Cable Inductance Calculator

Inputs

Cable configuration

Choose the geometry closest to your installation.

Frequency (Hz)

Used to compute inductive reactance.

Relative permeability (μr)

1 for air/typical insulation.

Cable length

Total route length along the run.

Dimension unit

Applies to diameters, radii, and spacing.

Frequency mode

Switching/fast edges may behave closer to high frequency.

Parallel two‑conductor inputs

Loop & per‑conductor

Conductor diameter

Round conductor equivalent diameter.

Center spacing (D)

Center-to-center distance between conductors.

Use this for single‑phase runs, control pairs, and DC loops. Smaller spacing typically reduces loop inductance.

Coaxial inputs

a & b radii

Inner radius (a)

Radius of inner conductor.

Outer inner radius (b)

Inner radius of the outer shield.

Coax confines fields inside the shield, lowering interference and making inductance predictable.

Three‑phase inputs

per‑phase inductance

Conductor diameter

Spacing model

Use unequal spacing for tray/trefoil variations.

Phase spacing (D)

Distance Dab

Distance Dbc

Distance Dca

Per‑phase inductance is estimated using the geometric mean distance (D_m) and an effective conductor radius (D_s).

Reset

Example data table

Scenario	Geometry	Key inputs	Frequency	Typical output
Temporary single‑phase run	Parallel	Ø 12 mm, D 100 mm, length 50 m	50 Hz	Inductance in the low mH range
Shielded control signal	Coax	a 2 mm, b 6 mm, length 30 m	1 kHz	Stable µH/m behavior
Motor feeder in tray	Three‑phase	Ø 12 mm, spacing 150 mm, length 80 m	50 Hz	Reactance grows with run length

Formula used

This calculator estimates inductance from conductor geometry using common field approximations.

Parallel two‑conductor (per loop): L′_loop = (μ/π) ln(D / r_eff). Per conductor is L′_loop/2.
Coaxial cable: L′ = (μ/2π) ln(b/a), where a is inner radius and b is shield inner radius.
Three‑phase (per phase): L′ = (μ/2π) ln(D_m/D_s), with D_m = (Dab·Dbc·Dca)^1/3.
Reactance: X_L = 2π f L, using total inductance L.

Power‑frequency mode uses D_s ≈ 0.7788·r to include internal inductance for solid conductors. High‑frequency mode uses r and assumes current crowds near the surface.

How to use this calculator

Select the cable configuration that matches your run.
Enter frequency and total route length.
Choose a frequency mode that fits your application.
Fill in the geometry inputs in your preferred units.
Press Calculate to view results above the form.
Use CSV or PDF exports for checklists and submittals.

Accurate inductance estimates help safer, quieter electrical installations everywhere.

Cable Inductance in Construction

Why inductance matters

Site feeders, temporary boards, hoists, and cranes all depend on cables carrying changing current. Inductance resists those changes, adding reactive impedance that influences voltage drop and equipment starting. Estimating inductance supports safer sizing, commissioning checks, and troubleshooting.

Common site layouts

Inductance is driven by conductor spacing and geometry. Widely separated conductors on trays typically have higher inductance than bundled multicore cable. Trefoil single-core routing often lowers inductance and reduces external magnetic fields. Flat three-phase spacing can raise inductance and increase interference near controls.

What this calculator estimates

This tool provides practical estimates for typical geometries: two-wire circuits, coax-like arrangements, and three-phase sets in trefoil or flat formation. It uses conductor radius, spacing, run length, and relative permeability to compute inductance per meter and total inductance.

Inputs you should measure

Enter conductor radius (or diameter/2), center-to-center spacing, and installed length. If the route includes significant ferromagnetic containment, inductance can rise; adjust the relative permeability only when you have reliable data. For three-phase, pick the installed arrangement to avoid misleading results.

Worked example

Consider a 50 m two-wire feeder with 5 mm radius conductors and 60 mm spacing in non-magnetic containment (μr = 1). Submit those values to obtain inductance per meter and total inductance. Multiply by angular frequency to estimate inductive reactance, then compare options such as reduced spacing or different routing.

Interpreting results

Higher total inductance means higher reactance at the same frequency, increasing reactive voltage drop and affecting motor or transformer energization on weak supplies. For variable-speed drives, inductance can moderate di/dt, but excessive inductance may worsen regulation and power factor.

Practical reduction tips

Keep outgoing and return conductors close together, use trefoil for single-core three-phase, avoid unnecessary separation on trays, and minimize loop area at joints and terminations. Where practical, select multicore cable and route phases together. Recheck values if the cable path changes during construction.

Example data snapshot

Case	Geometry	Length (m)	Radius (mm)	Spacing (mm)	μr
A	Two-wire	50	5	60	1.0
B	3-Phase Trefoil	80	6	70	1.0
C	3-Phase Flat	80	6	120	1.0

Documentation and reporting

Record the geometry, spacing, and calculated inductance in commissioning notes so later changes are traceable. If protective settings are sensitive, keep both the inductance and the derived reactance used in checks. When a circuit is rerouted or phases are split temporarily, recalculate and update the as-built file.

FAQs

1) Is this inductance value exact for every cable?

No. It’s an estimate based on geometry and assumptions. Manufacturer data, cable construction, and installation environment can shift results. Use it for planning and cross-checking, then validate against project specifications when available.

2) What spacing should I enter for multicore cable?

Internal spacing is not easy to measure. Prefer manufacturer inductance data. If you must estimate, use an equivalent center spacing based on the cable’s construction notes and treat the outcome as approximate.

3) Why does trefoil usually reduce inductance?

Trefoil keeps phase conductors close and symmetric, reducing loop area and balancing magnetic fields. That typically lowers inductance and external field strength compared with a wide flat arrangement.

4) How does inductance relate to voltage drop?

Inductance creates inductive reactance, which adds to circuit impedance. Under load, reactance contributes reactive voltage drop. Combine resistance and reactance to assess total drop and power-factor impacts.

5) What if the cable is in steel conduit or near steel?

Ferromagnetic materials can increase effective permeability and raise inductance. If you have credible permeability information, adjust μr. Otherwise, keep μr near 1 as a baseline and verify during detailed design.

6) Which frequency should I use for reactance checks?

Use the supply fundamental frequency for standard checks. For harmonics from drives or switching, evaluate reactance at the harmonic frequencies too, since reactance increases linearly with frequency.

7) Can higher inductance ever be beneficial?

Sometimes. More inductance can reduce di/dt and limit high-frequency current spikes. However, it can also worsen regulation and power factor, so assess the full system behavior.