Coaxial Cable: Structure, Transmission, and Applications

When you connect a cable modem, watch cable television, or deploy a security camera system, you're relying on a transmission medium whose elegant design dates back to 1880 when Oliver Heaviside first patented the coaxial cable concept. Despite being over 140 years old in principle, coaxial cable remains a critical transmission medium in modern networks—a testament to the brilliance of its concentric, layered architecture.

Coaxial cable represents one of networking's most ingeniously designed transmission media. Its name derives from the Latin prefix "co-" (together) and "axis"—describing how multiple cable layers share a common geometric axis. This precise concentricity isn't merely aesthetic; it's the fundamental engineering principle that gives coaxial cable its remarkable electromagnetic properties.

Before dissecting the physical layers, we must understand why coaxial cable exists and what problems it solves. Every transmission medium faces a fundamental challenge: electromagnetic interference (EMI).

When electrical current flows through a conductor, it generates an electromagnetic field around that conductor. Conversely, external electromagnetic fields can induce unwanted currents in a conductor—this is the principle behind both radio reception and signal interference. In networking, this interference manifests as:

• Crosstalk: Signals from adjacent cables leaking into each other
• Radio Frequency Interference (RFI): External radio signals corrupting data transmission
• Electromagnetic Pulse (EMP): High-energy events disrupting signal integrity
• Ambient Noise: Electrical noise from motors, fluorescent lights, and other equipment

Coaxial cable's genius lies in its self-shielding geometry. By surrounding the signal-carrying conductor with a grounded metallic shield—arranged concentrically around the same axis—the cable creates what engineers call a Faraday cage in cylindrical form.

The Concentricity Requirement:

For this shielding to work optimally, the inner and outer conductors must be precisely concentric—sharing exactly the same geometric axis. Any eccentricity (off-center positioning) creates asymmetric electromagnetic fields, reducing shielding effectiveness and causing impedance variations along the cable's length.

This is why coaxial cable manufacturing demands strict tolerances. High-quality cables maintain concentricity within fractions of a millimeter across their entire length. This precision is what distinguishes professional-grade cable from inferior products that suffer signal degradation.

A standard coaxial cable consists of four concentric layers, each serving a distinct and critical function. From inside to outside, these are:

1. Center Conductor (Core): The signal-carrying pathway
2. Dielectric Insulator: The spacing and insulating layer
3. Outer Conductor (Shield): The electromagnetic barrier
4. Outer Jacket: The protective covering

Let's examine each layer in engineering detail:

The center conductor is the cable's heart—the pathway through which signals actually travel. Its electrical and physical properties directly determine signal quality, attenuation, and power handling capability.

Conductor Materials:

Solid Copper:

• Advantages: Excellent conductivity (5.96 × 10⁷ S/m), superior signal quality, lower attenuation
• Disadvantages: More expensive, less flexible, can work-harden and break with repeated bending
• Applications: Fixed installations, backbone cabling, high-frequency applications

Stranded Copper:

• Advantages: High flexibility, resistant to fatigue from repeated bending
• Disadvantages: Slightly higher attenuation due to air gaps between strands, requires careful termination
• Applications: Patch cables, mobile equipment, installations requiring flexibility

Copper-Clad Steel (CCS):

• Advantages: Mechanical strength, lower cost, adequate for high-frequency signals (skin effect concentrates current at surface)
• Disadvantages: Higher DC resistance, unsuitable for Power over Coax applications
• Applications: Cable TV drop cables, antenna connections where mechanical strength matters

Copper-Clad Aluminum (CCA):

• Advantages: Lightweight, lower cost than pure copper
• Disadvantages: Lower conductivity than copper, connector compatibility issues
• Applications: Cost-sensitive installations with shorter runs

Conductor Diameter and Impedance:

The center conductor's diameter is not arbitrary—it's precisely calculated based on the cable's target characteristic impedance. For a given outer conductor diameter and dielectric constant, the center conductor diameter determines impedance:

• Larger diameter: Lower impedance, higher current capacity, increased stiffness
• Smaller diameter: Higher impedance, lower current capacity, improved flexibility

Common specifications:

• RG-6 (75Ω): 1.0mm center conductor (18 AWG)
• RG-59 (75Ω): 0.81mm center conductor (20 AWG)
• RG-58 (50Ω): 0.81mm center conductor (20 AWG)
• RG-8 (50Ω): 2.17mm center conductor (13 AWG)

The relationship between conductor diameter (d), shield inner diameter (D), and characteristic impedance (Z₀) is:

Z₀ = (138 / √εᵣ) × log₁₀(D/d)

Where εᵣ is the relative permittivity (dielectric constant) of the insulating material.

The dielectric insulator serves three critical functions: it electrically isolates the center conductor from the shield, maintains precise spacing for consistent impedance, and influences signal velocity and loss characteristics.

Dielectric Constant (εᵣ):

The dielectric constant measures how much the insulating material reduces electric field strength compared to a vacuum. This property directly affects:

• Characteristic Impedance: Higher εᵣ = lower impedance for given geometry
• Signal Velocity: Higher εᵣ = slower propagation (velocity factor = 1/√εᵣ)
• Cable Capacitance: Higher εᵣ = higher capacitance per unit length

Common Dielectric Materials:

Foam Dielectrics:

Foam dielectrics contain microscopic air bubbles injected during manufacturing. Since air has a dielectric constant of 1.0 (lowest possible), incorporating air lowers the effective dielectric constant. Benefits include:

• Lower attenuation: Less signal loss per unit length
• Higher velocity factor: Faster signal propagation
• Lighter weight: Reduced cable mass
• Better flexibility: Foam is more pliable than solid materials

However, foam dielectrics have drawbacks:

• Moisture vulnerability: Air bubbles can trap moisture if the jacket is compromised
• Compression sensitivity: Excessive bending can crush the foam structure
• Impedance variation: Crushed foam changes local impedance, causing reflections

The outer conductor—commonly called the shield—performs dual roles: it provides electromagnetic shielding AND serves as the return path for signal current. These functions are inseparable in coaxial cable design.

Shield Types:

Braided Shield:

• Construction: Woven mesh of thin copper or aluminum wires
• Coverage: Typically 60-95% depending on braid density
• Advantages: Excellent flexibility, good mechanical strength, reliable connector termination
• Disadvantages: Cannot achieve 100% coverage, higher attenuation than solid shields at very high frequencies
• Applications: Most general-purpose coaxial cables (RG-58, RG-59, RG-6)

Foil Shield:

• Construction: Thin aluminum or copper foil wrapped around dielectric, usually bonded to a polyester backing
• Coverage: 100% coverage
• Advantages: Complete high-frequency shielding, lightweight, low cost
• Disadvantages: Fragile (cannot withstand repeated flexing), difficult to terminate
• Applications: Usually combined with braid in "quad-shield" configurations

Solid (Hard-Line) Shields:

For the highest performance applications, coaxial cables can use solid aluminum or copper tubes as the outer conductor. These "hard-line" or "semi-rigid" cables offer:

• Complete shielding: No gaps whatsoever
• Lowest attenuation: Solid metal has lower resistance than braided wire
• Precise impedance: No variations from braid pattern
• Excellent power handling: Solid conductor dissipates heat efficiently

The tradeoff is significant: hard-line cables are inflexible, requiring special bending tools and techniques. They're used in cellular tower installations, broadcast transmission lines, and other fixed infrastructure.

Shield Effectiveness Measurement:

Shielding effectiveness is measured in decibels (dB) of signal attenuation. Higher numbers mean better shielding:

• 60 dB: Minimal commercial grade (1,000:1 signal reduction)
• 75 dB: Standard residential grade (32,000:1)
• 90 dB: Professional grade (1,000,000:1)
• 100+ dB: Broadcast/military grade (10,000,000,000:1)

The outer jacket provides mechanical protection and environmental sealing. While not directly involved in signal transmission, jacket selection critically affects cable longevity and safety compliance.

Jacket Materials:

Polyvinyl Chloride (PVC):

• Characteristics: Flexible, inexpensive, easy to work with
• Limitations: Releases toxic fumes when burned, not suitable for plenum spaces
• Color Coding: Often black for outdoor, gray or white for indoor
• Temperature Range: -20°C to +75°C typical

Polyethylene (PE):

• Characteristics: Excellent outdoor durability, UV resistant, moisture resistant
• Typical Application: Direct burial cables, outdoor runs
• Limitations: Less flexible than PVC, can crack in extreme cold
• Temperature Range: -40°C to +80°C typical

Plenum-Rated (CMP):

• Characteristics: Low-smoke, low-flame materials (typically fluoropolymers)
• Requirement: Mandated by building codes for air-handling spaces (dropped ceilings, HVAC ducts)
• Cost: Significantly higher than PVC
• Purpose: Prevents toxic smoke from spreading through ventilation systems during fire

Specialized Jackets:

• Riser-Rated (CMR): Suitable for vertical runs between floors; has fire resistance but not at plenum level
• Direct Burial: Includes water-blocking gel and UV-resistant jacket for underground installation without conduit
• Armored: Includes steel or aluminum armor layer for protection against rodents, crushing, or physical damage
• Marine Grade: Tinned copper and specialized jacket for saltwater environments
• Halogen-Free: Eliminates halogens from jacket material; required in some European and transportation applications

Cable Identification:

Jacket markings typically include:

• Cable type (RG-6, RG-11, etc.)
• Impedance (75Ω, 50Ω)
• Fire rating (CM, CMR, CMP, CMX)
• Manufacturer name and date code
• Sequential footage markers (for measuring cable runs)

The "RG" designation (Radio Guide) originated from US military specifications during World War II. While the original specifications are obsolete, the naming convention persists in describing cable geometry and nominal impedance.

75Ω Cables (Video/CATV):

50Ω Cables (Data/Radio):

We've conducted a comprehensive examination of coaxial cable anatomy. Let's consolidate the key engineering principles:

What's next:

With the physical structure understood, we'll explore how coaxial cable actually carries signals in two fundamentally different ways—baseband and broadband transmission. The next page examines these signaling modes, their technical characteristics, and why each suits different networking applications.