Coaxial Cables (RF)

Image	Part Number	Description / PDF	Quantity	Rfq
	CARTNM305NSMAM-001 Laird - Antennas	CABLE ASSY A195 RTNM 10FT ATX195	0
	PT19525TSTS Laird - Antennas	CABLE ASSY A195 TNCM TNCM	0
	CANM300SNM-001 Laird - Antennas	CABLE ASSY 2M LOW PIM/PLENUM	0
	PT1951BBFBH Laird - Antennas	CABLE ASSY A195 BNCM BNCF	0
	PT4001NRTNF Laird - Antennas	CBL ASSY PIGTAIL 1' NM RTNF	0
	PT40010NP Laird - Antennas	CBL ASSY PIGTAIL 10' NM UHFM	0
	PT1740.66BMCX Laird - Antennas	CABLE ASSY 174 BNCM MCX MALE	0
	PT82MBNFBH Laird - Antennas	CBL ASSY PIGTAIL 2' MUHFM BNCF	0
	PT83.33NT Laird - Antennas	CBL ASSY PIGTAIL 3.33' NM TNCM	0
	CARTNM610PRTNM-001 Laird - Antennas	CABLE ASSY A400 RTNM RTNM CMP	0
	PT840NSMA Laird - Antennas	CBL ASSY PIGTAIL 40' NM SMA MALE	0
	CANM24BRTN Laird - Antennas	CABLE ASSY 24" N MALE-RP TNC FEM	0
	PT850NN Laird - Antennas	CBL ASSY PIGTAIL 50' NM NM	0
	PT4008PP Laird - Antennas	CBL ASSY PIGTAIL 8' UHFM UHFM	0
	PT4005NN Laird - Antennas	CBL ASSY PIGTAIL 5' NM NM	0
	PT400150NNF Laird - Antennas	CBL ASSY PIGTAIL 150' NM NF	0
	PTD20NN Laird - Antennas	CBL ASSY 20' TEFLEX NM-NM	0
	PT400100NNF Laird - Antennas	CBL ASSY PIGTAIL 100'CRIMP N-NF	0
	PT8X3PFPF Laird - Antennas	CBL ASSY PIGTAIL 3' UHFF-UHFF	0
	PT8X75NT Laird - Antennas	CBL ASSY PIGTAIL 75' NM-TNC MALE	0

Coaxial Cables (RF)

1. Overview

RF coaxial cables are cylindrical transmission lines consisting of concentric conductors separated by dielectric materials. They enable efficient transfer of high-frequency electrical signals (typically 1 MHz to 110 GHz) with minimal interference, making them critical components in telecommunications, broadcasting, aerospace, and test equipment. Their shielded structure ensures signal integrity in noisy environments.

2. Main Types and Functional Classification

Type	Key Features	Applications
Rigid Coaxial Cable	Metallic outer conductor, fixed geometry	Test labs, high-power transmitters
Semi-Rigid Cable	Formable but non-flexing, excellent shielding	Microwave systems, aerospace
Flexible Coaxial Cable	Braided shield, bendable	General-purpose communication systems
Low-Loss Foam Dielectric	PE/PTFE dielectric, reduced attenuation	5G infrastructure, satellite links

3. Structure and Composition

Typical construction includes:

Center Conductor: Solid/stranded copper/aluminum for signal transmission
Dielectric Insulator: Polyethylene (PE) or PTFE foam maintaining uniform impedance
Shielding Layer: Braided copper/aluminum with 85-95% coverage (single/double layers)
Outer Jacket: PVC/PE for mechanical/environmental protection

Critical dimensions determine characteristic impedance (commonly 50 for data/75 for video).

4. Key Technical Parameters

Parameter	Description	Importance
Characteristic Impedance	Matched load resistance (50/75 )	Minimizes signal reflection
Attenuation (dB/100m)	Signal loss per unit length	Determines transmission distance
Frequency Range	Operational bandwidth (e.g., 0-18GHz)	Limits application scope
VSWR	Voltage Standing Wave Ratio	Measures impedance matching quality
Power Handling	Max RF power capacity	Prevents dielectric breakdown

5. Application Fields

Telecommunications: 5G base stations, fiber-wireless systems
Broadcasting: TV antenna feeds, studio equipment
Aerospace: Radar systems, avionics
Test & Measurement: Oscilloscope probes, signal analyzers
Industrial IoT: Wireless sensor networks

6. Leading Manufacturers

Manufacturer	Key Products
Amphenol Corporation	SUCOFLEX 104, 106 series
TE Connectivity	Radiation-resistant RG-58
HUBER+SUHNER	RF flexible cables (SST series)
CommScope	Heliax FSJ1-50A
Southwest Microwave	832 Series semi-rigid

7. Selection Guidelines

Key considerations:

Match impedance to system requirements
Verify frequency/attenuation specifications
Environmental factors (temperature, UV resistance)
Mechanical requirements (flexure life, bending radius)
Connector compatibility (SMA, N-Type, etc.)

Example: 5G massive MIMO deployment requires low-PIM (Passive Intermodulation) cables with <0.1dB/100m loss at 3.5GHz.

8. Industry Trends

High-Frequency Demand: Development of 110GHz+ cables for 6G research
Weight Reduction: Composite materials in aerospace applications
Green Manufacturing: Halogen-free jacket materials adoption
Smart Cables: Embedded sensors for condition monitoring
Standardization: 5G NR band-specific cable specifications