Captures the corpus state (36 EXACT + 5 pinned community-heating
variants), the SAP 302 CHP credit cluster as the highest-leverage
remaining front, the unresolved 0.8523 / 0.1994 worksheet-factor
mysteries to per-line-walk before hypothesising, and — importantly —
the new test layout (tests/domain/sap10_calculator/) that changes every
verification command.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
The calculator tests lived under domain/sap10_calculator/{tests,worksheet/
tests,rdsap/tests,climate/tests,validation/tests}, none of which are in
pytest.ini testpaths — so CI (which collects tests/) never ran them. Relocate
all five dirs to tests/domain/sap10_calculator/{,worksheet,rdsap,climate,
validation}, mirroring the tests/domain/property_baseline/ convention, so the
cascade-pin / golden / e2e conformance suites run in CI.
Mechanics:
- git mv preserves history (110 files).
- Flattening the trailing /tests keeps each file's depth-to-repo-root
identical, so all 16 repo-root parents[4] fixture refs stay valid. Only
test_pcdb_etl.py's parents[1] (→ pcdb data) and one hardcoded absolute
golden-fixture path in test_cert_to_inputs.py needed rebasing.
- Cross-imports rewritten domain.sap10_calculator.worksheet.tests →
tests.domain.sap10_calculator.worksheet (21 files incl. the external
importer backend/documents_parser/tests/test_summary_pdf_mapper_chain.py).
- Golden-fixture path strings in test_summary_pdf_mapper_chain.py +
scripts/fetch_cohort2_api_jsons.py updated to the new location (the JSONs
moved with the rdsap tests).
load_cells / gitignored worksheet xlsx: the xlsx-pinned tests (test_dimensions
/ ventilation / water_heating) read 2026-05-19-17-18 RdSap10Worksheet.xlsx,
which is gitignored (.gitignore `*.xlsx`) and so absent in CI. _xlsx_loader.
load_cells now pytest.skip()s when the file is absent, so those tests run
locally and skip cleanly in CI instead of erroring — no new CI failures from
the move, and the gitignore policy is respected.
Verified: tests/domain/sap10_calculator + backend/documents_parser +
tests/domain/property_baseline = 2248 pass, 1 skipped; pyright resolves the
new import paths with zero import-resolution errors.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
test_heating_systems_corpus.py (and one pcdb-1 cross-check in
test_cert_to_inputs.py) read the 001431 controlled-variable corpus PDFs
directly at runtime from `sap worksheets/heating systems examples/`, but
that directory was never committed — it was supplied locally on
2026-05-30 and only ever existed on dev machines. CI therefore errored
with "no Summary PDF in …" for all 57 corpus variants.
Commit the 82 corpus PDFs (41 populated variant folders × Summary +
P960, 4.7 MB) in place so the cascade-vs-worksheet residual pins run in
CI, matching the existing convention where the U985 / 000565
conformance fixtures are committed under
backend/documents_parser/tests/fixtures/ (31 PDFs already tracked).
Only the .pdf fixtures are added; the stray .DS_Store and a P960 .txt
dump in pcdb 1/ are left untracked.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Two unrelated breakages surfaced after merging the PR into this branch;
neither was caused by the appliances/cooking work.
test_appendix_u.py (9 failures) — signature drift + wrong methodology
label. The climate lookups were renamed `external_temperature_c(region=…)`
→ `(region_or_climate, month)` when PostcodeClimate support landed for
the demand cascade, but the tests still passed `region=`. The expected
values match our SAP 10.2 _TABLE_U1/U2/U3 exactly (UK-avg Jan 4.3 °C,
Thames Jul 17.9 °C, solar Jul 189 W/m², Shetland Jan wind 9.5 m/s), so
these are valid 10.2 coverage — fixed the call signature to positional
and corrected the mislabelled "SAP 10.3" docstrings to SAP 10.2 (we
track 10.2 deliberately). Also converted pytest.approx → abs(x-y)<=tol
per the repo convention; pyright on the file drops 48 → 0.
test_table_32.py (2 failures) — the parametrised "match PDF p.95" test
pinned heating oil (code 4) = 7.64 and FAME (code 73) = 5.44, but the
table deliberately diverges from the PDF for these two carriers: oil =
5.44 (Slice S0380.131, two independent lodging engines agree the PDF
7.64 is the outlier) and FAME = 7.64 (Slice S0380.168). Updated the two
expected values to the worksheet-canonical figures the table actually
uses, with inline citations + a docstring note on the divergence.
Full calculator + property_baseline + heating-corpus suites: 1748 pass,
0 fail. pyright net-improving on both files.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
ADR-0014 BillDerivation prices a per-end-use EnergyBreakdown
(HEATING / HOT_WATER / LIGHTING / PUMPS_FANS / APPLIANCES / COOKING).
SapResult already carried the first four but not appliances or cooking,
so a downstream SapResult→EnergyBreakdown adapter had to stub those two
at 0 kWh — understating the bill by the whole unregulated electricity
load. Surface them so the property_baseline side can wire the sections.
Adds two output-only fields to CalculatorInputs + SapResult, threaded
exactly like lighting_kwh_per_yr:
appliances_kwh_per_yr — SAP 10.2 Appendix L L13/L14/L16a annual E_A
(sum of the §5 (68) monthly appliances kWh)
cooking_kwh_per_yr — SAP 10.2 Appendix L L20 (p.91) ELECTRICITY
estimate E_cook = 138 + 28×N
Both values already existed in cert_to_inputs.py (appliances_monthly_kwh,
cooking_monthly_kwh) — reused, not recomputed.
Fuel attribution: cooking_kwh_per_yr is the L20 ELECTRICITY figure (the
field docstring says so), distinct from the L18 cooking heat GAIN
(35 + 7N W) the §5 internal-gains cascade uses. The bill adapter should
treat cooking as an electricity carrier; a gas-cooker split, if ever
needed, is a separate follow-up.
HARD CONSTRAINT honoured — output-only, zero rating drift. Appliances +
cooking are unregulated and are NOT fed into ECF / total_fuel_cost /
CO2 / primary energy / sap_score. Every golden-fixture, Elmhurst e2e
SapResult pin, section cascade pin, and heating-corpus residual stays
byte-identical (1165 rated pins green). The synthetic CalculatorInputs
fixtures set the new fields non-zero on purpose so the existing cost/PE
reconciliation assertions act as leak detectors.
New focused test asserts both fields are populated (non-zero) and
threaded unchanged onto SapResult, with cooking equal to the L20
electricity figure (138 + 28×occupancy) to 1e-9. pyright net-zero
111 → 111.
Note: 11 pre-existing failures in test_appendix_u.py / test_table_32.py
arrived with the recently absorbed PR and are unrelated to this change
(they fail identically on the clean branch); flagged separately.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Closes the "no system" corpus variant fully (ΔSAP +1.18 → <1e-4 on all
four metrics).
The cert lodges §15.0 "Water Heating Code: NON / SapCode 999" and §15.1
"Hot Water Cylinder Present: No". Per RdSAP 10 §10.7 (PDF p.55) "No
water heating system" verbatim: "the calculation is done for an
electric immersion heater. If the electric meter is dual the immersion
heater is also dual, but is a single immersion otherwise... for a
cylinder defined by the first row of Table 28 (110 litres) and the
first row of Table 29." Table 29 row 1 gives age-band cylinder
insulation (age G -> 25 mm foam) and assumes a cylinder thermostat
present for immersion-heated DHW.
The BRE-approved Elmhurst engine confirms the substitution: the P960
worksheet header lodges "WHS: 903 Electric immersion, Single", a 110 L
cylinder, and storage loss (56) = 594.32 kWh/yr, so HW (64) = (45)
1935.37 + 594.32 = 2529.6927.
Pre-slice the cascade trusted the lodged "no cylinder" -> added no
storage loss and a spurious Table 3a keep-hot combi loss; the wrong HW
heat-gains also propagated through §5/§7, over-stating the base MIT by
+0.25 K and space fuel by +228 kWh. New
`_apply_rdsap_no_water_heating_system_default(epc)` rebinds the epc at
the top of cert_to_inputs (the demand cascade delegates here too) when
water_heating_code == 999, injecting WHC 903 + electricity fuel +
110 L cylinder + Table 29 insulation + assumed cylinder thermostat.
This closes HW fuel AND the downstream space residual in one move.
Age bands A-F (12 mm loose jacket) raise UnmappedSapCode — no corpus
member exercises that and the Table 2 loss-factor dispatch only has the
factory-foam path plumbed. Gate is keyed on code 999, unique to "no
system" in the corpus; 40 other variants + 858 section pins + 6 U985
fixtures unchanged. 936 pass; pyright net-zero 32 -> 32.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Closes the residual S0380.177 exposed on oil 6. The cascade's central
heating pump used the bare Table 4f age default (41 kWh for "2013 or
later") but the worksheet (230c) = 53.3 kWh.
SAP 10.2 Table 4f (PDF p.175) footnote a) on the "Circulation pump"
rows reads verbatim: "Multiply by a factor of 1.3 if room thermostat
is absent." oil 6 lodges control code 2101 ("No time or thermostatic
control of room temperature") = no room thermostat, so 41 x 1.3 = 53.3
= ws (230c) EXACTLY; pumps/fans (231) = 53.3 + 100 (liquid-fuel boiler
flue fan/pump) = 153.3 EXACT. Same root cause (absent room thermostat)
as the S0380.177 Table 4c(2) interlock fix — both keyed on the new
`_BOILER_NO_ROOM_THERMOSTAT_CONTROL_CODES = {2101, 2102}`.
`_table_4f_circulation_pump_kwh` now multiplies the resolved pump kWh
by `_TABLE_4F_NO_ROOM_THERMOSTAT_PUMP_MULTIPLIER = 1.3` when the main's
control code is in that set.
oil 6 now FULLY EXACT on all four metrics (ΔSAP/cost/CO2/PE < 1e-4).
The sibling oil 5 (same "2013 or later" pump age but control 2106 WITH
a room thermostat) keeps the bare 41 kWh and is unaffected — as do the
other 39 corpus variants (2101/2102 appear only on oil 6). 935 pass;
pyright net-zero 32 -> 32.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
oil 6 (B30K standard liquid-fuel boiler, Table 4b code 126 winter 80 /
summer 68) lodges Main Heating Controls Sap code 2101 ("No time or
thermostatic control of room temperature") WITH a cylinder thermostat.
The cascade's `no_interlock` gate only checked the cylinder thermostat,
so oil 6 kept raw efficiency despite the P960 worksheet header lodging
"Boiler Interlock: No".
Per RdSAP 10 §3 (PDF p.57): boiler interlock is "assumed present if
there is a room thermostat and (for stored hot water systems heated by
the boiler) a cylinder thermostat. Otherwise not interlocked." Control
code 2101 (and 2102 "Programmer, no room thermostat") provides no room
thermostat — the two Table 4e Group 1 rows carrying the "+0.6 °C /
Table 4c(2)" annotation — so the boiler is NOT interlocked regardless
of the cylinderstat. SAP 10.2 Table 4c(2) (PDF p.169) "No thermostatic
control of room temperature – regular boiler" then deducts 5pp from
BOTH the Space and DHW seasonal efficiency.
Three changes in cert_to_inputs.py:
- new `_BOILER_NO_ROOM_THERMOSTAT_CONTROL_CODES = {2101, 2102}`;
- `no_interlock` now ORs room-thermostat absence with the existing
stored-HW cylinderstat-absence test (the RdSAP §3 conjunction);
- the Space -5pp leg fires for Table 4b non-PCDB boilers (code
101-141), not only PCDB-record boilers; the DHW leg is gated on a
cylinder being present (Table 4c(2) combi DHW = 0).
Result for oil 6: space fuel (211) = 13446.3457 EXACT, HW fuel (219) =
4099.5872 EXACT. ΔSAP +3.0518 → +0.0782, Δcost -£69.79 → -£1.68,
ΔCO2 -240.66 → -1.71, ΔPE -1112.66 → -18.61.
The spec-correct fix exposes a single residual cause (per
[[feedback-software-no-special-handling]]): the central heating pump
(230c) — cascade reads pump_age=2 → Table 4f 41 kWh but ws (230c) =
53.3 kWh. The 12.3 kWh gap fully accounts for the residual across all
three metrics; pinned as the S0380.178 forcing function.
All other 40 corpus variants + 858 section pins + 6 U985 fixtures
unchanged (2101/2102 boiler codes appear only on oil 6). Pyright
net-zero.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
PR feedback: the SapResult -> Performance mapping should be a method, not a
free function you must know exists in the rebaseliner. Put the factory on
the target as `Performance.from_sap_result`, beside its sibling
`lodged_performance` and mirroring `Epc.from_sap_score` (the factory this
mapping already calls).
Not a `SapResult.to_performance()`: that would make the SAP calculator
import `Performance` (a property_baseline type), re-introducing the
engine->consumer coupling removed by the SapCalculator ABC. SapResult is a
TYPE_CHECKING-only import in performance.py (the body only reads attributes),
so the calculator module is not pulled in at runtime.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
PR feedback: annotate locals assigned from a method-call return or
attribute access, even though pyright infers them — the type is visible at
the assignment without chasing the callee. `result: SapResult` and
`sap_version: Optional[float]` in rebaseline(). Local annotations are not
evaluated at runtime, so the TYPE_CHECKING-only SapResult import stands.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
PR feedback: prefer an abstract base the calculator inherits from over a
structural Protocol. Define `SapCalculator(ABC)` in the calculator package
(the engine owns its own contract) and have `Sap10Calculator` inherit it;
a future methodology is another subclass. Placing the ABC with the engine —
not in property_baseline — keeps the dependency pointing consumer -> engine
(sap10_calculator imports nothing from property_baseline). Consistent with
the repo's existing port convention (FuelRatesRepository(ABC)).
CalculatorRebaseliner keeps its reference to SapCalculator type-only (under
TYPE_CHECKING), so the module still does not import the calculator at
runtime. Test fakes now inherit the ABC since structural conformance no
longer applies.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
SAP 10.2 §4 line 7702 (PDF p.137) defines (61)m as "Combi loss for
each month from Table 3a, 3b or 3c (enter '0' if not a combi
boiler)". Table 4b sub-rows 128 / 129 / 130 are explicit combi sub-
rows per the spec row names:
128: Combi oil boiler, pre-1998
129: Combi oil boiler, 1998 or later
130: Condensing combi oil boiler
Pre-slice `_table_3a_combi_loss_default_applies` gated only on
`main_heating_category ∈ {1, 2, 3, 6}`. The Elmhurst mapper leaves
`main_heating_category=None` on Table 4b liquid-fuel boilers (FAME,
HVO, B30K) — the cascade fell through to (61)m=0 despite the lodged
SAP code being a combi sub-row, under-counting (62)m by 600 kWh/yr
for FAME combi certs.
Extended the helper with a `_TABLE_4B_COMBI_OR_CPSU_CODES` fall-
through (set already exists for the symmetric `_primary_loss_
applies` Table 4b non-combi branch — see S0380.146). The set carries
the canonical combi + CPSU sub-row codes (103/104/107/108/112/113/
118/120-123/128-130). For cylinder-lodged certs the existing
`if epc.has_hot_water_cylinder: combi_loss_override = zero_monthly`
guard in `_water_heating_worksheet_and_gains` still pre-empts the
combi-loss fall-through correctly — non-combi codes with cylinders
remain (61)m=0.
Closures (heating-systems corpus 001431):
oil 3 (code 128, FAME, no cylinder) ALL EXACT (±0.0000):
ΔSAP_c +2.5863 → -0.0000
Δcost -£61.89 → -£0.00
ΔCO2 -14.58 → +0.00
ΔPE -967.10 → +0.00
oil 4 (code 129, FAME, no cylinder) ALL EXACT (±0.0000):
ΔSAP_c +2.5603 → +0.0000
Δcost -£56.66 → +£0.00
ΔCO2 -13.35 → +0.00
ΔPE -884.90 → +0.00
Oil 6 (code 126, NOT a combi, with cylinder) unchanged — the fix
is gated on the combi sub-row set. Cohort moves from 9 pinned
residuals to 7.
933 pass + 0 fail (+1 new mapper test). Pyright net-zero on cert_
to_inputs.py + tests.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
SAP 10.2 Table 4e Group 3 (PDF p.173) — heat-network control codes
2301-2314 dispatch to control_type 1, 2, or 3. Code 2306 = "Charging
system linked to use of heating, programmer and TRVs" →
control_type=3, temperature_adjustment=0. Per Table 9 the elsewhere-
zone off-hours depend on control_type: type 1/2 → (7, 8); type 3 →
(9, 8). The two extra off-hours change the §7 (90) T_rest mean by
~0.6 K → (92) MIT by ~0.4 K → (98) SH demand by ~390 kWh/yr.
Pre-slice diagnosis: cascade defaulted `main_heating_control=2`
(modal RdSAP) when the §14.0 "Main Heating Controls Sap" field was
empty. The 5 community heating corpus variants ALL lodge the SAP
code in §14.1 Community Heating "Heating Controls SAP" instead
(format: bare 4-digit integer, e.g. "2306"). The extractor was
storing this in `CommunityHeating.heating_controls_sap` but the
mapper only read `mh.heating_controls_sap` (§14.0).
Two changes:
1. `_elmhurst_sap_control_code` extended to accept bare 4-digit form
("2306") in addition to the §14.0 narrative form ("SAP code 2106,
Programmer, room thermostat and TRVs"). Empty-string returns None
instead of swallowing through the original `re.match` regex.
2. `_map_elmhurst_sap_heating` falls through to
`mh.community_heating.heating_controls_sap` when the §14.0 main
block leaves `heating_controls_sap` empty.
Closures (heating-systems corpus 001431):
CH1 ΔSAP_c -1.0572 → +0.0000 EXACT
Δcost +£24.36 → -£0.00 EXACT
CH3 ΔSAP_c -1.0572 → +0.0000 EXACT
Δcost +£24.36 → -£0.00 EXACT
CH2/CH4 SAP-side flip ±0.42 → ±0.53 (CHP-split blend reacts to
the now-lower SH demand × CHP rate)
CH6 ΔSAP_c -8.4406 → -7.4942 (DLF=1.0 P960 quirk untouched)
Remaining CH1/CH3 ΔCO2 -23.60 / ΔPE -208.23 is the §13a (372)
"Electrical energy for heat distribution" line (118.38 kWh × electric
factors 0.1993 CO2 / 1.760 PE). Cascade doesn't currently meter this
electricity overhead separately from heat-network heat — next slice.
932 pass + 0 fail (+5 new mapper tests). No regressions on the other
36 corpus variants — the mapper change is gated on `mh.community_
heating is not None` and only fires when §14.0 leaves the control
field empty. Pyright net-zero on mapper.py + corpus test.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
SAP 10.2 §4 "Heat networks" (PDF p.17 line 1482):
"Primary circuit loss for insulated pipework and cylinderstat
should be included (see Table 3)."
SAP 10.2 Table 2b note b (PDF p.159) verbatim:
"Multiply Temperature Factor by 0.9 if there is separate time
control of domestic hot water (boiler systems, warm air systems
and heat pump systems)."
The Table 2b note b ×0.9 multiplier is restricted to "boiler / warm
air / heat pump systems" — community heating is omitted from that
verbatim list. Pre-slice the cascade applied the ×0.9 reduction
unconditionally when DHW was separately timed, AND omitted the Table
3 primary-loss path for heat-network mains entirely. Combined the
two gaps under-counted (62)m HW total demand by ~320 kWh/yr for
heating-systems corpus 001431 community heating 1 (8164 + 0 vs
448.74 + 273.90 spec losses).
Three changes:
1. New `_HEAT_NETWORK_PIPEWORK_INSULATION_FRACTION = 1.0` constant.
`_primary_loss_override` selects this for heat-network mains
instead of the RdSAP §3 age-band default, per the spec's literal
"insulated pipework" + back-solve from worksheet (59) Jan = 23.26
= 31 × 14 × (0.0091×3 + 0.0263).
2. Extended `_primary_loss_applies` with a new branch: heat-network
main + WHC ∈ {901, 902, 914} + cylinder present → primary loss
applies.
3. New `_table_2b_note_b_multiplier_applies(epc, main)` predicate
that gates the ×0.9 storage-loss reduction on the spec's verbatim
system-type list, returning False for heat-network mains. The
primary-loss `_separately_timed_dhw` continues to return True for
community heating (Table 3's "separately timed" row is system-
type-agnostic and gives h=3 all year).
Closures (heating-systems corpus 001431):
CH1 HW kWh 3391.90 → 3854.12 (= ws 3854.1175, abs Δ < 1e-3)
CH1 HW cost £143.82 → £163.41 (= ws £163.41, EXACT)
CH1 (65)m heat gains 793.51 → 1221.62 (= ws 1221.62, EXACT)
CH2/CH3/CH4/CH6 same shape — HW path closes against ws (310).
§4 fix is spec-correct on all 5 CH variants. The closure surfaces a
separate §7 MIT (92)m over-count of +0.46 K (cascade Jan = 17.22 vs
ws 16.76) that the pre-slice (65)m gain under-count was masking. Per
[[feedback-software-no-special-handling]] apply the spec-correct
fix uniformly; new pinned residuals reflect the exposed MIT gap.
New residuals (vs pre-slice):
CH1 ΔSAP -0.5273 → -1.0572 ΔPE -9.15 → +408.67
CH2 ΔSAP -0.0076 → -0.4187 ΔPE +1506 → +1779
CH3 ΔSAP -0.5273 → -1.0572 ΔPE -387.03 → -239.03
CH4 ΔSAP -0.0076 → -0.4187 ΔPE +494.61 → +767.13
CH6 ΔSAP -8.0295 → -8.4406 ΔPE +7864.60 → +8137.11
927 pass + 0 fail (+1 new test). No regressions on the other 36
corpus variants — the gate is narrow on `_is_heat_network_main`.
Pyright net-zero (43 → 43) on cert_to_inputs.py + tests.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Closes CH1 (boilers) + CH3 (HP) HW CO2 / PE residuals by routing
the HW cost / CO2 / PE factor lookups through the heat-network main
when WHC ∈ {901, 902, 914} ("HW from main heating system"). Pre-
slice the cascade honoured Elmhurst Summary §15.0's
`water_heating_fuel_type = "Mains gas"` placeholder on community-
heated certs, mis-routing HW through Table 12 code 1 (mains gas,
3.48 p/kWh / 0.21 CO2 / 1.13 PE) instead of the heat-network code
(4.24 p/kWh + Table 12 code 41 / 51 / 53 / 54 with Table 4a heat-
source-eff scaling per S0380.172).
Per SAP 10.2 §C1 + RdSAP 10 §C (PDF p.49 + p.58) the HW heat
delivered by a heat-network main is supplied through the same
network as SH: spec block 10b (342a)/(342b) computes HW cost as
`(310a) × CHP_price + (310b) × boiler_price`, mirroring SH's
(340a)/(340b) split. Block 12b (365)/(366) and 13a (465)/(466)
likewise apply the heat-source-eff division on HW.
Three layers wired:
1. New `_is_community_heating_hw_from_main(epc)` predicate. Gates
on WHC ∈ {901, 902, 914} + heat-network main + SAP code in
`_HEAT_NETWORK_HEAT_SOURCE_EFFICIENCY` table (S0380.172 — only
301 boilers + 304 HP). SAP 302 (CHP+boilers) is excluded
because the 35%/65% split needs the displaced-electricity
credit cascade per spec block 13b (464)/(466) on BOTH SH and HW
paths — both converge in a single follow-up slice.
2. `_hot_water_fuel_cost_gbp_per_kwh` gains a keyword-only
`inherit_main_for_community_heating: bool = False` parameter.
When True, returns `_fuel_cost_gbp_per_kwh(main, prices)` —
same helper that already applies the S0380.171 CHP blend +
heat-network rate. The orchestrator passes
`inherit_main_for_community_heating=_is_community_heating_hw_
from_main(epc)` at the cost-rate construction site.
3. `_hot_water_co2_factor_kg_per_kwh` and `_hot_water_primary_
factor` get top-level branches: when the predicate fires, return
`Table_12_factor × _heat_network_heat_source_efficiency_scaling
(main)` — same scaled-factor return as the SH path in S0380.172.
Closures (heating-systems corpus block 11b):
CH1 (Boilers/Gas) ΔPE −967 → −9 (essentially closed)
CH1 ΔCO2 −126 → +52 (shifted across worksheet)
CH3 (HP/Elec) ΔPE +1749 → −387 (~78% closure)
CH3 ΔCO2 +473 → −86 (~82% closure)
Cost / SAP signs flip on CH1 / CH3 (was −£14 / +0.59 SAP, now
+£12 / −0.53 SAP) — HW cost now matches the worksheet's (342) line
exactly, exposing a +£12 lighting / standing overage that was
previously masked by the HW under-charge. Per [[feedback-software-
no-special-handling]] the pre-slice near-zero on CH1 / CH3 cost was
an offsetting-bugs artifact; the spec-correct fix surfaces the real
lighting / standing gap as the next forcing function.
CH2 / CH4 / CH6 (SAP 302) unchanged from S0380.171 / S0380.172 pins
— gated out per the heat-source-eff-table membership check.
Test baseline at HEAD: 926 pass + 1 skipped (was 926 + 1 at
predecessor 36d4bf87). Pyright net-zero on affected files
(cert_to_inputs.py, test_heating_systems_corpus.py): 32 → 32.
Per [[feedback-spec-citation-in-commits]] the rule cites SAP 10.2
§C1 verbatim ("heat from CHP + back-up boilers, via a heat main")
and RdSAP 10 §C defaults (PDF p.58).
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Closes the CO2 / PE residuals for CH1 (boiler community heating, SAP
code 301) and CH3 (HP community heating, SAP code 304) via SAP 10.2
Table 4a (PDF p.164) heat-network heat-source efficiency:
"Boilers (RdSAP)" → 80% → code 301
"Heat pump (RdSAP)" → 300% → code 304
Spec block 13a (PDF p.153) (467) "PE associated with heat source 2"
= [(307b)+(310b)] × 100 / (467b) — i.e. fuel input = network_input ×
100 / heat_source_eff before applying Table 12 PE factor. Block 12b
(367) mirrors for CO2. The cascade meters network_input directly
(eff = 1/DLF for the cost path via Table 12 heat-network rate), so
PE / CO2 factors are scaled by 1/heat_source_eff at lookup time —
mathematically equivalent to spec's (network_input / eff) × factor.
Three changes:
1. New `_HEAT_NETWORK_HEAT_SOURCE_EFFICIENCY: Final[dict[int, float]]`
keyed on SAP code: 301 → 0.80, 304 → 3.00. SAP 302 (CHP+boilers)
is omitted — the 35%/65% split + displaced-electricity credit per
spec block 13b (464)/(466)/(364)/(366) needs the .171 follow-up.
2. New `_heat_network_heat_source_efficiency_scaling(main)` helper
returning 1.0 for non-heat-network mains + SAP 302, and
1/heat_source_eff for SAP 301 / 304.
3. Wired into `_main_heating_co2_factor_kg_per_kwh` and
`_main_heating_primary_factor` non-electric branches (heat
networks are non-electric per `_is_electric_main`). Both functions
return `Table_12_factor × scaling` so the cascade's
`network_input × scaled_factor` lands on the spec
`(network_input / eff) × Table_12_factor`.
Closures vs pre-S0380.172 residuals (heating-systems corpus block 11b):
variant ΔCO2 ΔPE notes
CH1 (Boilers/Gas) -787→-126 -3827→-967 ~75-84% closure
CH2 (CHP/Gas) unchanged unchanged excluded — SAP 302
CH3 (HP/Elec) +1614→+473 +11879→+1749 ~71-85% closure
CH4 (CHP/Oil) unchanged unchanged excluded — SAP 302
CH6 (CHP/Coal) unchanged unchanged excluded — SAP 302
Cost + SAP unchanged on all 5 (heat-network rate × network_input via
Table 12 is correct regardless of heat-source efficiency).
Residual CH1 / CH3 gap drivers (follow-up scope):
- WHC=901 HW path: cascade reads cert-lodged "Mains gas" as HW fuel
on community-heating certs; should fall through to main fuel for
the heat-network so the scaling applies on HW side too.
- Elmhurst 0.8523 multiplier on heat-network energy column (worksheet
(467) energy = spec_formula × 0.8523 uniformly across non-CHP
heat-network rows; mechanism not yet identified — spec divergence
candidate for SAP_CALCULATOR.md §8).
Cohort no-regression verified: 9 ASHP + 38 cohort-2 golden fixtures
pass unchanged; the 41-variant heating-systems corpus has identical
residuals for non-heat-network certs. The 2 closed CH variants are
re-pinned at their new sub-1000 magnitudes.
Test baseline at HEAD: 926 pass + 1 skipped (was 926 + 1 at
predecessor a4b5f4e7; pin updates net to 0). Pyright net-zero on
affected files (cert_to_inputs.py, test_heating_systems_corpus.py):
32 → 32.
Per [[feedback-spec-citation-in-commits]] the dispatch table cites
SAP 10.2 Table 4a (PDF p.164) verbatim row labels.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Closes the +£104 cost / +4.5 SAP gap on CH2/CH4 (community heating
with CHP-fed mains-gas / oil boilers) by implementing the RdSAP 10
§C / SAP 10.2 Appendix C (PDF p.58) default heat-fraction split:
"If CHP (waste heat or geothermal treat as CHP):
- fraction of heat from CHP = 0.35
- CHP overall efficiency 75%
- heat to power ratio = 2.0
- boiler efficiency 80%"
Verified against the corpus block 9b lodgement: CH2 worksheet (303a)
= 0.3500 + (303b) = 0.6500 + (305) = 1.00 + (306) DLF = 1.45. The
worksheet block 10b cost cascade applies (340a) = (307a) × CHP_price
(Table 12 code 48 = 2.97 p/kWh) + (340b) = (307b) × boiler_price
(Table 12 codes 51-58 = 4.24 p/kWh) with (307a) = 0.35 × (307),
(307b) = 0.65 × (307).
Pre-slice the cascade dispatched single-fuel code 48 (CHP) for every
CHP variant and billed 100% of heat at 2.97 p/kWh, under-charging by
~£104/yr versus the worksheet's 35% × 2.97 + 65% × 4.24 = 3.7945
p/kWh blended rate.
Three layers wired:
1. Datatype — new fields on `MainHeatingDetail`:
- `community_heating_chp_fraction: Optional[float]`
- `community_heating_boiler_fuel_type: Optional[int]`
None on individually-heated dwellings + non-CHP heat networks
(Boilers-only + Heat-pump networks bill at a single Table 12 code
via main_fuel_type, unchanged path).
2. Mapper — new `_elmhurst_community_chp_split(community)` helper +
`_RDSAP_COMMUNITY_CHP_FRACTION_DEFAULT = 0.35` constant. When the
§14.1 Community Heat Source is "Combined Heat and Power": returns
(0.35, boiler_fuel_code) where boiler_fuel_code is resolved from
the §14.1 Community Fuel Type via the existing
`_ELMHURST_COMMUNITY_BOILER_FUEL_TO_TABLE_12` dispatch (gas → 51,
oil → 53, coal → 54).
3. Cascade — `_fuel_cost_gbp_per_kwh` now returns
`chp_frac × CHP_price + (1 - chp_frac) × boiler_price`
when both new fields are set on Main 1. Per [[feedback-spec-
citation-in-commits]] the implementation cites RdSAP 10 §C
verbatim. Non-CHP heat networks + individually-heated certs route
through the existing single-fuel-code branch unchanged.
5 new AAA tests parametrized over the 5 CH corpus variants in
`test_community_heating_mapper_populates_chp_split_fields` assert
the per-variant (chp_fraction, boiler_fuel_code) populates correctly.
Closures vs pre-S0380.171 residuals (heating-systems corpus block 11b):
variant ΔSAP Δcost status
CH1 (Boilers/Gas) +0.5915 -£13.63 unchanged (no CHP split)
CH2 (CHP/Gas) +4.50→-0.0076 -£104→+£0.17 ✓ CLOSED
CH3 (HP/Elec) +0.5915 -£13.63 unchanged (no CHP split)
CH4 (CHP/Oil) +4.50→-0.0076 -£104→+£0.17 ✓ CLOSED
CH6 (CHP/Coal) -3.52→-8.03 +£81→+£185 REGRESSED
The CH6 regression is exposed (not caused) by the spec-correct split:
pre-slice CH6 sat at -3.52 SAP / +£81 by coincidence — the cascade's
CHP-only pricing (2.97 p/kWh) cancelled with cascade DLF=1.45
(Table 12c age G default) against the CH6 worksheet's lodged DLF=1.0.
Per [[feedback-software-no-special-handling]] apply the spec-correct
fix uniformly; the pre-fix near-zero was an offsetting-bugs artifact,
not a deliberate non-spec rule.
The CH6 worksheet (306) DLF=1.0 is a cert-side quirk not currently
surfaced through the Summary PDF: CH4 and CH6 §14 lodgements are
IDENTICAL except for Community Fuel Type ("Mineral oil or biodiesel"
vs "Coal"), yet CH6's worksheet (306) = 1.0000 while CH4's = 1.4500.
The Elmhurst engine appears to override DLF for the coal-CHP combo
via a path not visible in the Summary; a follow-up slice will need to
either (a) add a §17 assessor-lodged DLF extractor or (b) extend the
mapper's age-band → DLF dispatch with a community-fuel-specific
override.
CO2 / PE residuals on all 5 CH variants are unchanged — this slice
touches cost only. The CO2 / PE cascade still needs: (1) the CHP
electricity-credit line (worksheet (464)/(466)/(364)/(366) per SAP
10.2 §13b spec — displaced-electricity reduction), (2) community-HP
COP cascade for CH3 (Table 12 code 41 PE/CO2 isn't divided by COP),
and (3) heat-network overall blended-factor (486)/(386) calc.
Test baseline at HEAD: 926 pass + 1 skipped (was 921 + 1 at
predecessor 9f0d23ad). Pyright net-zero on affected files
(epc_property_data.py, mapper.py, cert_to_inputs.py,
test_heating_systems_corpus.py + elmhurst_site_notes.py): 65 → 65.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Closes the 5 community-heating variants in the heating-systems corpus
(community heating 1/2/3/4/6 on property 001431). Pre-slice the
mapper returned `MainHeatingDetail.main_fuel_type=''` for every
community-heating cert because §14.0 lodges no Fuel Type — only EES
'COM' + a Table 4a heat-network SAP code (301/302/304). The cascade
strict-raised `MissingMainFuelType` per S0380.132. The actual fuel
that bills the cascade lives in the §14.1 Community Heating/Heat
Network block, which the extractor was skipping entirely.
SAP 10.2 Table 12 (PDF p.189) defines the heat-network fuel codes:
Boilers + Mains Gas → 51 (heat from boilers — mains gas)
Boilers + Mineral oil → 53 (heat from boilers — oil)
Boilers + Coal → 54 (heat from boilers — coal)
Boilers + Biomass → 43 (heat from boilers — biomass)
Combined Heat and Power → 48 (heat from CHP; fuel-agnostic)
Heat pump + Electricity → 41 (heat from electric heat pump)
Per spec text the upstream fuel determines the boiler-side code; CHP
is fuel-agnostic at the Table 12 cost / CO2 / PE level.
Three layers wired:
1. Survey schema — new `CommunityHeating` dataclass alongside
`MainHeating2` carrying the §14.1 fields (heating_type,
community_heat_source, community_fuel_type, heating_controls_ees,
heating_controls_sap, chp_fuel_factor). Mutually exclusive with
`main_heating_2` at the §14.1 level. Attached as
`MainHeating.community_heating: Optional[CommunityHeating] = None`.
2. Extractor — new `_extract_community_heating()` method bracketed by
"14.1 Community Heating/Heat Network" / "14.2 Meters". Returns
None on individually-heated dwellings (no Community Heat Source
lodged). Wired into `_extract_main_heating()`.
3. Mapper — new `_resolve_community_heating_fuel_code(heat_source,
fuel)` dispatch helper + `_ELMHURST_COMMUNITY_BOILER_FUEL_TO_TABLE_12`
constant for the boiler upstream-fuel split. Wired in
`_map_elmhurst_sap_heating` after the EES-code-to-fuel dispatch
and before the strict-raise on absent SAP code.
Per the standard slice workflow + [[feedback-aaa-test-convention]]:
- 5 new AAA tests in `test_community_heating_mapper_resolves_table_12_
fuel_code` parametrized over the 5 corpus variants, asserting the
mapper resolves the expected Table 12 code per variant.
- The existing parametrized residual-pin test in
`test_heating_systems_corpus_residual_matches_pin` picks up the
5 community-heating variants with cascade-side residuals pinned as
forcing functions for follow-up slices:
variant dSAP dcost dCO2 dPE
CH1 (Boilers/Gas) +0.59 -£14 -787 -3827
CH2 (CHP/Gas) +4.50 -£104 -1430 +1506
CH3 (HP/Elec) +0.59 -£14 +1614 +11879
CH4 (CHP/Oil) +4.50 -£104 -4397 +495
CH6 (CHP/Coal) -3.52 +£81 -2935 +7865
These reflect open cascade-side work (SAP 10.2 Appendix C CHP/
boiler heat-fraction split missing — cascade treats CHP+Boilers as
100% CHP; community-HP COP cascade missing — cascade doesn't divide
delivered heat by COP for Table 12 code 41; heat-network overall
CO2/PE blended-factor cascade missing — cascade doesn't compute
worksheet rows (386)/(486)). Pinned per [[feedback-zero-error-strict]];
follow-up slices close gaps and re-pin smaller residuals.
- `_BLOCKED_BY_MISSING_MAIN_FUEL_TYPE` tuple now empty; the
blocked-tier test pytest-skipped via `pytest.mark.skipif` with a
reason naming this slice.
Test baseline at HEAD: 921 pass + 1 skipped (was 916 + 0 at
predecessor 7e08e7af). Pyright net-zero on affected files
(elmhurst_site_notes.py, elmhurst_extractor.py, mapper.py,
test_heating_systems_corpus.py): 32 → 32.
Per [[feedback-spec-citation-in-commits]] the dispatch is grounded
in SAP 10.2 Table 12 (PDF p.189). Per
[[feedback-bigger-slices-for-uniform-work]] all 5 variants land in
one slice — the work is uniform (single Elmhurst label dict + single
dispatch helper) and the per-variant residuals surface together
because of cascade-side gaps, not mapper-side variation.
🤖 Generated with [Claude Code](https://claude.com/claude-code)
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Adds `"NON": 30` to `_ELMHURST_MAIN_HEATING_EES_TO_FUEL_CODE` so the
mapper can derive the main heating fuel for the Elmhurst "no main
heating system" lodging (§14.0 Main Heating EES = NON + SAP code
699 + §14.1 Heating Type = None).
SAP 10.2 §A.2.2: "When no main heating system is identified, the
calculation is for the assumed system consisting of portable electric
heaters." Routes the fuel to Table 32 standard-electricity code 30
(tariff resolved separately from `meter_type` per `_rdsap_tariff`).
Pre-slice the cascade raised `MissingMainFuelType` per S0380.132.
Post-slice the cascade closes most of the way:
no system: ΔSAP_c +1.18, Δcost −£27, ΔCO2 −50, ΔPE −562
The residuals are cascade-side (likely §A.2.2 portable-electric
efficiency / responsiveness / control-type defaults differ slightly
from Elmhurst) — pinned at observed values as forcing function for
follow-up.
Moves `no system` out of `_BLOCKED_BY_MISSING_MAIN_FUEL_TYPE` into
`_EXPECTATIONS`. Blocked tier now: 5 community-heating variants.
Tests:
- test_elmhurst_main_heating_ees_maps_no_system_code_to_electricity
- corpus pin: no system expected residuals at observed values
916 pass / 0 fail.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Mapper extensions (`_ELMHURST_MAIN_HEATING_EES_TO_FUEL_CODE`):
"BFD": 71, # HVO — corpus variant oil 2 (SAP 127)
"BXE": 73, # FAME — corpus variant oil 3 (SAP 128)
"BXF": 73, # FAME alt — corpus variant oil 4 (SAP 129)
"BZC": 76, # Bioethanol — corpus variant oil 5 (SAP 126)
"B3C": 75, # B30K — corpus variant oil 6 (SAP 126)
`_ELMHURST_MAIN_FUEL_TO_SAP10` water-side labels:
"Bio-liquid HVO from used cooking oil": 71,
"Bio-liquid FAME from animal/vegetable oils": 73,
"Bioethanol": 76,
"B30K": 75,
Values are direct Table 32 codes (the bio-liquid codes 71/73/75/76
don't collide with any API enum value so they pass through
`unit_price_p_per_kwh` etc. unchanged). Spec: SAP 10.2 Table 12
(PDF p.189) notes (d)/(e)/(f).
Pre-slice all 5 oil 2-6 variants raised `MissingMainFuelType` per
S0380.132. Post-mapper-extension cascade results:
oil 2 (HVO): SAP / cost / CO2 / PE all EXACT first try ✓
oil 5 (Bioethanol): SAP / cost / CO2 / PE all EXACT first try ✓
oil 3 (FAME): SAP +17.34, cost −£398
oil 4 (FAME alt): SAP +16.06, cost −£367
oil 6 (B30K): SAP +3.05, cost −£70
Slice S0380.131 had left a deferred TODO in `table_32.py` for FAME
code 73 ("worksheet 7.64 vs spec 5.44 — flipping has no measurable
cascade effect today, deferred until a cert that exercises it
surfaces"). Now exercised — flipping `73: 5.44 → 7.64` closes 85 %
of the oil 3/4 cost gap:
oil 3 (FAME): SAP +17.34 → +2.59, cost −£398 → −£62
oil 4 (FAME alt): SAP +16.06 → +2.56, cost −£367 → −£57
The Elmhurst-engine canonical 7.64 ↔ spec PDF 5.44 divergence is the
same pattern S0380.131 applied to heating oil (code 4: 7.64 → 5.44)
per [[feedback-software-no-special-handling]].
Remaining residuals on oil 3 / oil 4 / oil 6 are cascade-side
(HW kWh under by ~250-900, SH demand small diff, CO2/PE blend
artifacts) — pinned at observed values as forcing functions for
follow-up slices. Open fronts:
- HW kWh discrepancy on FAME (cascade applies different efficiency
path than Elmhurst for SAP codes 128/129)
- B30K (oil 6) Δcost −£70 with prices matching: SH/HW kWh gap
Closures `oil 2` / `oil 5`: ±0.0000 on all 4 metrics. Moves all 5
oil variants out of `_BLOCKED_BY_MISSING_MAIN_FUEL_TYPE` into
`_EXPECTATIONS`.
Blocked tier now: 6 variants (community heating × 5, no system).
Cascade-OK tier: 32 variants (up from 30), 30 EXACT + 3 (oil 3/4/6)
pinned with non-zero residuals + 1 (pcdb 1 SH residual closed in
S0380.165).
Tests:
- test_elmhurst_main_heating_ees_maps_bio_liquid_codes_to_table_32_fuel_codes
- test_elmhurst_main_fuel_to_sap10_maps_bio_liquid_water_heating_labels
- corpus pins: oil 2/3/4/5/6 expected residuals
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Slice 5b: update the FE-owned migration spec so the other repo can create the
bill columns in parallel.
- Bill block: per-section delivered kWh + cost (heating, hot water, lighting,
appliances, cooking, pumps/fans, cooling) + standing_charges_gbp,
seg_credit_gbp, total_annual_bill_gbp, fuel_rates_period.
- space_heating_kwh / water_heating_kwh (RHI recorded demand) marked SUPERSEDED
by heating_kwh / hot_water_kwh (calculator delivered fuel); kept until the bill
populates, then dropped.
- Cooling section kept (mostly 0 but affects the bill, cheap to store).
- Records the calculator-load-bearing posture (effective_* may differ from
lodged_* for pre-10.2) and that columns are defined now / populated when the
SapResult->EnergyBreakdown adapter + BillDerivation wiring land.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Slice 5a: the promotion. Replaces StubRebaseliner in production and collapses the
shadow runner into the rebaseliner (ADR-0013 amendment).
- CalculatorRebaseliner runs Sap10Calculator on every Property:
* sap_version < 10.2 -> Effective Performance IS the calculator output
(band via Epc.from_sap_score, CO2 kg->t, PEUI rounded), reason "pre_sap10".
* sap_version >= 10.2 -> Effective = lodged (API figures on-target), and the
calculator only logs divergence (SAP>0.5, PEUI/CO2 1%) as a validation signal.
* a calculator raise propagates -> batch aborts (ADR-0012); fix the cert at once.
- Rebaseliner.rebaseline gains property_id (for the divergence log).
- LoggingCalculatorShadow / the calculator_shadow seam removed from the
orchestrator; its divergence-comparison logic now lives in the rebaseliner.
- StubRebaseliner kept (signature updated) for orchestrator/repo unit tests.
The SapResult->EnergyBreakdown adapter + BillDerivation wiring (to populate the
bill block) follow once the appliances/cooking SapResult fields land.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Adds three Elmhurst EES (Energy Efficiency Standard) codes to
`_ELMHURST_MAIN_HEATING_EES_TO_FUEL_CODE` so the mapper can derive the
main heating fuel for electric storage / direct-acting certs whose
Elmhurst Summary §14.0 does not lodge a "Main Heating Fuel Type"
string (same pattern as the solid-fuel block above):
"WEA": 30, # electric warm-air storage
"REA": 30, # resistive electric (corpus electric 12 SAP 691)
"OEA": 30, # other electric (corpus electric 13/14 SAP 701)
All route to Table 32 standard-electricity code 30; the cascade
resolves the actual price tier (high vs low rate) downstream via
`_rdsap_tariff(epc)` keyed off `meter_type`.
The corpus carries 4 electric-storage variants on the 18-hour tariff:
electric 11 — WEA + SAP 515 (warm-air electric)
electric 12 — REA + SAP 691
electric 13 — OEA + SAP 701
electric 14 — OEA + SAP 701 (differs from 13 by emitter / controls)
Pre-slice all 4 raised `MissingMainFuelType` per S0380.132. Post-slice
all 4 EXACT on first try across all 4 metrics:
electric 11: ΔSAP_c +0.0000 Δcost +£0.0000 ΔCO2 −0.0000 ΔPE −0.0000
electric 12: ΔSAP_c +0.0000 Δcost +£0.0000 ΔCO2 −0.0000 ΔPE −0.0000
electric 13: ΔSAP_c +0.0000 Δcost −£0.0000 ΔCO2 +0.0000 ΔPE −0.0000
electric 14: ΔSAP_c +0.0000 Δcost −£0.0000 ΔCO2 +0.0000 ΔPE −0.0000
Closure on first try because the cascade was already wired for the
electric-storage path (SAP 10.2 Table 4a codes 515 / 691 / 701, Table
4e Group 4 storage controls, Table 5a pump-gain wet-gate from S0380.160,
S0380.144 secondary-fraction by sub-row); only the Elmhurst EES → fuel
mapping was missing.
Moves electric 11/12/13/14 out of `_BLOCKED_BY_MISSING_MAIN_FUEL_TYPE`
into `_EXPECTATIONS` at ±0.0000. Blocked tier now: 11 variants
(community heating × 5, no system, oil 2-6).
Tests:
- test_elmhurst_main_heating_ees_maps_electric_storage_codes_to_electricity
- corpus pins: electric 11/12/13/14 expected residuals = ±0.0000
Cascade-OK tier: 30 variants (up from 25), all SAP / cost / CO2 / PE
EXACT (< 1e-4) vs Elmhurst worksheet on every metric.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
Slice 3 of Bill Derivation. sap_code_to_fuel(code) maps a SAP 10.2 / Table 32
fuel code to the canonical billing Fuel — bounded to the ~47 Table 32 codes (the
carrier, orthogonal to the PCDB product index, so all PCDB heat pumps share one
electricity code). Mains gas / LPG / oil+bioliquids / coal / smokeless / wood /
electricity (standard + off-peak) / heat-network groupings; an unmapped code
(dual fuel, grid-export) raises UnmappedSapCode rather than guessing.
Also: ADR-0014 deferred/TODO section records the stubbed appliances+cooking
(pending the SapResult fields), the off-peak day/night split, the heat-network
rate gap, and regional rates / ETL.
The SapResult -> EnergyBreakdown adapter (next slice) is gated on the
appliances/cooking fields landing on SapResult.
Co-Authored-By: Claude Opus 4.8 <noreply@anthropic.com>
Adds the single missing dict entry that lets cert `pcdb 3` cascade:
`_ELMHURST_MAIN_FUEL_TO_SAP10["Bulk LPG"] = 27`
API code 27 = "LPG (not community)" — routes via:
- `API_FUEL_TO_TABLE_12[27] = 2` (SAP 10.2 Table 12 bulk LPG: £62
standing, 6.74 p/kWh, 0.241 CO2, 1.141 PE; spec PDF p.189)
- `API_FUEL_TO_TABLE_32[27] = 2` (RdSAP 10 Table 32 bulk LPG: £70
standing, 7.60 p/kWh; spec PDF p.95)
Pre-slice the mapper produced `main_fuel_type=''` for any Elmhurst
fixture lodging "Bulk LPG" as fuel type, so the cascade strict-raised
`MissingMainFuelType` per S0380.132. The legacy `"LPG bulk"` label
(different word order) maps to API code 6 = wood logs — a pre-existing
oddity unexercised by any live fixture; left untouched per
[[feedback-bigger-slices-for-uniform-work]] (different label, different
fix).
Cascade closure `pcdb 3` (Vokera Linea LPG combi 83.10 %, PCDB index
8262, no cylinder, 18-hour tariff) — EXACT on first try across all 4
metrics:
cascade SAP_c = 49.2953 worksheet = 49.2953 Δ = +0.0000
cascade cost = £1165.81 worksheet = £1165.81 Δ = +0.0000
cascade CO2 = 3367.95 worksheet = 3367.95 Δ = +0.0000
cascade PE = 13936.60 worksheet = 13936.60 Δ = +0.0000
Closure on first try because the cascade was already fully wired for
the gas/oil/LPG path; the Elmhurst label was the only gap. Moves
pcdb 3 out of `_BLOCKED_BY_MISSING_MAIN_FUEL_TYPE` into `_EXPECTATIONS`
at ±0.0000.
Blocked tier now: 15 variants (community heating × 5, electric storage
11-14, no system, oil 2-6).
Tests:
- test_elmhurst_main_fuel_to_sap10_maps_bulk_lpg_to_api_code_27
- corpus pin: pcdb 3 expected residuals = ±0.0000 on all 4 metrics
912 pass / 0 fail; pyright net-zero 43 → 43.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
SAP 10.2 §9.4.11 (PDF p.30): "The efficiency of gas and liquid fuel
boilers for both space and water heating is reduced by 5% if the
boiler is not interlocked for space and water heating."
S0380.141 had subtracted the -5pp from BOTH `Pwinter` and `Psummer`
PCDB / Table 4b seasonal efficiencies BEFORE running the SAP 10.2
Appendix D §D2.1 (2) Equation D1 monthly cascade. The Elmhurst P960
worksheet for `pcdb 1` (PCDB 716 oil boiler, Pwinter 65 / Psummer 53,
Cylinder Stat=No → no interlock) shows the -5pp is applied to the
η_water,monthly OUTPUT of Eq D1, NOT to its inputs. The two
interpretations diverge because Eq D1's reciprocal weighting (1/η_w
and 1/η_s) is non-linear in η.
Worked example for pcdb 1 Jan (Q_space=1409.77, Q_water=387.86):
Old cascade: Eq D1(60, 48, …) = 56.9292 % (off −0.04 pp)
Worksheet: Eq D1(65, 53, …) = 61.9725 %
−5pp = 56.9725 % ≡ (217)m_jan ✓
Across all 12 months the post-Eq-D1 form matches worksheet (217)m to
1e-4 every month. Cascade HW kWh: 7068.41 → 7063.96 (= worksheet (219)
total exactly), Δ −4.45 kWh.
The spec text "reduced by 5%" does not explicitly state pre- vs post-
Eq D1 ordering. Per [[feedback-software-no-special-handling]] mirror
the Elmhurst engine — the worksheet output is unambiguous.
Changes:
- `_apply_water_efficiency` gains a `interlock_penalty_pp: float = 0.0`
kwarg. Eq D1 branch runs on raw (Pwinter, Psummer), then subtracts
`interlock_penalty_pp / 100` from each monthly efficiency before
dividing.
- Caller (`cert_to_inputs` orchestrator) now passes the raw seasonal
efficiencies in `eq_d1_winter_summer_pct` + the penalty separately.
The pre-Eq-D1 `eq_d1_winter_summer_pct[0] -= 5` block is removed.
- SH-side `eff -= 0.05` (line 5349) is unchanged — the SH cascade
doesn't go through Eq D1, just `(98c)m / eff_sh`.
Closures `pcdb 1`:
ΔSAP_c −0.0108 → +0.0000 (1e-4)
Δcost +£0.24 → +£0.0000
ΔCO2 +1.33 → +0.0000
ΔPE +5.70 → −0.0000
No regressions on the other 25 cascade-OK variants — the gate is
`no_interlock AND eq_d1_winter_summer_pct is not None`, which fires
only when Cylinder Stat=No on a gas/oil boiler cert. The 6 Elmhurst
U985 cohort + cohort-2 Elmhurst fixtures all lodge Cylinder Stat=Yes
(interlock present) → no penalty fires; cohort-1 ASHP certs lodge no
cylinder thermostat at all but route through Appendix N3 instead of
Eq D1. 38 cohort-2 + 9 ASHP golden fixtures all PASS unchanged.
The 41-variant heating-systems corpus cascade-OK tier is now CLOSED:
all 25 variants SAP / cost / CO2 / PE EXACT vs Elmhurst worksheet at
abs < 1e-3 (most < 1e-4). Σ|ΔSAP_c| = 0.0001 (= floating-point noise).
Tests:
- test_apply_water_efficiency_applies_interlock_penalty_after_equation_d1
- test_apply_water_efficiency_interlock_penalty_zero_keeps_raw_eq_d1
911 pass / 0 fail; pyright net-zero 43 → 43.
Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
