ASU optical cable is a variant of all-dielectric self-supporting (ADSS) cable designed for complex outdoor environments. Its performance parameters integrate cutting-edge achievements in structural mechanics, materials science, and optical transmission technology, widely used in overhead communication, smart grids, rail transit, and other scenarios. The following systematically analyzes its core parameter characteristics from six dimensions: structural parameters, optical performance, mechanical properties, environmental adaptability, installation compatibility, and application adaptability.

GYFTA optical cable is a stranded-layer outdoor communication cable with a non-metallic strength member and aluminum tape longitudinal armor structure. It combines the anti-electromagnetic interference advantages of non-metallic reinforcements with the mechanical protection performance of metal armor, making it widely applicable to various laying scenarios such as pipeline, direct burial, and non-self-supporting overhead installations. It is particularly suitable for complex environments with high mechanical protection requirements.

Audio Jumper (audio patch cable) is the "neural network" connecting various devices in audio systems, widely used in recording studios, stage performances, radio and television, home audio-visual setups, and other scenarios. It is responsible for accurately transmitting audio signals between microphones, mixers, power amplifiers, speakers, effectors, and other equipment. As a key carrier of signal transmission, its parameter design directly affects sound quality clarity, dynamic range, anti-interference ability, and system stability. The following is a detailed analysis of the parameter characteristics of audio jumpers exceeding 2,500 words, covering six dimensions: physical specifications, electrical performance, interface characteristics, structural design, environmental adaptability, and scenario compatibility.

The physical specifications of network cable jumpers determine their basic transmission capabilities, mechanical strength, and flexibility, laying the foundation for stable data transmission.

As a core device for ensuring the safety of optical cable connections in optical fiber communication networks, optical fiber joint boxes play an irreplaceable role as "guardians" in the optical signal transmission chain. They not only need to ensure the physical safety of optical fiber joints but also guarantee the stable transmission of optical signals in complex environments. Their parameter characteristics cover multiple dimensions from basic capacity to complex environmental adaptability, with each parameter directly affecting the applicable scenarios and operational performance of the device. The following provides a comprehensive and in-depth analysis of their parameter characteristics from multiple key perspectives.

In the evolution of twisted-pair cabling, CAT8 (Category 8 cable) represents the highest performance grade in current copper cable standards, specifically designed for short-distance, ultra-high bandwidth scenarios such as data centers and supercomputing centers. Compared to CAT7’s 1000MHz bandwidth and 100Gbps short-distance speed, CAT8 achieves stable 25Gbps/40Gbps transmission through doubled bandwidth and stricter parameter optimization, emerging as a "core competitor" between copper cables and optical fibers in short-distance applications. Below is a comprehensive analysis of CAT8’s parameter characteristics from dimensions including transmission performance, structural innovation, electrical parameters, and link design.