An air line is a Transmission line whose dielectric is air (or vacuum), with perfectly conducting conductors. Equivalently: a lossless TEM line with , , , .
The simplest possible TEM line, and the canonical starting case for transmission-line problems before adding dielectric materials, conductor losses, or leakage.
Parameter values
The four distributed parameters reduce to two:
with the universal TEM identity pinning down their product. For a specific geometry (coax, parallel-wire, etc.), and follow from the cross-section dimensions.
For a coaxial line with inner radius , outer radius :
Check: . ✓
Why it’s useful as a baseline
Phase velocity equals :
Signals on an air line travel at the speed of light, the fastest any TEM line can carry them. Any dielectric () slows the signal by a factor of .
Propagation constant is purely imaginary:
No attenuation. The wave amplitude stays constant along the line (for as long as the model holds; real conductors and air have nonzero losses, just tiny).
Characteristic impedance is real:
For air-dielectric coax, . Inverting: 50 Ω requires ; 75 Ω requires (the canonical air-dielectric values). Filling the line with a dielectric of relative permittivity scales these by .
When the air-line approximation is valid
The model holds when:
- The dielectric losses () are negligible: true for air, vacuum, dry gases.
- The conductor losses () are negligible: approximately true at low frequency in good conductors, or in superconducting lines.
- No radiation losses. TEM lines are mostly self-contained, but at very high frequencies and with imperfect geometries, some power can leak as radiation.
Real-world “air-dielectric” coaxial cables (like rigid copper coax, used for low-loss RF and microwave) have actual finite from conductor resistance, especially at high frequency due to skin effect, but their is essentially zero. They behave like air lines for many purposes, with small corrections for conductor loss.
When it’s used in problems
The air-line idealization shows up as:
- The reference case in textbook transmission-line problems. “Assume a lossless air line” simplifies to and to a real number, and makes Smith chart analysis exact.
- High-precision measurements. Air-dielectric precision coaxial standards (Type N, 3.5 mm, 2.4 mm connectors with rigid bead-supported inner conductors) are calibrated to air-line behavior at the metrology level.
- RF and microwave instrumentation. Network analyzers use air-dielectric reference standards because their behavior is fully predicted by geometry alone — no dielectric properties to characterize.
Beyond about 10 GHz, even “air lines” need corrections for skin-effect conductor loss, but in the GHz range and below, the air-line model is accurate for rigid coax.
Versus dielectric-filled line
| Air line | Dielectric-filled | |
|---|---|---|
| at 1 GHz | 30 cm | 30/ cm |
| same (depends on , not ) | same | |
Filling with a dielectric () lowers by and slows the wave by the same factor. So 50 Ω coax with PE dielectric () requires (standard RG-58: ), while 50 Ω air-dielectric coax needs only .
In context
The cleanest base case for TEM transmission lines: zero loss, light-speed propagation, real . Adding dielectric filling () gives the typical practical coax; adding conductor loss () and dielectric leakage () gives the Lossy transmission line used to model real cables at high frequency or with imperfect materials.