Zero changes to energy, water, or sustainability provisions.

NCC Structure, Volumes & Compliance Pathways FOUNDATION ▶

Volume One (BCA)

Class 2–9 buildings: Multi-residential, commercial, industrial, institutional. Plus disability access for Class 1b and 10a. Contains Section J energy efficiency — the primary commercial green building energy code.

Volume Two (BCA)

Class 1 and 10 buildings: Detached/semi-detached dwellings, garages, sheds. Contains Part H6 (energy efficiency), H8 (livable housing — from 1 Oct 2023), and H7 (bushfire, alpine, pools).

Volume Three (PCA)

Plumbing and drainage — all building classes, new AND existing work. Covers cold water, heated water (solar/heat pump mandatory for pools), non-drinking water, rainwater (B6), sanitary, stormwater, on-site wastewater.

COMPLIANCE PATHWAYS (A2G1–A2G4)

Pathway	Method	Assessment Tools	Green Building Application
Deemed-to-Satisfy	Follow prescriptive provisions exactly	Evidence of suitability, Expert Judgement	Fast approval but may constrain innovation
Performance Solution	Demonstrate equivalence to Performance Requirements directly	Verification Method, Evidence of Suitability, Expert Judgement, Comparison with DtS	ENABLES: Passivhaus, rammed earth, straw bale, radiant floors, earth-sheltered — anything demonstrably equivalent or better
Combined Solution	Mix of DtS and Performance Solution per element	Both above	Most common for innovative green buildings — standard structure + performance-proved energy systems

🔬

Performance Solution process (A2G2): 1) Prepare performance-based design brief with stakeholders → 2) Analysis → 3) Evaluate against acceptance criteria → 4) Final report documenting all Performance Requirements, Assessment Methods used, conditions/limitations. A Certified Passive House building satisfies NCC Section J via this pathway.

Building Classifications & Energy Obligations CRITICAL ▶

Class	Type	Volume	Energy Budget (conditioned)	Key Green Obligations
1a	Detached/semi/terrace house	Vol 2	NatHERS load limits per Spec 44	H6P1/P2 (7★ avg, 6★ min), H8 livable housing, H6V3 sealing test
2	Apartment building	Vol 1	J1P2/P3 per Spec 44 (SOUs)	100% EV-ready carpark, 7★ avg / 6★ min NatHERS SOUs, NABERS/Green Star pathway
3	Hotel, hostel, residential	Vol 1	≤ 15 kJ/m².hr	J1P1 energy budget, EV 20% of spaces, NABERS Hotels 4★ option
4	Dwelling in commercial bldg	Vol 1/2	J1P2/P3 applies	Same as Class 2 SOU for energy
5	Office	Vol 1	≤ 43 kJ/m².hr	J1P1, NABERS 5.5★ or Green Star pathway, EV 10% of spaces
6	Retail, restaurant, café	Vol 1	≤ 80 kJ/m².hr	J1P1 (highest allowance), NABERS Shopping Centres 4.5★, EV 10%
7a	Car park (standalone)	Vol 1	Lighting controls apply	Exempt from J9D4 EV boards if standalone
7b	Warehouse, storage	Vol 1	≤ 43 kJ/m².hr	J1P1, 0.15 kPa extra roof load for solar PV (structural), EV 20%
8	Factory, lab, workshop	Vol 1	≤ 43 kJ/m².hr	J1P1, EV 20%. Substations exempt from J7D3/J7D4 lighting
9a	Hospital, day surgery	Vol 1	≤ 43 kJ/m².hr (non-ward) / ≤15 (ward)	J1P1 specialised HVAC rules
9b	Schools, theatres, stadiums	Vol 1	≤ 43 kJ/m².hr (schools)	Strict lighting IPD limits, EV 20%
9c	Residential care / aged care	Vol 1	≤ 15 kJ/m².hr	Enhanced sound insulation between SOUs

Residential Energy — H6P1 Thermal Performance + H6P2 Whole-of-Home CLASS 1 & 2 ▶

H6P1 — Thermal Performance (New 2022)

Total heating load, cooling load, and total thermal energy load of all habitable rooms must not exceed limits in Specification 44. Varies by climate zone, floor area, and building type.

Two DtS pathways (H6D2):

Option 1 — NatHERS: 7-star average, 6-star minimum per SOU. Must produce NatHERS Certificate (A5G9).
Option 2 — Elemental: Housing Provisions Section 13 prescriptive R-values, glazing, sealing, ceiling fans.

H6P2 — Whole-of-Home Energy Cap (Brand New 2022)

Energy value of domestic services ≤ 70% of reference building with: 3★ ducted heat pump (heating + cooling) + 5★ instantaneous gas HWS + 4 W/m² lighting.

💡

All-electric heat pump + solar HWS + LED lighting easily beats 70% cap. The reference still uses gas HWS — replacing it with heat pump HWS alone saves ~30-40% relative to reference.

BUILDING SEALING — H6V3 (Blower Door)

Test Result	Outcome	Requirement
> 10 m³/hr.m² @ 50Pa	FAIL — non-compliant	Must improve sealing
≤ 10 m³/hr.m² @ 50Pa	PASS — basic compliance	No additional requirements
≤ 5 m³/hr.m² @ 50Pa	HIGHLY SEALED — additional obligations	Mandatory mechanical ventilation system: Q = 0.05A + 3.5(N+1)/p [L/s]. Solid-fuel/gas appliances require specific venting
≤ 0.6 ACH₅₀	PASSIVE HOUSE standard	Far exceeds NCC. Requires MVHR per PHI criteria

NCC INSULATION MINIMUMS BY CLIMATE ZONE (Elemental DtS — Housing Provisions S.13)

Zone	Key Cities	Min Ceiling/Roof R	Max Roof Solar Absorptance	Ceiling Fans Mandatory
1	Darwin, Cairns	R1.5–3.0 (table)	≤ 0.64	YES — all bedrooms
2	Brisbane, Rockhampton	R2.0–3.5 (table)	≤ 0.64	YES — all bedrooms
3	Perth, Port Augusta	R2.5–4.0 (table)	≤ 0.64	YES — all bedrooms
4	Sydney, Adelaide	R3.0–4.5 (table)	≤ 0.64	NSW/QLD Zone 5 only
5	Western Sydney, ACT warm	R3.5–4.5 (table)	≤ 0.64	NSW + QLD mandatory
6	Melbourne, Adelaide hills	R3.5 (or R3.0 + reflective)	No limit	No
7–8	Canberra, alpine, Tasmania	R4.5–R6.3+	No limit	No

Renewable Energy, Solar PV & EV Infrastructure — J1P4, J9D4, J9D5 LANDMARK 2022 ▶

⚡

J1P4 is a new Performance Requirement: every Class 2–9 building must have features that facilitate future installation of on-site renewable energy, battery storage, and EV charging. Met via J9D4 + J9D5.

J9D5 — SOLAR PV + BATTERY READINESS

Requirement	Specification
Main switchboard slots	≥ 2 empty 3-phase circuit breaker slots + 4 DIN rail spaces (labelled)
Switchboard sizing	Must accommodate PV producing max output on 20% of roof area
Roof clearance	≥ 20% of roof area clear for solar PV
Warehouse roof load	B1P1: +0.15 kPa notional roof load for solar PV (Class 7b) — design in from day 1

Exemptions from 20% clear rule: PV already installed (≥20% roof area), roof ≤55m², 100% shaded >70% daylight hours, >50% roof as terrace/carpark/garden/skylight.

J9D4 — EV CHARGING INFRASTRUCTURE

Building Class	Spaces EV-Ready	Energy/Circuit	Window
Class 2 (Apartments)	100%	12 kWh	11pm–7am
Class 3 (Hotels)	20%	48 kWh	11pm–7am
Class 5–6 (Office/Retail)	10%	12 kWh	9am–5pm
Class 7b, 8, 9	20%	12 kWh	9am–5pm

All chargers must be 7kW (32A) Type 2. Boards must include demand management/scheduling system. Standalone Class 7a car parks: exempt.

J9D3 — ENERGY MONITORING (SUB-METERING)

Building Size	Requirement
> 500 m²	Time-of-use metering: gas and electricity
> 2,500 m²	Advanced sub-metering: HVAC, lighting, appliance power, central HWS, lifts/escalators (>1), on-site renewables, EV charging, batteries, other plant — all interlinked to single BMS monitoring interface

Section J — Commercial Energy (Class 3–9): J4–J9 Summary COMMERCIAL ▶

J4 Building Fabric

R-values for roofs, walls, glazing. U-Value + SHGC for glazing assemblies. Floor edge insulation. Metal-frame thermal bridges must be addressed. Insulated sandwich panel R-values.

J5 Building Sealing

Seal all: chimneys, flues, roof lights, windows, doors, exhaust fans, evaporative coolers, construction joints. Air permeability tests per AS/NZS ISO 9972 Method 1.

J6 HVAC Controls

AC setback, time controls, zoning. Fan VSDs. Duct insulation and sealing. Pump systems. Pipework insulation. Condensing space heaters. Refrigerant chiller MEPS. Unitary A/C MEPS.

J7 Lighting

IPD limits by space type (office 4.5 W/m², retail 14 W/m², carpark 2 W/m²). Time switches, motion detectors, daylight sensors mandatory at scale. 90% LED exterior >100W.

J8 Hot Water + Pools

HWS → Volume 3 Part B2. Pool heating: solar / reclaimed / geothermal / heat pump / gas ≥86% only. Pool covers R0.05 min. Time switches mandatory. No standalone electric resistance heating.

J9 Monitoring + Renewables

Sub-metering thresholds. EV infrastructure (J9D4). Solar PV switchboard readiness (J9D5). See full detail above.

KEY LIGHTING IPD LIMITS (J7D3a)

Space	Max IPD W/m²	Key Control Adjustments
Office (≥200 lux ambient)	4.5	÷0.5 with daylight sensor adjacent windows → effective 2.25 W/m²
Retail / museum for sale	14	High allowance for display lighting
Restaurant / café / bar	14	—
School — general learning	4.5	÷0.5 with daylight sensor
Carpark — general	2	Motion detector: ÷0.4 in toilets
Storage	1.5	Motion detector mandatory (J7D4)
Corridors	5	Daylight sensor if adjacent windows >250W
Hospital — patient care	2.5	ICU/high dep: 6 W/m². Emergency lighting exempt.

NABERS & Green Star as NCC Verification Methods — J1V1 + J1V2 PREMIUM GREEN ▶

✓

A Green Star 5–6★ or NABERS 5.5★ building automatically satisfies NCC Section J energy performance requirements — no separate DtS compliance needed. This is a direct regulatory linkage unique to NCC 2022.

Standard	Building Class	Min Rating	GHG Threshold	Additional
NABERS Energy — Base Building	Class 5 Office	5.5★	<67% of 5.5★ level	Thermal comfort PMV -1 to +1 in ≥95% floor area, ≥98% operating hours
NABERS — Apartment Buildings	Class 2 Common	4★	<90% of 5★ level	A/C in enclosed lobbies/corridors ≥18hrs/day
NABERS — Hotels	Class 3	4★	<70% of 5★ level	Operating hours: bedrooms ≥12hr, corridors 24hr
NABERS — Shopping Centres	Class 6 >15,000m²	4.5★	<80% of 4.5★ level	Common area A/C ≥20% GLA
Green Star Design & As-Built	Class 3,5,6,7,8,9 + Class 2 common	Any rating	<90% of reference building	Thermal comfort PMV check required. Spec 33 additional requirements still apply.

State & Territory Variations — Critical Overrides PRACTICE ▶

State	Residential Energy	Commercial Energy	Water	Critical Difference
NSW	BASIX overlay	Section J (transition)	BASIX includes water targets	BASIX v4.0+ aligns with NCC 2022 J for Class 2. Earlier = NCC 2019. Ceiling fans mandatory Zone 5.
VIC	H6V1/H6D2 variations	Slight Section J variations	—	VIC-specific schedule variations throughout
QLD	Standard NCC	Standard NCC	—	Ceiling fans Zone 5 mandatory. Some B1P4 flood variations.
SA	Standard NCC	Standard NCC	SA Part H9 — extensive water efficiency requirements beyond NCC	SA Part H10 adds disability access requirements
WA	Standard NCC	Standard NCC	WA Part H9 — Water Use requirements	WA-specific terminology and definitions
TAS	Class 2/4: BCA 2019 Amdt 1 (NOT NCC 2022!)	Partial 2022	—	H8 Livable Housing deferred to 1 Oct 2024
NT	NT-specific H6/J variations	NT Part J modifications	—	Tropical climate zone specifics throughout
ACT	Standard NCC	Standard NCC	—	ZERO-CARBON GRID: S34C3 table does NOT provide ACT electricity GHG factor — must use ACT-specific values for all J1V3 emissions modelling

10,000 Years of Passive Design

Ancient Passive
Architecture

Twelve civilisations — Persian, Roman, Egyptian, Greek, Chinese, Islamic, Anatolian, Indian, Mesoamerican, Native American, Korean, Japanese — perfected passive cooling, heating, ventilation, water, and daylighting without mechanical energy. These are not historical curiosities: they are thermodynamic solutions still applicable today.

12

Civilisations whose passive systems are documented and analysed

Persian · Roman · Chinese · Islamic · Korean · Japanese · +7

10,000

Years of passive performance optimisation — empirical field-testing at civilisational scale

Qanat systems dated to 1000 BCE; badgir towers to 3000 BCE

0

Mechanical energy required by any system in this reference

All systems driven by sun, wind, gravity, and thermal physics

8

Layers of the modern passive design protocol — site to detail

Climate analysis → orientation → form → mass → water → systems → integration

40–60%

Typical cooling load reduction from windcatcher + qanat + night purge combined

Hot-arid climate; documented in Yazd, Iran field studies

6×

Maximum plan depth for effective cross-ventilation (ceiling height multiplier)

Universal rule from Islamic to Japanese vernacular traditions

±15°

Maximum deviation from true north for optimal solar orientation (southern hemisphere)

Each degree beyond costs performance no other measure can recover

50%

Less winter solar radiation on north-facing slopes (Australia) vs south-facing

Site selection is the highest-leverage passive design decision

Cooling

Windcatcher · Qanat · Courtyard · Mashrabiya

Heating

Hypocaust · Ondol · Trombe Wall · Solar Orientation

Ventilation & Light

Stack Effect · Clerestory · Oculus · Engawa

Water

Qanat · Aqueduct · Impluvium · Stepwell

Materials & Mass

Adobe · Rammed Earth · Stone · Thermal Lag

Urban Morphology

Shade Canyon · Party Wall · Street Orientation

8-Layer Protocol

Site · Orientation · Form · Mass · Water · Systems

Climate Matrix

System × Climate Zone × NCC Mapping

🌬️

Ancient cooling without refrigeration. Hot-arid civilisations developed interlocking passive cooling systems — windcatcher, qanat, courtyard, night-purge ventilation — that together reduce indoor temperatures by 15–25°C below ambient during peak summer. Each system is a standalone solution; combined, they create a thermodynamic feedback loop far more powerful than the sum of parts.

🌀 Windcatcher / Badgir — Persian Tower Ventilation HOT-ARID ▶

Mechanism

The badgir (Persian: بادگیر) is a tower that captures prevailing wind at height, channels it downward through a vertical shaft, and delivers cooled air at ground level. Multi-directional versions (4-faced or 8-faced) catch wind from any direction. The shaft often passes over water or a qanat channel, adding evaporative cooling. Hot exhaust air exits via a second opening or the courtyard stack effect.

Physics: Bernoulli effect accelerates air through constricted tower throat; adiabatic cooling as air descends; evaporative cooling over water surface; stack effect drives continuous circulation without wind.

Performance Data

Parameter	Value
Indoor temp reduction (peak)	15–25°C below ambient
Effective wind speed	2–8 m/s at tower inlet
Tower height (typical)	6–33 m (Yazd, Iran)
Orientation (single-face)	Prevailing wind ± 15°
Combined with qanat	Additional 5–10°C reduction
Night purge compatibility	Fully compatible — reverses at night

Modern Applications

Windcatcher towers are currently used in Zion National Park Visitor Centre (USA), BedZED (UK), and multiple schools in Iran. Design software: EnergyPlus windcatcher module, Climate Consultant.

🌊 Qanat / Earth-Air Heat Exchanger — Underground Cooling Tunnels HOT-ARID ▶

Mechanism

The qanat (قنات) is a gently sloping underground tunnel connecting a highland aquifer to a lowland settlement — typically 5–50 km long, 1–2 m diameter. Air drawn through the qanat is cooled by soil thermal mass (ground temperature remains ~18–22°C year-round) and humidified by the water surface. At the exit, the cooled, humidified air is directed into the windcatcher shaft, courtyard, or directly into occupied rooms.

Engineering principle: Ground-coupled heat exchange. Same physics as modern earth-air heat exchangers (EAHE), but operating at civilisational scale.

Design Parameters

Parameter	Guidance
Depth for stable ground temp	≥ 3 m (seasonal); ≥ 8 m (annual)
Ground temperature (3m depth)	~18–22°C in hot-arid zones
Air flow velocity	0.5–2 m/s (gravity-driven)
Tunnel diameter	0.8–1.5 m (human entry for maintenance)
Cooling capacity	5–15°C reduction in summer
Modern equivalent	EAHE — earth-air heat exchanger

🏛️ Courtyard (Sahn / Peristyle / Tian Jing) — Thermal Engine ALL CLIMATES ▶

Mechanism

The inward-facing courtyard is the universal passive building form across Persian, Roman, Islamic, Chinese, and Indian traditions. The courtyard acts as a thermal regulator: shaded by surrounding walls during the day, it retains cool air pooled overnight by radiation to the sky. The central water feature (fountain, pool, impluvium) adds evaporative cooling. At night, the open sky allows rapid radiative cooling of the courtyard mass.

Chinese Tian Jing (天井) Skywell

The Chinese skywell is a compressed, vertical courtyard — narrow and deep (H:W ratio 2:1 to 4:1). It functions as a chimney: heated air rises from the cool ground-floor rooms, drawing fresh air in through lower openings. The narrow proportions prevent direct solar penetration while maximising stack ventilation.

H:W ratio: 2:1 creates 80% shading on the floor at solar noon; 4:1 creates 95% shading. Rule of thumb: for hot climates, H:W ≥ 2:1.

🪟 Mashrabiya — Islamic Lattice Screen HOT-DRY · HOT-HUMID ▶

The mashrabiya (مشربية) is a projecting oriel window enclosed with intricately carved wooden latticework. It simultaneously provides: (1) shading — blocking 60–80% of direct solar radiation; (2) air filtration — the lattice creates turbulence that increases convective cooling; (3) evaporative cooling — wet clay pots placed on the mashrabiya shelf cool passing air by evaporation; (4) privacy and daylighting — diffused daylight without glare. A single mashrabiya element performs four distinct building-performance functions. Modern equivalent: external shading louvres + natural ventilation opening, though no single contemporary element matches this multi-functional integration.

🔥

Radiant floor heating from 100 BCE. The Roman hypocaust and Korean ondol are fully developed underfloor radiant heating systems — the same principle as modern hydronic heating, operating centuries before fossil fuels. Solar walls and Trombe walls extend the tradition to passive solar gain storage and slow release.

🏛️ Hypocaust — Roman Underfloor Radiant Heating (100 BCE – 400 CE) COLD · TEMPERATE ▶

How it Works

The Roman hypocaust (Latin: hypocaustum) circulates hot air and combustion gases under a raised floor — the suspensura — supported on short brick pillars (pilae) typically 600–800 mm high. A wood-fired furnace (praefurnium) drives hot gases under the floor and up through hollow tiles (tubuli) in the walls. The mass of the floor (typically 200–300 mm concrete/tile) stores heat and radiates it gently to the room above at 24–28°C surface temperature.

Korean Ondol (온돌) — 37 BCE to Present

The Korean ondol is a direct-contact radiant floor system: hot gases from a firebox flow under a stone floor covered with oiled paper. Unlike the Roman hypocaust (raised floor with air gap), ondol uses direct conduction through the stone slab. The system heats the floor to 35–40°C; occupants sleep directly on the floor surface. Ondol is still installed in contemporary Korean housing and is the precursor to all modern in-slab hydronic systems.

Modern equivalent: PEX in-slab hydronic heating. Same thermodynamic principle, same comfort outcome — 2,000 years of development later.

Performance Comparison

System	Floor Temp	Response Time	Fuel
Roman Hypocaust	28–35°C	2–4 hours	Wood
Korean Ondol	35–42°C	1–3 hours	Wood / rice straw
Modern Hydronic	28–35°C	2–6 hours	Gas / heat pump
Modern Electric UFH	28–32°C	0.5–2 hours	Electricity

Design Principles — Still Valid Today

Thermal lag: Heavy floor slab stores heat; surface temperature remains stable for 6–12 hours after firing stops. Design floor mass for the climate — heavier slab for colder climates with longer heating cycles.

Surface temperature: Keep floor surface below 29°C for continuous standing comfort; 35–42°C acceptable for sleeping surfaces (ondol principle).

NCC relevance: In-slab hydronic systems count toward NCC H6 thermal performance credits when paired with a heat pump COP ≥ 3.5.

☀️ Trombe Wall / Solar Wall — Passive Solar Heat Storage COLD · TEMPERATE ▶

Ancient Precedent: South-Facing Stoa (Greece) & Solar Orientation (China)

Greek architects from 400 BCE oriented stoa (colonnades) to face south, using the colonnade as a selective solar aperture: winter sun penetrates under the low colonnade; summer sun is blocked by the high colonnade overhang. Chinese courtyard homes were oriented south; the north wall was a solid thermal mass — the first Trombe wall principle, without the glazing.

Trombe Wall Mechanism (Formalised 1881, popularised 1960s)

A Trombe wall consists of: (1) south-facing glazing, (2) a 20–400 mm air gap, (3) a dark-coloured masonry or concrete wall of 200–600 mm thickness. The wall absorbs solar radiation during the day; heat conducts slowly through the mass and radiates to the interior 6–12 hours later (thermal lag). Vents at top and bottom allow convective air circulation.

Thermal lag formula: Lag (hours) ≈ thickness (mm) / 25. A 300 mm concrete wall has ~12 hour lag — heat absorbed at noon radiates to interior at midnight.

💨

Stack effect, cross-ventilation, and daylighting. Every ancient building culture discovered the same ventilation principles independently: hot air rises and must be given a path to escape; cool air must be drawn in low; building plan depth must not exceed 6× ceiling height for cross-ventilation to work. These are not cultural preferences — they are thermodynamic laws.

🌪️ Stack Effect / Thermal Buoyancy Ventilation ALL CLIMATES ▶

Physics

Hot air is less dense than cool air. When a building has a height difference between a low inlet and a high outlet, the temperature difference drives continuous air movement without wind. The greater the height difference and the greater the indoor/outdoor temperature differential, the stronger the stack-driven flow.

Flow rate formula: Q = Cd × A × √(2g × h × ΔT/T) where h = height between inlet and outlet, ΔT = temperature difference, T = absolute outdoor temperature.

Ancient Applications

Roman atrium: Central compluvium (roof opening) above the impluvium (water basin) created a powerful stack — warm room air rose and exited through the compluvium; cool, humidified air was drawn in at floor level from the surrounding peristyle.

Islamic hammam (bathhouse): Domed ceiling with small glass oculi created multiple stack paths — each dome drew air upward through its crown opening, and the height of the dome (~8–15 m) gave substantial stack pressure.

Japanese minka: High thatched roof with smoke vent and open floor-to-roof structural bays created a full-height stack. Cooking fires assisted the stack effect in winter.

Design Rules of Thumb

Design Parameter	Rule of Thumb	Source
Plan depth (cross-ventilation)	≤ 6× ceiling height	Universal — Islamic, Japanese, vernacular
Stack height for effective buoyancy	≥ 3 m height differential	Roman atrium; Islamic dome
Inlet:outlet area ratio	1:1.25 (outlet slightly larger)	Windcatcher research (Iran)
Night purge temperature differential	≥ 3°C outdoor cooler than indoor	Adobe tradition; desert vernacular
Cross-ventilation opening size	≥ 5% floor area each side	NCC + ancient practice convergence

🌞 Daylighting — Clerestory, Oculus, Light Wells ALL CLIMATES ▶

Clerestory — Egyptian, Roman, Romanesque

A clerestory is a band of windows placed high on a wall, above adjacent lower roofs. It delivers deep daylight penetration (up to 2.5× the window head height into the plan) without low-angle glare and without the direct solar gain of a standard window. The Egyptian hypostyle hall used clerestory lighting as early as 1550 BCE.

Roman Oculus — The Pantheon (125 CE)

The Pantheon oculus (9 m diameter) at 43 m height is the supreme example of top-lighting: a single circular opening floods the entire hemispherical interior with a moving disc of light that traverses the walls over the course of a day. The opening also provides stack ventilation and rain (which drains through floor holes). No artificial light is needed in daytime.

Modern daylight rule: Top-light (skylight) delivers 3× more daylight per unit area than side windows. Always prefer top-light for deep-plan or large-floor-area buildings.

📐

The 2.5× rule for clerestory penetration. Daylight from a clerestory window penetrates approximately 2.5× the window head height into the plan. A clerestory with its head at 4 m height delivers useful daylight 10 m into the plan — far beyond what a standard side window (head at 2.1–2.4 m) can achieve. This is why basilicas and great halls are lit at all. Apply this rule to modern deep-plan buildings.

🌿 Engawa — Japanese Transitional Buffer Space TEMPERATE · HUMID ▶

The engawa (縁側) is a veranda or corridor running along the southern face of a Japanese timber house — typically 900 mm–1200 mm deep. It performs as a thermal and acoustic buffer: in summer, the deep roof overhang blocks high-angle sun while the engawa allows cross-ventilation through sliding shoji screens; in winter, the engawa space is closed, acting as a solar buffer zone that pre-warms air entering the house. It simultaneously manages solar gain, natural ventilation, glare, privacy, and acoustic separation. Modern equivalent: a climate-controlled sunspace or conservatory — but the Japanese achieved this with a 900 mm timber platform and a sliding paper screen. The engawa principle directly informs NCC climate zone 5–7 solar access and shading requirements.

💧

Gravity-fed water systems that outlasted their civilisations. The Roman aqueduct network delivered 1,000,000 cubic metres of water per day to Rome at peak. Persian qanats, some constructed 3,000 years ago, still supply water to Iranian villages today. These are not primitive solutions — they are systems engineering at civilisational scale, gravity-driven, maintenance-efficient, and millennium-proof.

🌊 Qanat Water System — Underground Aqueducts (Persia, 1000 BCE) HOT-ARID ▶

System Description

A qanat taps a highland aquifer and channels water through a gently sloping underground tunnel (gradient typically 1:1000 to 1:1500) to a lowland settlement. Vertical shafts at 20–50 m intervals allow access for construction and maintenance. At the exit point, the water emerges naturally at surface level — no pumping required. The tunnel also provides passive air cooling (see Cooling section). Over 3,000 qanat systems are still operational in Iran today.

Roman Aqueduct System (312 BCE – 455 CE)

At its peak, Rome was served by 11 aqueducts carrying 1,000,000 m³/day — approximately 600 litres per person per day, compared to a modern Australian average of ~300 l/p/day. The aqueducts operated entirely by gravity, maintaining a grade of 1:4800 over distances of up to 90 km. Distribution through the city used a system of castella (distribution tanks) and lead/terracotta pipes at differential pressures — the first urban water pressure network.

Impluvium — Roman Rainwater Harvesting

The impluvium is a shallow rectangular basin in the centre of the Roman atrium, directly below the compluvium roof opening. It collected rainwater from the roof and directed it to an underground cistern (cisterna) for household use. The water surface also provided evaporative cooling to the atrium. The impluvium is the direct precursor to the modern rainwater harvesting tank — and applies to the LBC I05 Responsible Water Use imperative and NCC rainwater provisions.

Design Sizing — Cistern for 3-Month Supply

Parameter	Value
Household daily use (basic)	50 l/person/day (emergency minimum)
Cistern for 3 months (4 people)	50 × 4 × 90 = 18,000 litres
Typical Roman/Persian cistern	20,000–200,000 litres (stone-lined)
Recommended modern size	Catchment area (m²) × annual rainfall (m) × 0.8 (runoff coefficient)

🪜 Stepwell / Vav / Baoli — Indian Underground Water Halls (2nd century CE) HOT-ARID · HOT-HUMID ▶

The Indian vav or baoli (stepwell) is a multi-storey underground structure reaching a permanent water table, with a series of descending steps and landings that allow users to access water at any level as the water table fluctuates seasonally. The deep shaft maintains a temperature of 20–25°C year-round — a passive cooling refuge for communities. The stepped galleries are decorated with elaborate carvings; the entire structure functions simultaneously as a water source, community meeting space, passive cooling retreat, and architectural monument. Chand Baori (8th century, Rajasthan) descends 13 stories and 30 m deep, with 3,500 narrow steps. The stepwell provides passive cooling to the surrounding area through evaporation and earth coupling — a local urban heat island countermeasure.

🧱

Thermal mass — the original passive conditioning system. Adobe, rammed earth, stone, and brick are not construction choices — they are thermal batteries. They store heat or coolness during the day and release it slowly during the night, dramatically reducing peak indoor temperatures. The key insight every ancient building culture discovered: in hot climates, keep mass on the interior (shaded exterior insulation); in cold climates, place mass on south-facing (solar-exposed) surfaces.

🏜️ Adobe & Rammed Earth — Thermal Mass Materials HOT-ARID · TEMPERATE ▶

Material Properties

Property	Adobe	Rammed Earth	Concrete
Thermal conductivity λ (W/mK)	0.52–0.72	0.8–1.6	1.4–2.0
Specific heat capacity (J/kgK)	840–920	800–1000	840–880
Density (kg/m³)	1600–1900	1800–2200	2200–2400
Thermal lag (300mm wall)	8–12 hours	8–14 hours	8–12 hours
Embodied carbon (kg CO₂/m³)	~15–20	~10–30	~300–380

Design Rules for Thermal Mass

Hot-arid climate rule: Maximum thermal mass on all interior surfaces. Exterior must be insulated (or shaded) to prevent mass from absorbing daytime solar heat. Pair with night-purge ventilation (open windows at night when outdoor temp drops below indoor) to discharge stored heat. Wall thickness: 300–600 mm optimal for 24-hour cycle.

Cold climate rule: Mass on south-facing interior surfaces only. Exterior walls must be insulated first; mass on interior side of insulation stores solar gain. Pair with passive solar apertures to charge the mass.

Mixed climate rule: Insulation on exterior + mass on interior of all walls. Prioritise south-facing mass. Use night-purge ventilation in summer; close tight in winter.

NCC application: Adobe and rammed earth walls can achieve NCC H6 thermal performance requirements without additional insulation in climate zones 3–5 when wall thickness ≥ 400 mm and solar access is managed.

🏙️

Urban form is the most powerful passive design tool. Ancient builders understood that the layout of streets, blocks, and buildings creates the microclimate that individual buildings then respond to. A well-designed street network can reduce cooling loads by 30–40% compared to an identical building in an unplanned suburban grid. The decisions that matter most — street orientation, H:W ratio, building attachment — are made at the masterplan stage, not the building design stage.

🏘️ Islamic Medina / Shade Canyon Streets HOT-ARID · HOT-HUMID ▶

Street H:W Ratio

The narrow streets of Islamic medinas (H:W ratio typically 2:1 to 6:1) create shade canyons: the upper floors of buildings on opposite sides of the street shade the street level for most of the day. At H:W = 2:1, street-level shading exceeds 80% during solar noon. The mutual shading between buildings also reduces wall solar gain — neighbour buildings act as free shade screens for each other.

Modern application: Urban design guidelines for hot-climate Australian cities (Darwin, Broome, Cairns) should specify H:W ≥ 1.5:1 for east-west streets and ≥ 1:1 for north-south streets.

Party Wall Construction

Islamic medina buildings are typically party-wall construction — shared walls between adjacent buildings. This eliminates two external wall exposures per building; those walls become interior walls with no solar gain and no heat loss. Party-wall construction can reduce heating and cooling loads by 30–40% compared to detached buildings of identical plan and height.

Passive House relevance: PHI v9f explicitly credits terraced and semi-detached configurations with reduced thermal envelope area, improving the heat load / treated floor area ratio. Terrace housing is not a housing style choice — it is a thermodynamic choice.

Urban Morphology Design Rules

Principle	Guidance	Climate
Primary street orientation	East-west (max solar access to north face, AU)	All
Street H:W ratio (hot-arid)	2:1 minimum	Hot-arid, hot-humid
Building attachment	Party-wall or terrace	All (especially cold)
Block depth	Max 60 m (allows cross-ventilation through each dwelling)	Hot-humid
Courtyard size (hot-arid)	H:W ≥ 2:1 for 80%+ shading	Hot-arid
Vegetation / canyon shading	Deciduous trees on north (AU) or south (NH) face	Temperate, hot

📐

The Eight Layers of Passive Performance. A step-by-step design protocol for integrating ancient passive systems into new developments. Proceed from site selection through to detailing, following the sequence of decisions that maximise the effectiveness of each layer. Decisions at Layer 1 and 2 are free and irreversible — they cannot be corrected by any later design measure.

1

Site & Climate Analysis

Before any design begins: map prevailing wind directions by season, the solar path, annual temperature range and diurnal swing, rainfall distribution, groundwater depth, and soil thermal properties. Ancient builders learned this empirically over generations; we now have Climate Consultant, Ladybug/Grasshopper, and BOM data. This layer costs zero in construction and delivers maximum passive performance.

2

Site Orientation

Orient the building’s primary living face to true north (Australia) within ±15°. Choose the site’s highest or most north-facing slope. Every degree of deviation from optimal orientation costs performance that cannot be recovered by any other design measure. North-facing slopes (Australia) receive up to 50% more winter solar radiation than south-facing slopes.

3

Urban Morphology

Design the street network and block layout for maximum shading (H:W ratio 2:1+), party-wall construction, and wind channelling. Orient primary streets east-west. Build compact, attached, or clustered forms rather than isolated pavilions.

4

Building Form

Design a plan depth no greater than 6× ceiling height for cross-ventilation effectiveness. Place buffer spaces (garage, utility) on the west. Position the thermally stable side (south, Australia) for bedrooms. Create a building section that supports stack ventilation: tall spaces, high-level exhausts, low-level inlets.

5

Thermal Mass & Insulation

Specify thermal mass on all sun-facing interior surfaces: concrete slab (100 mm minimum), brick veneer, stone, rammed earth. Insulate the exterior of all walls — keep mass on the warm side. Hot climates: mass is the priority. Cold climates: insulation is the priority. Mixed climates: both at their respective sides.

6

Water Systems

Integrate rainwater harvesting (impluvium principle) into the roof and plan design. Size underground cistern for minimum 3 months supply. Connect qanat-principle earth-air heat exchangers if site conditions permit (groundwater ≤8 m depth). Use gravity distribution wherever elevation allows.

7

Passive Climate Systems

Select and size the appropriate passive systems for your climate: Hot-arid: windcatcher + qanat + night purge + adobe mass. Hot-humid: cross-ventilation + raised floor + ventilated dome + shade canyons. Temperate: clerestory + solar orientation + Trombe wall + hydronic floor. Cold: hypocaust equivalent + solar glazing + windbreak planting.

8

Integration & Monitoring

Ancient passive systems work as an integrated whole — the windcatcher, qanat, courtyard, and night purge are not separate add-ons but a single thermodynamic system. Design all systems together from the beginning. Monitor performance post-occupancy: temperature, humidity, air quality, energy consumption. Iteratively refine — this is how ancient builders perfected their systems over centuries of local adaptation.

🌍

The Fundamental Principle. Every ancient building culture optimised for its specific place: its prevailing winds, sun path, rainfall, soil, and available materials. There is no universal passive solution — the windcatcher is genius in Yazd and useless in Singapore; the heavy adobe wall is perfect in Alice Springs and dangerous in Cairns. The ancient tradition teaches us above all to read the place first and design second.

Ancient System × Climate Matrix

Which ancient passive system performs in which climate? Use this matrix to select applicable strategies by climate zone before designing. Systems marked ● are highly effective; ◐ are partially effective or seasonally applicable; · are not recommended.

System	Hot-Arid	Hot-Humid	Temperate	Cold	NCC Zone (AU)
Windcatcher / Badgir	● Excellent	◐ Partial	◐ Seasonal	· Not rec.	Zones 1, 3
Qanat / EAHE	● Excellent	· Not rec.	◐ Seasonal	◐ Heating	Zones 1, 3, 4
Courtyard / Sahn	● Excellent	● Excellent	◐ Seasonal	· Heat loss	Zones 1, 2, 3, 5
Mashrabiya	● Excellent	● Excellent	◐ Partial	· Not rec.	Zones 1, 2, 3
Tian Jing Skywell	◐ Partial	● Excellent	● Excellent	· Not rec.	Zones 2, 3, 5
Hypocaust / Ondol	· Not rec.	· Not rec.	● Excellent	● Excellent	Zones 5, 6, 7, 8
Trombe / Solar Wall	◐ Partial	· Not rec.	● Excellent	● Excellent	Zones 4, 5, 6, 7
Adobe / Rammed Earth	● Excellent	◐ Partial	● Excellent	◐ With insul.	Zones 1, 3, 4, 5
Night Purge Ventilation	● Excellent	· Too humid	● Excellent	◐ Limited	Zones 1, 3, 4, 5
Cross-Ventilation	◐ w/cooling	● Excellent	● Excellent	◐ Summer only	Zones 1, 2, 3, 5
Clerestory Daylighting	● Excellent	● Excellent	● Excellent	● Excellent	All zones
Stack Effect / Chimney	● Excellent	● Excellent	● Excellent	◐ Summer only	All zones
Impluvium / Cistern	● Essential	● Excellent	◐ Useful	◐ Freeze risk	All zones
Party Wall / Shade Canyon	● Excellent	● Excellent	● Excellent	● Excellent	All zones
Engawa Buffer Space	· Not rec.	◐ Partial	● Excellent	◐ Partial	Zones 4, 5, 6

NCC climate zones reference: Zone 1 = Hot humid (Darwin, Townsville) · Zone 2 = Warm humid (Brisbane coast) · Zone 3 = Hot dry (Alice Springs, Broken Hill) · Zone 4 = Mixed (Sydney, Adelaide) · Zone 5 = Cool temperate (Melbourne, Canberra) · Zone 6 = Cold (high country VIC/NSW) · Zone 7 = Cool alpine · Zone 8 = Alpine

GBCA · Green Building Council of Australia

Green Star
Rating Tools

Australia’s most widely recognised green building and community rating system, administered by the Green Building Council of Australia (GBCA). Two primary tools: Green Star — Communities for precinct-scale sustainable development; and Green Star — Design & As-Built for individual buildings. Together they define best practice across social, environmental, economic, and design outcomes.

2

Primary rating tools — Communities (precinct scale) and Design & As-Built (building scale)

Both administered by GBCA

5

Principles in the Green Star Communities National Framework

Liveability · Prosperity · Environment · Design · Governance

9

Credit categories in Green Star Design & As-Built v1.2

Management · IEQ · Energy · Transport · Water · Materials · Land & Ecology · Emissions · Innovation

4★–6★

Certification levels — Best Practice (4★), Australian Excellence (5★), World Leadership (6★)

45–59 pts → 4★ · 60–74 pts → 5★ · 75+ pts → 6★

100

Maximum base points available across the 9 Design & As-Built categories

Innovation credits available above 100

36M

Australia’s projected population by 2050 — the challenge driving the Communities framework

85% urban · two-thirds in major cities

0

Credits that can be partially met — all credits are all-or-nothing unless otherwise specified

Best practice standards, not minimum compliance

8

Community attribute types used to define project boundaries

Infrastructure · Buildings · Public Realm · People · Ecology · Economy · Governance · Services

⭐

Green Star is Australia’s definitive green building and community rating system. Developed and administered by the Green Building Council of Australia (GBCA), Green Star tools provide nationally consistent, third-party verified benchmarks for sustainable outcomes at both the building and community scale. Green Star certification signals to the market, government, and tenants that a project delivers genuine sustainability performance — not just ambition.

Green Star — Communities

Scale: Precinct, neighbourhood, masterplan, town, city.

Purpose: Establishes five national best practice principles to guide the planning, design, delivery, and renewal of sustainable communities across Australia. A national framework that provides a common language, aspirational vision, and process for integrated sustainability at community scale.

Stage 1: National Framework (this document) — five principles and their sub-issues. Stage 2: Rating tool — benchmarks, assessment criteria, and certification process informed by the framework.

Developed by: GBCA with Rock Development Group (principal sponsor), Australian Government (Dept. Infrastructure & Transport), eight Government Land Organisation sponsors, and 30+ Technical Reference Committee members.

Green Star — Design & As-Built v1.2

Scale: Individual buildings — new construction and major refurbishment.

Purpose: Provides measurable, third-party certified benchmarks for building sustainability performance across nine credit categories. Two submission stages: Design (based on design documentation) and As-Built (based on the constructed building, typically submitted 12–24 months after practical completion).

Certification levels: 4 Star (best practice), 5 Star (Australian excellence), 6 Star (world leadership).

Administered by: GBCA. Assessors are independent GBCA-appointed professionals. All claims must be substantiated by documented evidence per the submission guidelines.

Tool Comparison

Attribute	Green Star Communities	Green Star Design & As-Built v1.2
Scale	Precinct / community / city	Individual building
Stage	Framework (Stage 1) + Rating tool (Stage 2)	Design + As-Built submissions
Structure	5 principles, each with sub-issues	9 categories, 100+ credits
Output	Principles compliance / certification (Stage 2)	Star rating (4★, 5★, 6★)
Verification	Stakeholder engagement + documentation (Stage 2)	GBCA-appointed independent assessor
Time	Ongoing (lifecycle of community)	Design: pre-construction. As-Built: 12–24 mo post-PC
Primary beneficiary	Governments, developers, communities, planners	Building owners, developers, tenants, government
Australian context	Addresses 2050 population growth and urban sustainability	Benchmarks buildings beyond NCC minimum compliance

🏛️

Green Star and the NCC are complementary, not competing. The NCC sets the legal minimum for building performance in Australia. Green Star sets aspirational best practice above that minimum. A 4 Star Green Star building significantly exceeds NCC minimum; a 6 Star building operates at world leadership level. For community scale, Green Star Communities provides the framework that state and local planning instruments currently lack — a nationally consistent language for sustainable precinct outcomes.

🏘️

A vision, a set of principles, and aspirations. The Green Star Communities National Framework is designed to provide inspiration and contribute to a national conversation about how we plan, design, build, maintain and renew sustainable communities. It is aspirational and visionary — not a prescriptive solutions document, but a lens for structuring sustainability thinking at community scale.

What is a Community?

For the purposes of this framework, a community encompasses precincts, places, neighbourhoods, or any geographic area used by stakeholders to describe their projects — regardless of size. Communities are characterised by eight attribute types, each with its own boundary of influence:

Infrastructure

Systems and services supplying energy, water, waste management, communications, technology, and mobility.

Buildings

Built form accommodating working, living, and recreation — both public and private.

Public Realm

Areas accessible to the public — streets, parks, plazas, waterways.

People

Those who own, rent, occupy, visit, work, reside, recreate, or interact in the area.

Ecology

Biological systems within the environment — flora, fauna, soil, water systems.

Economy

Systems supporting production, exchange, distribution, and consumption of goods and services.

Governance

Rules, behaviours, and structures that shape and influence communities.

Services

Information and facilities available to people — health, education, community services.

The Five Principles

🏠 Principle 1 — Enhance Liveability SOCIAL ▶

The Principle

Sustainable communities are liveable. They are diverse, affordable, inclusive and healthy; they enhance social interaction and ownership, are safe and caring, and improve people’s well-being.

Sub-Issues

Diverse & affordable living: Diversity of dwellings, buildings, and facilities reflecting broad socio-economic needs. Access to transport, food, health, and conveniences.

Healthy, safe & secure: Planning, urban design, and landscape architecture supporting physical activity and social engagement. Healthy activities promoted.

Inclusiveness & cohesiveness: Inclusive environments for all ages, abilities, cultures. Shared vision, diversity, tolerance. Stakeholder engagement from policy to revitalisation.

Community adaptability: Capacity to adapt to changing needs. Diversity of uses enabling future challenges.

💰 Principle 2 — Create Opportunities for Economic Prosperity ECONOMIC ▶

The Principle

Sustainable communities prosper. They encourage opportunities for business diversity, innovation, and economic development that support local jobs for people in the region.

Sub-Issues

Education & learning: Opportunities for access to a variety of education systems.

Employment: Diverse employment opportunities meeting local and regional needs. Local procurement.

Investment: Infrastructure enabling community and business connectivity. Ethical investment. Business case for green infrastructure, inclusive of externalities.

Innovation: Business and community innovation through initiatives recognising and rewarding local excellence.

Efficiency & effectiveness: Lifecycle impact management. Infrastructure creating greater urban management efficiencies.

🌿 Principle 3 — Foster Environmental Responsibility ENVIRONMENT ▶

The Principle

Sustainable communities respect the environmental systems that support them. They protect and restore natural environmental values of their bio-regions. They are less resource intensive and promote infrastructure, transport, and buildings that reduce their ecological footprint.

Sub-Issues

Enhancing natural environment: Protecting, valuing, restoring heritage assets (water and land). Biodiversity. Reducing GHG emissions, contaminants, pollutants. Minimising risk from extreme events and climate change.

Reducing ecological footprint: Efficient water and wastewater management. Sustainable energy generation. Waste management and recycling. Resource efficiency in lifecycle context. Retrofit and reuse. Sustainable transport. Food security. Community education on impacts.

🏛️ Principle 4 — Embrace Design Excellence DESIGN ▶

The Principle

Sustainable communities are places for people. They are desirable, accessible, and adaptable. They have their own distinct character and identity and evolve over time.

Sub-Issues

Effective planning: Integrated planning framework. Density, mixed use, connectivity, protection of valuable land uses. Measurable design outcomes.

Integrated design: Understanding community context and regional relationship. Responding to land, water, and climatic constraints. Coherent urban structure. Connectivity between transport, communication, social, and physical infrastructure.

Flexible approaches: Retrofit and revitalisation opportunities. Planning flexibility. Adapting to changing climatic and physical conditions.

Desirable places: Sense of place and identity. Connection with nature. Quality public realm. Climate-responsive built form and landscape. Cultural heritage. Vibrant, stimulating places.

Accessibility: Higher densities near public transport. Mixed-use development.

🏛️ Principle 5 — Demonstrate Visionary Leadership and Strong Governance GOVERNANCE ▶

The Principle

Sustainable communities are characterised by leadership and strong governance frameworks that are transparent, accountable, and adaptable. They enable active partnerships to build capacity and achieve a shared vision delivering stakeholder benefit.

Sub-Issues

Coordinated approaches: Cross-sectoral stakeholder coordination. Transparent, accountable decision-making. Practical standards of responsibility and resource allocation.

Commitment to implementation: Enforceable standards of ownership, accountability, and delivery. Performance evaluation and continual improvement mechanisms.

Stakeholder engagement: Shared vision across community, industry, and government. Progress monitoring, community capacity building.

Sustainable cultures: Awareness raising, education, sustainable behaviours. Environmental data monitoring.

Innovation: Open access information sharing. Recognising and rewarding leadership in innovation and excellence.

🏢

Green Star — Design & As-Built v1.2. The rating tool for individual buildings — new construction and major refurbishment. Certification is earned by accumulating points across nine categories. The Design stage is assessed against design documentation. The As-Built stage is assessed against the completed building, typically submitted 12–24 months post practical completion. Both stages are assessed by GBCA-appointed independent assessors.

Two-Stage Submission Process

Stage	Timing	Evidence Basis	Outcome
Design Stage	Pre-construction / during design development	Design documentation — drawings, specs, reports, modelling	Conditional Design certification (indicates intent to achieve)
As-Built Stage	12–24 months post practical completion	As-constructed evidence — commissioning records, invoices, testing results, handover docs	Full certification at 4★, 5★, or 6★

Key Submission Requirements

Project Registration

Projects must be registered with GBCA before submitting. Registration locks in the version of the rating tool applicable to the project. Fee structure is based on gross floor area (GFA). Projects retain the registered version even if newer versions are released post-registration.

Credit Documentation

Every credit attempt must be supported by documented evidence. Evidence requirements are detailed per-credit in the submission guidelines. Common evidence types include: energy modelling reports (NatHERS, NABERS, TRNSYS), commissioning reports, product specifications and declarations, invoices, certificates, and third-party verification letters.

Certified Energy Modelling

Energy credits (Cat. 3) require energy modelling by a qualified engineer. Modelling must use a GBCA-accepted software tool and follow the Green Star Energy Modelling Protocol. NatHERS (for residential) and JV3/simulation (for commercial) are accepted pathways.

As-Built Evidence

The As-Built stage requires confirmation that design commitments were realised in construction. For installed products, this typically means: product data sheet showing specification compliance, delivery docket or invoice confirming product installed, and commissioning or test report confirming performance. Generic substitutions post-Design stage may require re-assessment.

📋

Green Star vs NABERS. Green Star and NABERS are both GBCA-associated tools but serve different purposes. Green Star Design & As-Built certifies the design and construction quality of a building across nine categories — a snapshot at handover. NABERS rates actual operational energy and water performance of an occupied building — measured performance over a 12-month period. A Green Star 6★ building should achieve strong NABERS ratings, but Green Star certification does not guarantee NABERS ratings, and vice versa.

📊

Nine credit categories, 100 base points. Each category contains a set of credits. Credits are either fully awarded or not — there are no partial points unless the credit specifically provides a sliding scale. Innovation credits (Category 9) can be earned above the 100-point base and do not count against the maximum score but count toward the certified point total.

Category Overview

#	Category	Max Points	Key Focus Areas
01	Management	12	Green Star Accredited Professional, commissioning, tuning, building user guide, waste management, metering, building information modelling, contractor environmental management
02	Indoor Environment Quality (IEQ)	20	Ventilation rates (ASHRAE 62.1), air quality testing, thermal comfort (ASHRAE 55), daylighting, views, internal noise levels, VOC limits, hazardous materials
03	Energy	20	Greenhouse gas emissions reduction vs reference building, peak electricity demand reduction, sub-metering, on-site renewable energy, no/low combustion, electric vehicle charging, carpark ventilation
04	Transport	10	Cyclist facilities, fuel-efficient transport, public transport access, car parking provisions, green travel plan
05	Water	12	Potable water reduction (internal and external), cooling tower water efficiency, water sub-metering, sewage treatment
06	Materials	12	Steel, concrete, and timber sustainability, PVC minimisation, sustainable products, construction waste management, design for disassembly
07	Land Use & Ecology	7	Ecological value of site, change in ecological value, heat island effect, stormwater management, light pollution
08	Emissions	7	Refrigerant impacts (ODP, GWP), fire suppression agents, surface water quality, sewage treatment, airborne pollutants
09	Innovation	Bonus	Industry leadership, precedent-setting measures, Green Star Accredited Professional, technology innovation, exceptional performance

Category Deep Dives

⚡ Cat. 03 — Energy (20 pts) — The Highest-Impact Category CRITICAL ▶

Greenhouse Gas Reduction Credit

The core energy credit awards points based on the percentage reduction in greenhouse gas emissions compared to a reference building modelled to minimum NCC compliance. Points scale from 1 (10% reduction) to 15 (100% reduction — net zero).

Key metric: Predicted annual GHG emissions (kg CO₂-e/m²/year) from regulated energy uses — HVAC, lighting, hot water, and plug loads are excluded unless the credit specifically requires all-of-building.

Modelling requirement: Must use Green Star Energy Modelling Protocol. Software: IES VE, EnergyPlus, TAS, TRNSYS, or GBCA-accepted equivalent. Modeller must be a qualified engineer.

Key Energy Credits

Credit	Points	Requirement
GHG Reduction (10%)	1	10% below reference building
GHG Reduction (100%)	15	Net zero regulated energy
Peak Demand Reduction	1	10% peak kW reduction
Sub-metering	1	Major end-use sub-metering installed
On-site Renewables	1	Renewable energy system installed
No Combustion	1	No combustion for space heating/cooling
EV Charging	1	EV-ready car spaces provided

NCC alignment note: NCC 2022 Amendment 2 (2025) mandates NatHERS 7★ for residential. A typical 7★ home achieves approximately 10–15% GHG reduction vs the pre-2022 NCC baseline — equivalent to 1–2 Green Star energy points. A 6★ Green Star residential project typically achieves 80%+ reduction, requiring high-performance envelope, all-electric systems, and on-site solar.

🌬️ Cat. 02 — Indoor Environment Quality (20 pts) HEALTH ▶

IEQ is the largest category by points, reflecting the GBCA’s recognition that buildings must serve human health, not just energy efficiency. Credits address:

Ventilation & Air Quality

Fresh air rate: Must meet or exceed ASHRAE Standard 62.1 (minimum 10 L/s/person or zone-based calculation). Higher rates earn additional points. CO₂-based demand-controlled ventilation can earn credit.

IAQ testing: Post-occupancy air quality testing for VOCs, formaldehyde, CO₂, particulates. Must meet GBCA benchmarks (based on NEPM/WHO guidelines).

Hazardous materials: Asbestos, lead paint, and other hazardous materials survey required for refurbishment projects.

Thermal Comfort, Daylighting & Views

Thermal comfort: Design must meet ASHRAE Standard 55 (Thermal Environmental Conditions for Human Occupancy). PMV/PPD modelling required for air-conditioned spaces.

Daylighting: Modelled daylight factor or illuminance levels in regularly occupied spaces. Minimum 2% average daylight factor or 300 lux for ≥80% of regularly occupied area.

Views: Direct views to the outside from ≥90% of workstations / regularly occupied spaces. View must include sky or ground-level elements, not solely adjacent buildings.

💧 Cat. 05 — Water (12 pts) WATER ▶

Internal Potable Water Reduction

Credits awarded for reducing potable water consumption vs a reference building. Reference building uses AS/NZS 6400-rated fixtures at 3-star level. Achieving 4-star WELS-rated fixtures earns 1–2 points; rainwater harvesting for toilet flushing earns additional points; greywater reuse earns further credit.

Other Water Credits

External water: Reduction in irrigation potable water use. Drought-tolerant planting and/or recycled water for irrigation.

Cooling tower: Minimum 5 cycles of concentration for cooling water systems. Use of recycled water or alternative sources.

Sub-metering: Water sub-meters on major end-uses (irrigation, cooling, domestic hot water, tenant areas).

NABERS Water commitment: Where NABERS Water is applicable, commitment to achieve a target rating post-occupancy.

🧱 Cat. 06 — Materials (12 pts) MATERIALS ▶

Structural Materials

Steel: Minimum 50% recycled content in structural steel by weight. Credits for higher recycled content or Australian-manufactured steel with Environmental Product Declarations (EPDs).

Concrete: Credits for supplementary cementitious materials (SCM) substitution — fly ash, slag, or silica fume replacing Portland cement. Minimum 30% SCM substitution for one credit; higher substitution for additional credits.

Timber: 95% of timber and wood products by cost must be legally harvested and sustainably sourced — FSC or PEFC certified, or declared-source equivalent.

Products & Waste

PVC minimisation: Credits for minimising PVC (polyvinyl chloride) in specified product categories — pipes, flooring, blinds, cables.

Sustainable products: Minimum 30% of products (by cost in specified categories) must hold an Environmental Product Declaration, Good Environmental Choice Australia (GECA) certification, or equivalent.

Construction waste: Minimum 60% of waste by weight diverted from landfill during construction. Waste management plan required. Documentation via waste removal dockets.

Design for disassembly: Structural system designed to allow future disassembly and material reuse.

⭐

Three certification levels, each signalling a market position. A 4 Star building exceeds NCC minimum and represents industry best practice. A 5 Star building demonstrates Australian excellence — the top tier of mainstream market delivery. A 6 Star building represents world leadership — buildings that set the global benchmark for their type.

Certification Thresholds

Rating	Points Required	Market Signal	Typical GHG Reduction	NCC Relationship
★★★★	45–59 points	Best Practice	30–50% below reference	Significantly exceeds minimum
★★★★★	60–74 points	Australian Excellence	50–70% below reference	Market-leading performance
★★★★★★	75+ points	World Leadership	75–100% below reference	Global benchmark

Points Distribution by Category

20

Indoor Environment Quality — largest category by points

IEQ credits drive occupant health outcomes

20

Energy — critical for GHG reduction and operational performance

Most points tied to GHG reduction modelling

12

Management — systems, commissioning, and operational readiness

GSAP, tuning, metering, waste management

12

Materials — embodied carbon, recycled content, waste diversion

Steel, concrete, timber, PVC, construction waste

12

Water — potable reduction, reuse, and sub-metering

Internal, external, cooling tower

10

Transport — active travel infrastructure and reduced car dependence

Cyclist facilities, PT access, green travel plan

7

Land Use & Ecology — biodiversity, stormwater, heat island

Site selection, ecological value change

7

Emissions — refrigerants, fire suppression, surface water, air quality

ODP/GWP, sewage treatment, pollutants

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Strategy for achieving 5 Star (60 pts): A well-designed 5 Star building typically requires: ~14–16 Energy points (major GHG reduction + sub-metering + renewables), 16–18 IEQ points (good ventilation, daylighting, thermal comfort), 10 Management points (GSAP, commissioning, metering), 8–10 Materials points, 8–10 Water points, 6–8 Transport points, 4–5 Land/Ecology points. Innovation credits can bridge gaps. The tightest trade-off is usually between Energy and Materials, where budget allocation between operational and embodied carbon performance drives the design strategy.

🗺️

Applying the five principles requires six steps. Regardless of how stakeholders use the Green Star Communities principles — whether for policy, planning, design, finance, tendering, construction, or marketing — the following process should be followed to apply them with integrity. The principles are not a checklist: they require a systems approach that recognises interactions and trade-offs between all five.

Six Steps for Applying the Principles

1

Apply All Five Principles

A sustainable community applies a broad sustainability lens — environmental, social, economic, design, and governance outcomes must all be achieved. While the issues underpinning each principle may vary, the overall outcome of each should be embodied in every policy, plan, or project. Selective application that focuses only on environment while neglecting governance, or focuses on design while neglecting liveability, is not consistent with the framework.

2

Define Community Boundaries

Each community has boundaries of influence — geographical, cultural, virtual or place-based, environmental, and/or economic. Define the relevant boundaries and dimensions of influence for each of the eight community attribute types (infrastructure, buildings, public realm, people, ecology, economy, governance, services) before applying the five principles. A masterplan boundary is different from an ecological catchment boundary, which is different from a governance boundary.

3

Adapt for Context

The sub-issues listed under each principle will not all apply to every community, nor will they be relevant at every lifecycle stage. Each community must define its own local objectives and strategies by reviewing the listed issues for relevance and supplementing or reducing as appropriate. Issues should be refined in detail to remain contextually relevant to the overarching principle. Projects may also wish to prioritise or weight specific issues.

4

Adopt a Systems Approach

In a systems approach, the principles are applied to optimise synergies and trade-offs between them. This requires understanding the interactions: the liveability and environmental principles interact (green infrastructure improves both); prosperity and design principles interact (economic vitality requires good urban form); and governance principles influence the achievement of all others. Do not treat the five principles as independent workstreams — they must be integrated from the outset of the planning or design process.

5

Acknowledge and Apply Existing Tools, Plans, Codes and Guidelines

The Communities framework does not replace existing tools and mechanisms. A community needs to identify and understand how tools, plans, codes, and guidelines assist in applying the principles. Different tools have different purposes — some assess performance, some test options, some certify outcomes, some establish regulatory compliance, and others strive for innovation beyond minimum practice. The framework provides a broader context for considering all of them.

6

Apply in a Transparent and Accountable Way

Best practice application requires openness and accountability. The review and refinement of issues underpinning the principles should be undertaken with relevant stakeholders and be open to public scrutiny and input. Governance mechanisms should ensure that sustainability commitments made at planning stage are carried through design, delivery, and ongoing operation.

Application by Project Stage

Stage	User	Typical Application
Policy making	State government planning dept.	Principles inform strategic directions and policies within a regional plan
Regional planning	Consultant planner	Principles used in drafting a new planning scheme’s desired outcomes
Community planning	Local government planner / community	Neighbourhood plan development or review; community capacity building and engagement
Design	Government or private developer	Briefing the design team, ensuring assessment methodologies align with framework principles
Finance	Commonwealth Government	Funding criteria ensuring projects optimise sustainability outcomes
Tendering	Owner / developer / government	RFT or EOI for community developments — embeds sustainability as a core outcome
Deliver	Construction contractor	Informs research program around sustainable community infrastructure delivery
Evolve & maintain	Community group / Chamber of Commerce	Prioritise funding applications for infrastructure improvements
Revitalise & retrofit	Alliance (LG + consultants + contractors)	Structure design workshops for renewal of buildings, open space, community facilities
Marketing	Consumer / public	Understand what constitutes a sustainable community and the standard applied

Building thatregeneratesplace

I01 — Ecology of Place (Core C1)

I04 — Human-Scaled Living (Core C2)

I02 — Urban Agriculture (Full LBC)

I03 — Habitat Exchange (Full LBC)

I05 — Responsible Water Use (Core C3)

I06 — Net Positive Water

I07 — ENERGY + CARBON REDUCTION REQUIREMENTS

EMBODIED CARBON — 20% REDUCTION CALCULATION

I08 — NET POSITIVE CARBON

105% On-Site Renewable Energy

Embodied Carbon Offset (One-Time)

I09 — HEALTHY INTERIOR ENVIRONMENT (Core C5)

I11 — ACCESS TO NATURE (Core C11)

I10 — HEALTHY INTERIOR PERFORMANCE (Core)

IAQ MAXIMUM CONCENTRATIONS (Table 10-1)

I13 — THE RED LIST (Core C6) — Chemical Classes BANNED

COMPLIANCE PATHWAYS

I12 — RESPONSIBLE MATERIALS (Core C6)

I15 — LIVING ECONOMY SOURCING (Full LBC)

I16 — NET POSITIVE WASTE (Full LBC)

I17 — Universal Access (Core C7)

I18 — Inclusion (Core C8)

I19 — Beauty + Biophilia (Core C9)

I20 — Education + Inspiration (Core C10)

PRECONDITION 01 — AIR QUALITY STANDARDS (all project types)

PRECONDITION 03 — VENTILATION EFFECTIVENESS

Part 1: Ventilation Design

Part 2: Demand Controlled Ventilation (DCV)

PRECONDITION 04 — VOC REDUCTION (materials)

PRECONDITION 05 — AIR FILTRATION

KEY AIR OPTIMIZATIONS

THERMAL COMFORT REQUIREMENTS

ACOUSTIC REQUIREMENTS

ERGONOMICS — Feature 73 (Precondition)

KEY FITNESS PRECONDITIONS (NEB)

FITNESS OPTIMIZATIONS

KEY NOURISHMENT PRECONDITIONS (NEB)

CERTIFICATION PATHWAY

PERFORMANCE VERIFICATION — WHAT GETS TESTED ON-SITE

Energy Audit — Transition from Conventional to Permaculture (3–8 Years)

The Permaculture Design Process — 5 Stages

Stage 1: Consideration Process

Stage 2: Selection Process

Stage 3: Design and Assembly Process

Stages 4 & 5: Observation, Evaluation & Maintenance

Resources vs Yields

Cycles in Design

Function, Diversity & Stability

Complexity & Connections

Niches — Physical Sites and Conceptual Moments

Food Web — Pyramid vs Reality

Designing to Catch and Store Water

Zoning System — Energy Concentrated at Centre

Sectors — External Energy Mapping

Guilds — Plants, Animals, Elements Working Together

Broad Humid Landscape — Best House Site

Urban Garden Design

Working With Time — Succession Strategy

Edges — Boundaries Enhance Productivity

Toroidal / Branching Patterns

Flow Patterns

Traditional Cultures and Pattern

Events in Time — Pulse and Cycle

Three Major Climatic Zones

Altitude Effect

Precipitation

Windbreaks

Radiation (Solar Gain)

Three Biomass Zones of a Tree

Crown & Trunk

Detritus Zone

Root Zone

Trees and Wind

Trees, Rain, and Atmosphere

Resources vs Yields

Cycles in Design

Function, Diversity & Stability

Complexity & Connections

Niches — Physical Sites and Conceptual Moments

Building that
regenerates
place