Learn how to manage and protect cabling systems

When choosing the transmission medium for the cabling system, it is necessary to strike a balance between factors such as bandwidth, flexibility, scalability and cost. Taking into account the development of applications, choosing the most appropriate and forward-looking transmission medium becomes the wisest choice. In short, if you need to establish an upgradeable and longer life cycle cabling system, the ideal choice is to install cables that support high-bandwidth applications and eliminate the risk of replacing cabling due to increased requirements.

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Next, we will help readers make a choice by comparing the advantages and disadvantages of commonly used wiring media.

Fiber Optic Systems

Optical fiber is the best medium for information transmission. It not only has unparalleled advantages over copper cable systems in terms of long-distance and high-speed transmission, but also is not limited by raw material resources, unlike copper cable manufacturing, which is subject to the rare resource of raw materials - copper metal. In addition, compared with copper cables, optical cables are smaller in size, and there is no need to limit the number of connectors in the link when networking, and there is no need to consider the problems caused by electromagnetic interference. With the trend of "optical fiber in and copper out", optical fiber systems will play an increasingly important role in data centers.

The price of fiber optic port equipment is still high, several times that of copper cable equipment for the same application, which is the main reason why fiber optic systems cannot completely replace copper cable systems. Secondly, fiber optic installation requires professional practitioners to use special tools, and the construction cost and requirements are relatively high. In addition, facing the emerging and highly concerned PoE Ethernet power supply technology, fiber optic systems cannot support it.

For fiber systems in data centers, the general consensus in the industry is to recommend the use of OM3 laser optimized fiber systems. This system can support 10Gb/s transmission at a wavelength of 850nm using VCSEL (vertical surface laser emitter) light sources, with a distance of up to 300 meters. In terms of upgrades, some manufacturers are working to go beyond the 10Gb/s standard and use coarse wavelength division multiplexing technology to transmit 40Gb/s.

Copper Cable System

Although copper cable systems are limited in transmission distance and the number of channel connectors compared to optical fiber systems, copper cable systems are the most familiar to all designers, installers, and users. They can achieve high-speed applications in a low-cost manner, from 10/100/1000Base-T to 10GBase-T, copper cable systems can support them well. In addition, unshielded systems can support PoE applications, providing power to remote devices while transmitting data signals.

When TIA issued the 942 standard in 2005, the Category 6A standard was not yet mature. Considering the market situation at the time, the standard recommended the use of Category 6 or higher cables. Today, Category 6A is the most economical link configuration method to achieve 10Gb/s transmission requirements. The system uses less than twice the cost of Category 6 but provides 10 times the transmission capacity, so the cost per Gbps is much lower. Although Category 6 can also support 10Gb/s in a short distance, its noise suppression ability and transmission performance are far behind 6A.

Although the existing 10G copper port network equipment on the market is expensive, with the mass production of equipment manufacturers and the maturity of the market, the price will naturally drop, just like the original Gigabit port equipment. It is worth noting that since 10G transmission requires high power, the power consumption of early transceivers even reached 10 to 15 watts per port, so the "low-power short-distance transmission mode" is specified in the 10GBASE-T standard to reduce the power consumption of each port to 4 watts. The important point is that only Category 6A or higher cables can support this mode within a distance of 30 meters.

Shielded or unshielded

It goes without saying that the shielding system has good anti-electromagnetic interference and information leakage prevention capabilities. For the 6A category shielding system that supports 10G transmission, there is no need to consider the external crosstalk test problem, which will undoubtedly save a lot of testing time. At present, the reason why most domestic users consider using the shielding system is for information security considerations. In addition, the shielding system can support higher bandwidth applications, up to 1.2GHz.

However, the shielded cabling system also has its development limitations. First, the shielded system is currently poorly accepted worldwide, and may only account for 5% of the entire copper cable cabling system market share. This means that designers and installers are relatively unfamiliar with it and need further training. In order to ensure the 360-degree continuous shielding effect of the shielded system, the shielded system must be properly installed and grounded, which is difficult to construct and time-consuming. In addition, due to the presence of the metal protective layer, when the shielded system is used to support PoEPlus applications, the heat generated by the cable cannot be dissipated, which will cause certain interference to the performance.

Protect your cabling system investment

In addition to choosing the right cable media type, how to manage and protect the cabling system is also crucial to ensuring business continuity and extending the life cycle of the cabling system.

Some key points are listed below:

Labeling system

Label identification is the basis of cabling system management and a basic element of the data center. A good label identification system will help network management personnel quickly find relevant information and shorten the time of moving, adding and changing. Good label identification can not only add value to the owner and improve the aesthetics, but also make the work more efficient, flexible and reliable.

Paths and Spaces

Since the data center is a high-density computing environment, there will be a large number of cables. If the reasonable paths and space planning for these cables are not carried out at the beginning of the design, the cables will be out of control and crowded as the data center operates and expands. Eventually, the cooling capacity of the data center will be affected, and it may even be impossible to maintain it, so it has to be demolished and rebuilt.

The ideal solution is to make reasonable use of the limited space in the data center and plan the space and paths for copper cables, optical cables and power cables, that is, to effectively separate the three types of cables for easy implementation and maintenance. The choice of running cables above or below each has different advantages and disadvantages. It is recommended that cables that are fixed for a long time, such as trunk and horizontal cables, be run under the raised floor, and jumpers (copper cables and optical jumpers) be run above the rack.

Different cables have different wire diameters. When designing the routing path, the cable path fill rate must be considered. It is recommended that the path fill rate be 35%~40% during design.

Cabinets and racks

In order to achieve good cable management and help maintenance personnel reduce the time of moving, adding and replacing wiring systems, cabinets and racks with cable management designs should be selected in data centers. Consider the storage of vertical and horizontal cable managers and redundant length cables in cabinets and racks, maintain the cable bending radius while making the cables more neat and orderly; avoid cable entanglement and accumulation that block the flow of hot and cold air in cabinets and racks, so that active equipment can effectively achieve heat dissipation and cooling.

Intelligent physical layer management system

The intelligent physical layer management system helps network administrators understand the connectivity of the network. By monitoring the connection status in real time, any network interruption can be quickly identified and reported to the system administrator immediately. This helps to quickly troubleshoot faults and security threats and minimize downtime.

In addition, the intelligent physical layer management system database continuously records asset movements and configuration changes of the system and physical layer. This information can be used to meet industry-mandated reporting requirements or establish service level agreements (SLAs) for customer data centers, avoiding the human errors that may exist in manual analysis tables.