Transmission Line Equations

Transmission lines take on many forms in order to accommodate particular applications. All rely on the same basic components - two or more conductors separated by a dielectric (insulator). The physical configuration and properties of all the components determines the characteristic impedance, distortion, transmission speed, and loss.

See a discussion on transmission lines and coaxial connectors.

The following formulas are presented in a compact text format that can be copied and pasted into a spreadsheet or other application.

For the following equations, ε is the dielectric constant (ε = 1 for air)

Two Conductors in Parallel (Unbalanced)

Above Ground Plane

For D << d, h

Z₀= (69/ε^½) log₁₀{(4h/d)[1+(2h/D)²]^-½}

Parallel conductors above a ground plane - RF Cafe

Single Conductor Above Ground Plane

For d << h

Z₀= (138/ε^½) log₁₀(4h/d)

Single conductor above a ground plane - RF Cafe

Two Conductors in Parallel (Balanced)

Above Ground Plane

For D << d, h₁, h₂

Z₀= (276/ε^½) log₁₀{(2D/d)[1+(D/2h)²]^-½}

Parallel conductors above a ground plane - RF Cafe

Two Conductors in Parallel (Balanced)

Different Heights Above Ground Plane

For D << d, h₁, h₂

Z₀= (276/ε^½)log₁₀{(2D/d)[1+(D²/4h₁h₂)]^-½}

Parallel conductors different heights above a ground plane - RF Cafe

Single Conductor Between

Parallel Ground Planes

For d/h << 0.75

Z₀= (138/ε^½) log₁₀(4h/πd)

Single conductor between parallel ground planes - RF Cafe

Two Conductors in Parallel (Balanced)

Between Parallel Ground Planes

For d << D, h

Z₀= (276/ε^½) log₁₀{[4h tanh(πD/2h)]/πd}

Two conductors between parallel ground planes - RF Cafe

Balanced Conductors Between

Parallel Ground Planes

For d << h

Z₀= (276/ε^½) log₁₀(2h/πd)

Balanced conductors between parallel ground planes - RF Cafe

Two Conductors in Parallel (Balanced)

of Unequal Diameters

Z₀= (60/ε^½) cosh^-1 (N)

N = ½[(4D²/d₁d₂) - (d₁/d₂) - (d₂/d₁)]

Parallel conductors - unequal diameters - RF Cafe

Balanced 4-Wire Array

For d << D₁, D₂

Z₀= (138/ε^½) log₁₀{(2D₂/d)[1+(D₂/D₁)²]^-½}

Balanced 4-wire array - RF Cafe

Two Conductors

in Open Air

Z₀= 276 log₁₀(2D/d)

Two conductors in open air - RF Cafe

5-Wire Array

For d << D

Z₀= (173/ε^½) log₁₀(D/0.933d)

5-wire array - RF Cafe

Single Conductor in

Square Conductive Enclosure

For d << D

Z₀≈ [138 log₁₀(ρ) +6.48-2.34A-0.48B-0.12C]/ε^½

A = (1+0.405ρ^-4)/(1-0.405ρ^-4)

B = (1+0.163ρ^-8)/(1-0.163ρ^-8)

C = (1+0.067ρ^-12)/(1-0.067ρ^-12)

ρ= D/d

Single conductor in square conducting enclosure - RF Cafe

Air Coaxial Cable with

Dielectric Supporting Wedge

For d << D

Z₀≈ [138 log₁₀(D/d)]/[1+(ε-1)(θ/360)]^½)

ε = wedge dielectric constant

θ= wedge angle in degrees

Air coaxial cable with dielectric supporting wedge - RF Cafe

Two Conductors Inside Shield

(sheath return)

For d << D, h

Z₀= (69/ε^½) log₁₀[(ν/2σ²)(1-σ⁴)]

ν = h/d σ = h/D

Twin conductors inside shield - RF Cafe

Balanced Shielded Line

For D>>d, h>>d

Z₀= (276/ε^½) log₁₀{2ν[(1-σ²)/(1+σ²)]}

ν = h/d σ = h/D

Balanced shielded line equation - RF Cafe

Two Conductors in Parallel (Unbalanced)

Inside Rectangular Enclosure

For d << D, h, w

∞

Z₀= (276/ε^½) {log₁₀[(4h tanh(πD/2h)/πd)- ∑ log₁₀[(1+μ_m²)/(1-ν_m²)]}

^m=1

μ_m=sinh(πD/2h)/cosh(mπw/2h)

ν_m=sinh(πD/2h)/sinh(mπw/2h)

Balanced 2-conductor line inside rectangular enclosure - RF Cafe

Equations appear in "Reference Data for Engineers," Sams Publishing 1993