Understanding Insertion Loss Specifications for High-Quality Micro Coaxial Cables - Micro Coaxial Cable factory-(FRS)

Micro coaxial cables, the unsung heroes of compact, high-frequency electronics, are critical for transmitting signals with minimal degradation. Among their key performance parameters, ​insertion loss is paramount. Understanding the specifications for insertion loss in high-quality micro coax is essential for engineers, designers, and procurement specialists working in industries like telecommunications, medical devices, aerospace, defense, and consumer electronics.

What is Insertion Loss?

Insertion loss (IL), measured in decibels (dB), quantifies the signal power lost as it travels through the cable assembly (including connectors). It’s essentially the reduction in signal strength between the input and output of the cable. ​Lower insertion loss values are always better, indicating more efficient signal transmission. High insertion loss can lead to weakened signals, data errors, reduced range, and impaired system performance.

Factors Influencing Micro Coax Insertion Loss

Insertion loss in micro coaxial cables is primarily determined by:

1. ​Frequency: Loss increases significantly with frequency. Performance at higher frequencies (e.g., mmWave bands like 26 GHz, 40 GHz, 67 GHz) is a key differentiator for high-quality cables.
2. ​Cable Length: Loss is directly proportional to length. Specifications are almost always given per unit length (e.g., dB/meter or dB/foot).
3. ​Conductor Material & Size: Larger center conductors generally have lower resistance and thus lower loss, but micro coax requires a small overall diameter. High-purity copper or silver-plated copper conductors are common in high-performance cables.
4. ​Dielectric Material: The insulating material surrounding the center conductor (e.g., PTFE, FEP, Polyethylene) significantly impacts loss. Materials with lower dissipation factors (loss tangents) are preferred for low-loss applications. Foamed or air-assisted dielectrics further reduce loss.
5. ​Shielding Effectiveness: Effective shielding (often multi-layer: braid + foil) minimizes signal leakage and external interference, but also contributes slightly to conductor loss. The design seeks optimal balance.
6. ​Connectors: High-quality, precision-machined connectors with smooth surfaces and low-loss dielectric interfaces are crucial. Mating adapters also add loss.

Typical Insertion Loss Specifications for High-Quality Micro Coax

Exact specifications vary significantly between manufacturers, cable series, and connector types. However, high-quality micro coaxial cables generally fall into performance tiers defined by their loss characteristics, often compared at specific benchmark frequencies like 3 GHz, 10 GHz, 18 GHz, 26 GHz, 40 GHz, and 67 GHz.

• ​Standard Performance:
  • Loss at 3 GHz: Typically < 0.5 dB/m to 1.0 dB/m
  • Loss at 10 GHz: Typically < 1.0 dB/m to 2.0 dB/m
  • Suitable for lower-frequency applications or shorter runs where loss is less critical.
• ​High Performance / Low Loss:
  • Loss at 3 GHz: Typically < 0.3 dB/m to 0.5 dB/m
  • Loss at 10 GHz: Typically < 0.7 dB/m to 1.5 dB/m
  • Loss at 26 GHz: Typically < 2.0 dB/m to 3.5 dB/m
  • Used in demanding RF applications, test equipment interconnects, higher data rate digital systems.
• ​Premium Performance / Very Low Loss (VLL) / Ultra Low Loss (ULL):
  • Often utilize specialized designs (e.g., air-core or micro-porous PTFE dielectrics).
  • Loss at 3 GHz: Typically < 0.2 dB/m to 0.4 dB/m
  • Loss at 10 GHz: Typically < 0.5 dB/m to 1.0 dB/m
  • Loss at 26 GHz: Typically < 1.5 dB/m to 2.5 dB/m
  • Loss at 40 GHz: Typically < 2.0 dB/m to 3.0 dB/m
  • Loss at 67 GHz: Typically < 3.0 dB/m to 4.5 dB/m
  • Essential for mmWave applications (5G/6G FR2, SATCOM, radar), high-resolution instrumentation, quantum computing, and long-haul signal paths within assemblies.

Reading Manufacturer Specifications:

Always refer to the ​detailed datasheet for the specific cable part number and connector combination. Key things to look for:

1. ​Frequency Range: What frequencies are the specs valid for?
2. ​Loss Curve/Table: A graph or table showing loss (dB) vs. frequency, usually normalized to per meter or per foot. This is the most critical data.
3. ​Test Conditions: Specified length, connector type, temperature, and sometimes bend radius during test.
4. ​Tolerance: Manufacturing variations (e.g., ±0.05 dB/m at X GHz).
5. ​Stability: Does loss remain stable over time, temperature cycles, and flexing? High-quality cables offer excellent phase and amplitude stability alongside low loss.
6. ​Frequency Limit: The maximum frequency the cable is rated for reliable operation.

Industry Standards and References:

While manufacturers define specific cable specs, industry standards provide consistency:

• ​MIL-DTL-17: The classic military standard for coaxial cables defines types (like RG-178, RG-316) and includes insertion loss limits for various sizes, though these are often higher than what premium commercial cables achieve today. Newer MIL specs exist for specialized cables.
• ​IEC 61196 (Parts 1, 4, 6, 8): International standards covering general requirements, sectional specs for various cable types, test methods, etc.
• ​ASTM D4566: Standard test methods for electrical performance properties of insulated and sheathed cables.
• ​IPC/WHMA-A-620: Covers acceptability criteria for cable and wire harness assemblies, including coaxial assemblies, though specific performance levels are defined by the cable/jacketing specs.

Importance of Low Insertion Loss in Modern Applications

• ​5G/6G & mmWave: Enables efficient signal distribution in massive MIMO antennas and base stations operating at 24 GHz, 28 GHz, 39 GHz, and beyond.
• ​High-Speed Digital: Preserves signal integrity for high-data-rate protocols (USB4, Thunderbolt, PCIe Gen5/6) operating at multi-GHz frequencies.
• ​Medical Imaging: Ensures accurate signal transmission in sensitive equipment like MRI machines and ultrasound probes.
• ​Aerospace & Defense: Critical for radar systems, avionics, secure comms, and satellite payloads where signal strength and reliability are mission-critical.
• ​Test & Measurement: Minimizes measurement uncertainty in oscilloscopes, VNAs, and spectrum analyzers when cables are part of the signal path.

Conclusion

Insertion loss is the definitive metric for evaluating the signal transmission efficiency of high-quality micro coaxial cables. Specifications range widely, but premium cables deliver remarkably low loss (< 1.0 dB/m at 10 GHz, < 3.0 dB/m at 40 GHz) essential for cutting-edge high-frequency and mmWave applications. When selecting cable assemblies, always demand detailed, frequency-dependent insertion loss charts from the manufacturer datasheet specific to your required cable diameter, frequency range, and connector configuration. Investing in cable assemblies with optimized low-loss specs directly translates to enhanced system performance, range, and reliability in today’s demanding electronic systems.