What Is the Voltage Drop for 2 AWG at 16A and 125 Feet?

2 AWG copper carrying 16 amps over 125 feet on a single-phase / DC circuit drops 0.776 volts (0.6467% on a 120V source). This sits within the 3% branch target and the 5% feeder+branch total target that NEC 210.19(A) Informational Note 4 cites. Both are planning targets, not code requirements.

2 AWG, 16A, 125ft · single-phase / DC
0.776 V drop (0.6467% on 120V)
On 120V circuit0.6467%
On 240V circuit0.3233%

Circuit basis: This uses the single-phase / DC round-trip formula (factor of 2) for the voltage drop across the two circuit conductors. For a three-phase line-to-line run use the three-phase version of the page (append ?type=3ph). Switch to the three-phase version →

2 AWG
0.78V (0.65%)

Assumes a 120V source on a single-phase / DC circuit. Use the circuit-basis link above to switch between single-phase/DC and three-phase.

Voltage Drop Formula (single-phase / DC)

Vdrop = (2 × L × I × R) ÷ 1000

(2 × 125 × 16 × 0.194) ÷ 1000 = 0.776 V

DC and single-phase AC use the round-trip factor of 2. Current travels out to the load on one conductor and returns on another.

For a three-phase circuit at the same amps and distance, see the three-phase version (uses √3 instead of 2, so the drop is about 13.4% lower).

Percentage

%VD = (Vdrop ÷ Vsource) × 100

On 120V: (0.776 ÷ 120) × 100 = 0.6467%
On 240V: (0.776 ÷ 240) × 100 = 0.3233%

How This Estimate Changes with Run Length and Gauge

Gauge Check

2 AWG clears the 3% drop target at these inputs. A smaller conductor may also meet it with less margin. See the minimum gauge for this load and distance.

Impact of Distance

Voltage drop is proportional to distance. Here is 2 AWG at 16A at different distances:

DistanceDrop (V)% on 120V% on 240VNEC (120V)
25ft0.1552V0.1293%0.0647%OK
50ft0.3104V0.2587%0.1293%OK
75ft0.4656V0.388%0.194%OK
100ft0.6208V0.5173%0.2587%OK
150ft0.9312V0.776%0.388%OK
200ft1.24V1.03%0.5173%OK
300ft1.86V1.55%0.776%OK

Same Run, Different Wire Gauges

How does wire gauge affect voltage drop for 16A at 125 feet on 120V single-phase / DC? Only gauges whose branch-circuit OCP cap is at or above the 16A load are listed, since thinner gauges would fail the ampacity check before drop even matters.

GaugeDrop (V)% on 120V% on 240V3% Target (120V)
2 AWG0.776V0.6467%0.3233%OK
1 AWG0.616V0.5133%0.2567%OK
1/0 AWG0.488V0.4067%0.2033%OK
2/0 AWG0.3868V0.3223%0.1612%OK
3/0 AWG0.3064V0.2553%0.1277%OK
4/0 AWG0.2432V0.2027%0.1013%OK

Related Calculations

cable Wire size: 16A, 125ft bolt Watts to amps calculator functions Voltage drop formula

Frequently Asked Questions

2 AWG carrying 16A over 125ft has a 0.776V drop (0.6467% on 120V). Reference: 0.3233% on 240V.
Motors run hotter and can have trouble starting under load. Incandescent and halogen lighting dims. Some electronics misbehave at the low end of their input tolerance. Energy is wasted as I²R heating in the conductor. These are performance issues; high drop is not itself a code violation unless the specific installation cites a hard limit.
On 120V, this run sits at 0.6467%, which is within the 3% branch and 5% feeder+branch total drop targets. NEC 210.19(A) Informational Note 4 cites 3% for branch circuits and 5% for total feeder+branch drop as performance recommendations, not hard code requirements.
2 AWG already sits within the 3% branch-circuit drop target at these inputs (0.6467% on 120V). Going to a larger gauge is only useful if you want more headroom for future load growth, longer runs, or tighter drop targets like the 5% feeder+branch total recommendation used in sensitive or motor-heavy installations.
Same wire, same amps, same distance: the volts dropped are identical. But the percentage is worse on 120V because the drop is a larger fraction of the source voltage. This run would be 0.3233% on 240V versus 0.6467% on 120V.
This calculator provides estimates for reference purposes only. Always consult a licensed electrician and verify compliance with the National Electrical Code (NEC) and local electrical codes before performing any electrical work.
person Written by Sean Day verified Reviewed by WireResult update Last updated Apr 11, 2026