Why does NEC use the 1.56 factor while AS/NZS and IEC use 1.25?

The NEC 1.56 factor is the product of two separate 1.25 multipliers. The first 1.25 is the continuous load factor (NEC 210.20(A) requires conductors for continuous loads to be rated at 125% of the continuous current). The second 1.25 is the irradiance correction factor accounting for conditions where solar irradiance exceeds the STC reference of 1,000 W/m² — during clear-sky conditions with cloud-edge enhancement, irradiance can momentarily reach 1,200-1,400 W/m². AS/NZS 5033 and IEC 62548 incorporate the irradiance correction differently: they allow the 1.25 factor to be reduced if site-specific irradiance data shows lower peaks, or they account for it through the temperature derating of the cable rather than a blanket multiplier on the current. The practical result is that NEC requires 25% more copper on the DC side than the other standards for the same installation.

Can I use a smaller AC cable if I reduce the inverter's export power?

Yes. Many modern inverters support configurable export limiting (also called "zero export" or "partial export"). If the inverter is configured to limit AC output to, say, 5 kW (21.7 A) instead of the full 10 kW, the voltage rise is halved, and a smaller cable (10 mm² under AS/NZS) would satisfy the 2% limit. However, export limiting means the system cannot deliver its full capacity to the grid during peak production, which reduces annual energy yield and revenue. The economic trade-off between larger cable (capital cost) and export limiting (opportunity cost of lost generation) depends on the feed-in tariff and system size. In Australia, where feed-in tariffs have dropped below $0.05/kWh in many states, export limiting is often the more cost-effective choice.

What happens if the grid voltage is already high before the inverter starts exporting?

This is the core problem in Australian rural areas. If the grid voltage at the point of supply is already 248 V (within the statutory range of 216-253 V per AS 60038), then the inverter can only add 253 - 248 = 5 V before reaching the anti-islanding trip point. At 43.5 A export current, a 5 V rise corresponds to an effective cable impedance of 5 / (2 × 43.5) = 0.0575 ohm — which for a 30 m run means maximum r = 1.92 mΩ/m, still requiring 16 mm². But if the grid voltage is already at 250 V, the margin shrinks to 3 V, and even 25 mm² cable may not be enough. In these cases, the solution is reactive power compensation (operating the inverter at leading power factor to absorb VAR and reduce voltage) or dynamic export limiting based on real-time grid voltage measurement.

Worked Example: Solar PV String Cable — 10 kW Roo…

Scenario

Parameter	Value
System capacity	10 kWp (DC STC rating)
PV module	400 Wp bifacial mono-PERC, half-cut
Module V_oc (STC)	37.2 V
Module I_sc (STC)	13.96 A
Module V_mpp (STC)	31.4 V
Module I_mpp (STC)	12.74 A
Temp coefficient V_oc	−0.25%/°C
Temp coefficient I_sc	+0.044%/°C
Inverter	10 kW single-phase, MPPT range 150–550 V DC, max 600 V DC
Inverter AC output	230 V single-phase, 50 Hz, max 43.5 A
Site min ambient temperature	−2°C (Melbourne, AU) / 0°C (Birmingham, UK)
Site max cell temperature	75°C (black roof, summer)
DC cable route (string to inverter)	25 m average one-way
AC cable route (inverter to MSB)	30 m
Roof type	Colorbond metal roof, residential
Standards	AS/NZS 5033 + 4777.1, IEC 62548 + 60364-7-712, NEC 690 (NFPA 70:2023)

This example reveals a surprising asymmetry: on the DC side, the concern is voltage RISE at low temperature (which can destroy the inverter), while on the AC side, the concern is voltage RISE at the point of supply connection (which can push the grid voltage above statutory limits). Different standards set different limits and measure in different directions.

Step 1: Determine String Configuration

Maximum string length (cold temperature limit):

At minimum ambient temperature, module V_oc increases. The temperature correction must use ambient temperature minus a small offset because V_oc is measured at cell temperature, but at minimum temperature and no irradiance, cell temperature approximately equals ambient temperature.

For AS/NZS 5033 (Melbourne, -2 deg C)

ΔT = T_min − T_STC = −2 − 25 = −27°C

V_oc,max = V_oc,STC × (1 + (ΔT × TK_Voc / 100)) — (Eq. 1)

V_oc,max = 37.2 × (1 + (−27 × −0.25 / 100))

V_oc,max = 37.2 × (1 + 0.0675)

V_oc,max = 39.71 V per module

Maximum modules per string (AS/NZS 5033, Cl. 4.3.3.3, max system voltage 600 V for residential):

N_max = floor(600 / 39.71) = 15 modules — (Eq. 2)

For NEC 690.7 (using 0 deg C)

ΔT = 0 − 25 = −25°C

V_oc,max = 37.2 × (1 + (−25 × −0.25 / 100))

V_oc,max = 37.2 × 1.0625

V_oc,max = 39.53 V per module

NEC 690.7(A) maximum system voltage for residential = 600 V:

N_max = floor(600 / 39.53) = 15 modules

Minimum String Length (Hot Temperature Limit)

At maximum cell temperature, V_mpp drops. The string must stay above the inverter’s MPPT minimum.

ΔT = T_cell,max − T_STC = 75 − 25 = +50°C

V_mpp,min = V_mpp,STC × (1 + (ΔT × TK_Voc / 100)) — (Eq. 3)

V_mpp,min = 31.4 × (1 + (50 × −0.25 / 100))

V_mpp,min = 31.4 × 0.875

V_mpp,min = 27.48 V per module

Minimum modules per string (MPPT minimum = 150 V):

N_min = ceil(150 / 27.48) = 6 modules — (Eq. 4)

Selected Configuration

With 400 Wp modules and 10 kWp target: 10,000 / 400 = 25 modules total.

Select 2 strings of 13 modules (total 26 modules = 10.4 kWp).

Voltage checks:

Check	Value	Limit	Status
V_oc,max (cold)	13 × 39.71 = 516.2 V	600 V	PASS
V_mpp,min (hot)	13 × 27.48 = 357.2 V	150 V MPPT min	PASS
V_mpp,STC	13 × 31.4 = 408.2 V	150–550 V MPPT	PASS

Step 2: Size DC String Cable — Current Capacity

AS/NZS 5033:2021 (Clause 3.3.4):

AS/NZS 5033 requires cable ampacity to be at least 1.25 × I_sc for the string:

I_cable,min = 1.25 × I_sc = 1.25 × 13.96 = 17.45 A — (Eq. 5a)

Temperature derating for cable on roof surface (AS/NZS 5033 Table 3.2, cable in contact with roof, 75°C ambient, 90°C rated cable):

C_temp = 0.58

Required tabulated ampacity:

I_z = 17.45 / 0.58 = 30.1 A — (Eq. 6a)

From AS/NZS 5033 Table 3.3 (solar DC cable, 90°C, copper, single-core on roof):

Cable Size	Rating (A)	Result
4 mm²	32 A	PASS (32 ≥ 30.1)
6 mm²	43 A	PASS with margin

Selected: 4 mm² DC solar cable (TUV-certified, double-insulated, per AS/NZS 5033 Cl. 3.3.3).

NEC 690.8(A) and 690.9(B)

NEC requires the maximum circuit current to include both the continuous load factor (1.25) and the irradiance correction (1.25):

I_cable,min = I_sc × 1.25 × 1.25 = I_sc × 1.56 = 13.96 × 1.56 = 21.78 A — (Eq. 5b)

Temperature correction from NEC Table 310.15(B)(1), 75°C ambient, 90°C cable:

C_temp = 0.58

Required ampacity:

I_z = 21.78 / 0.58 = 37.6 A — (Eq. 6b)

From NEC Table 310.16, 90°C column:

AWG	Rating (A)	Result
10 AWG (5.26 mm²)	30 A	FAIL (30 < 37.6)
8 AWG (8.37 mm²)	40 A	PASS (40 ≥ 37.6)

Selected: 8 AWG (8.37 mm²) USE-2/PV wire.

IEC 62548:2016 (Clause 7.3)

IEC 62548 requires cable ampacity to be at least 1.25 × I_sc (similar to AS/NZS):

I_cable,min = 1.25 × 13.96 = 17.45 A — (Eq. 5c)

With same derating:

I_z = 17.45 / 0.58 = 30.1 A — (Eq. 6c)

Selected: 4 mm² DC solar cable (same as AS/NZS).

First key difference: NEC requires 8 AWG (8.37 mm²) while AS/NZS and IEC allow 4 mm². The NEC 1.56 factor (vs 1.25 for AS/NZS and IEC) drives a cable that is more than double the cross-section. This is the 1.25 × 1.25 = 1.56 “double 80% rule” unique to NEC.

Step 3: DC Voltage Drop (or Rise?)

In a PV system, current flows FROM the array TO the inverter. Voltage is highest at the array and drops toward the inverter. This is technically a voltage DROP from source to load. However, the key performance metric is energy harvest: every volt lost in the cable reduces the power delivered to the inverter.

ΔV_DC = 2 × I_mpp × R × L / 1000 — (Eq. 7)

Where the factor of 2 accounts for positive and negative conductors, and R is resistance per km at operating temperature.

4 mm², 25 m, 12.74 A (AS/NZS and IEC):

Resistance of 4 mm² copper at 70°C: 5.36 Ω/km (from AS/NZS 5033, Table 3.4):

ΔV_DC = 2 × 12.74 × 5.36 × 25 / 1000 = 3.41 V

ΔV_DC% = 3.41 / 408.2 × 100 = 0.84%

8 AWG (8.37 mm²), 25 m, 12.74 A (NEC):

Resistance of 8 AWG at 70°C: 2.551 Ω/km:

ΔV_DC = 2 × 12.74 × 2.551 × 25 / 1000 = 1.63 V

ΔV_DC% = 1.63 / 408.2 × 100 = 0.40%

Standard	Cable	VD (V)	VD (%)	Limit	Status
AS/NZS 5033 Cl. 3.3.7	4 mm²	3.41	0.84%	3% (recommended)	PASS
IEC 62548 Cl. 7.4	4 mm²	3.41	0.84%	1% (recommended)	PASS
NEC 690.8 (Informational)	8 AWG	1.63	0.40%	3% (recommended)	PASS

Step 4: AC Output Cable — Where Voltage RISE Matters

The inverter feeds power back to the grid through the main switchboard. On the AC side, the direction of power flow reverses the voltage gradient: the inverter terminal voltage is HIGHER than the grid voltage at the MSB during export. This creates a voltage rise at the inverter terminals relative to the point of supply.

Calculate AC output current:

I_AC = P_inverter / (V × PF) = 10,000 / (230 × 1.0) = 43.5 A — (Eq. 8)

(Grid-tied inverters operate at unity power factor by default.)

AS/NZS 4777.1:2016 — Voltage Rise Limit

AS/NZS 4777.1, Clause 3.3.4 specifies that the voltage rise from the inverter to the point of supply connection must not exceed 2% of nominal voltage (230 V). This is a stringent limit designed to prevent the supply voltage from exceeding the +10% statutory maximum of 253 V.

For a 30 m AC cable run at 43.5 A (single-phase), the cable must limit voltage rise to:

ΔV_max = 0.02 × 230 = 4.60 V — (Eq. 9)

Required maximum cable impedance:

Z_max = ΔV_max / (2 × I_AC) = 4.60 / (2 × 43.5) = 0.0529 Ω — (Eq. 10)

Required maximum resistance per metre:

r_max = Z_max / L = 0.0529 / 30 = 1.763 mΩ/m

From AS/NZS 3008 Table 35, the cable size where r ≤ 1.763 mΩ/m:

Cable Size	r (mΩ/m) at 75°C	Result
6 mm²	3.65	FAIL (3.65 > 1.763)
10 mm²	2.19	FAIL (2.19 > 1.763)
16 mm²	1.37	PASS (1.37 < 1.763)

Selected: 16 mm² (voltage rise governs).

But check current capacity: the 50 A MCB protecting this circuit requires the cable to carry at least 50 A after derating. For 16 mm² TPS on tray at 35°C ambient:

From AS/NZS 3008 Table 13, 16 mm² on tray: 76 A. Derating for 35°C ambient: k₁ = 1.04 (below 40°C reference). Derated capacity: 76 × 1.04 = 79 A. Exceeds 50 A. PASS.

BS 7671 / IEC 60364-7-712 — Voltage Rise Limit

BS 7671 and IEC 60364-7-712 do not specify a dedicated voltage rise limit for PV inverters. Instead, the general voltage drop limit of 3–5% applies, interpreted as voltage rise for generation sources. The Engineering Recommendation G98 (UK) limits voltage rise to 1% at the connection point for systems up to 16 A/phase, but for a 43.5 A inverter, the designer typically uses the 2% rise limit from G99.

With a 2% limit (same as AS/NZS): 16 mm² selected (same result).

With a relaxed 3% limit (if applying IEC general limit):

ΔV_max = 0.03 × 230 = 6.90 V

r_max = 6.90 / (2 × 43.5 × 30) = 2.644 mΩ/m

10 mm² cable (r = 2.19 mΩ/m) would pass: 10 mm² selected.

NEC 690.8 — Voltage Rise

NEC does not specify an explicit voltage rise limit for grid-connected inverters. NEC 210.19 and 215.2 provide informational notes suggesting 3% for branch circuits and 5% total. For PV AC output cables, the standard practice is to limit voltage rise to 2% per NEC 690 best practice (not a code requirement but an engineering recommendation from IEEE 1547).

With 2% limit: same calculation as above, 16 mm² equivalent = 6 AWG (13.3 mm²) selected.

However, NEC 690.8(A)(1)(2) requires the AC cable ampacity to be at least 1.25 × maximum inverter output current (continuous load rule):

I_cable = 1.25 × 43.5 = 54.4 A

From NEC Table 310.16, 90°C column:

Size	Rating	Derated (35°C)	Result
6 AWG	55 A	55 × 0.96 = 52.8 A	FAIL
4 AWG (21.2 mm²)	70 A	70 × 0.96 = 67.2 A	PASS

NEC selected: 4 AWG (21.2 mm²) for AC output cable.

Step 5: Voltage Rise vs Voltage Drop — The Asymmetry

Here is the critical insight that confuses many solar installers:

Direction	DC Side	AC Side
Current flow	Array → Inverter	Inverter → Grid
Voltage gradient	DROP from array to inverter	RISE from grid to inverter point
What matters	Energy loss (reduced harvest)	Grid voltage compliance (statutory limit)
Limit (AS/NZS)	3% recommended (5033 Cl. 3.3.7)	2% mandatory (4777.1 Cl. 3.3.4)
Limit (NEC)	3% recommended	2% best practice
Limit (IEC)	1% recommended	2–3% depending on local grid code
Consequence of exceeding	Reduced revenue	Inverter shutdown (anti-islanding)

The AC voltage rise limit is the more consequential constraint because exceeding it triggers the inverter’s anti-islanding protection. When the grid voltage at the inverter connection point rises above the statutory maximum (typically 253–264 V depending on jurisdiction), the inverter must disconnect within 1–2 seconds per AS/NZS 4777.2 Table 2 / IEEE 1547 Table 4. In areas with already-high grid voltage (common in rural Australia where long distribution feeders have rising voltage profiles), even a 2% rise can push the supply above 253 V, causing nuisance tripping and lost generation.

Result Summary

Parameter	AS/NZS 5033 / 4777.1	IEC 62548 / 60364	NEC 690
String configuration	2 × 13 modules	2 × 13 modules	2 × 13 modules
V_oc,max (cold)	516.2 V (limit: 600 V)	516.2 V (limit: 600 V)	516.2 V (limit: 600 V)
DC cable I_sc factor	1.25	1.25	1.56
DC string cable	4 mm²	4 mm²	8 AWG (8.37 mm²)
DC voltage drop	0.84%	0.84%	0.40%
AC cable (voltage rise)	16 mm²	10–16 mm²	4 AWG (21.2 mm²)
AC voltage rise limit	2% mandatory	2–3% (grid code)	2% best practice
AC voltage rise	1.80%	1.80–2.70%	1.27%
Total copper (DC+AC)	4+16 mm²	4+10 mm²	8.37+21.2 mm²

Multi-Standard Comparison

Aspect	AS/NZS	IEC	NEC
DC current factor	1.25×	1.25×	1.56×
DC cable result	4 mm²	4 mm²	8 AWG (2.1× larger)
AC voltage rise limit	2% (strict, mandatory)	2–3% (variable)	2% (recommended)
AC cable result	16 mm²	10–16 mm²	21.2 mm²
AC governing factor	Voltage rise	Voltage rise / current	Current (1.25× continuous)
Anti-islanding trip voltage	253 V (+10%)	253 V (+10%)	264 V (+15% in some cases)
Unique requirement	4777.1 export limit	Grid code injection limit	690.11 AFCI mandatory

Key Insight

The key finding in solar PV cable sizing is that voltage rise on the AC side, not voltage drop on the DC side, is the governing constraint for most residential installations — and the standards disagree on how strict this limit should be.

Under AS/NZS 4777.1, the 2% mandatory voltage rise limit on the AC side forces a 16 mm² cable for a mere 30 m run, even though the 43.5 A current could be carried by 6 mm² on thermal grounds alone. The cable is nearly three times the size that current capacity alone would require.

Meanwhile, on the DC side, the NEC 1.56 factor forces 8 AWG (8.37 mm²) where AS/NZS and IEC allow 4 mm² — more than double the copper. But the irony is that the NEC’s larger DC cable has lower voltage drop (0.40% vs 0.84%), which means marginally more energy harvested over the system’s 25-year life. Whether this extra copper pays for itself through increased energy yield depends on the local electricity price and solar irradiance — in most cases, the payback on the extra DC copper under NEC is approximately 8–12 years.

The deepest surprise is directional: solar engineers trained on load circuits think “voltage drop” but must think “voltage rise” on the AC side. A cable that is perfectly adequate for carrying current can cause the inverter to trip repeatedly if the resulting voltage rise pushes the grid connection above statutory limits. This is not a theoretical problem — it is the single most common cause of solar inverter nuisance tripping in Australian residential installations, particularly in rural areas with already-elevated grid voltage.

Worked Example: Solar PV String Cable — 10 kW Rooftop Inverter