Fiber Optical Networking

Passive SFP+ Direct Attach Kupfer (DAC)-Kabel oder SFP+ zu SFP+ passive Kupferkabel sind 10-Gb-Kabelkonfektionen. Die Kabel entsprechen den SFF-8431-Spezifikationen und ermöglichen die Verbindung zwischen Geräten mit SFP+ -Ports. Und diese Kabel verwenden modernste Signalverarbeitungstechnologie, um den wachsenden Bedarf an kosteneffektiven Rechenzentrumsverbindungen zu decken. Warum würden Sie passives SFP+-Kabel wählen? Informationen zu passiven SFP+ -DAC-Kabeln werden in diesem Artikel angeboten. Überblick über passives SFP+ Kabel Die passive SFP+ DAC-Kabelkonfektion ist vollständig kompatibel mit dem SFF-8431 SFP+ MSA. Die Kabelkonstruktion besteht aus einem 100 zwei Paar abgeschirmten Twinax mit Ableitern für digitale Erde. Passives SFP+ Kabel ermöglicht eine serielle Datenübertragung von bis zu 12 Gbit/s in jeder Richtung. Das passive Design hat keine Signalverstärkung in der Kabelanordnung. Die elektronische Dispersionskompensation (Electronic Dispersion Compensation, EDC)

In FTTx and PON architectures, optical splitter plays an increasingly significant role to create a variety of point-to-multipoint fiber optic networks. But do you know what is a fiber optic splitter ? In fact, a fiber optic splitter is a passive optical device that can split or separate an incident light beam into two or more light beams. Basically, there are two types of fiber splitter classified by their working principle: fused biconical taper splitter ( FBT splitter ) and planar lightwave circuit splitter ( PLC splitter ). You may have one question: what’s the difference between them and shall we use FBT or PLC splitter? What Is FBT Splitter? FBT splitter is based on a traditional technology to weld several fiber together from side of the fiber. Fibers are aligned by heating for a specific location and length. Because the fused fibers are very fragile, they are protected by a glass tube made of epoxy and silica powder. And then a stainless steel tube covers the inner glass t

The war of copper vs fiber has raged for years. Fiber seems to operate as a rival to copper rather than a replacement until now, it has already established a niche in the industry. However, with recent advances in copper technology, the copper presents the same step-ladder upgrade path. The speed difference between the two media is considerably smaller. In some ways, the copper matters most to IT experts and data center decision makers. But many end-user organizations still face tough decision about which type is the best overall value for their current and future projected needs. This battle is also being waged in SFP transceivers , there is a measurable difference in the copper SFP vs optical SFP. This article will explore their respective strengths and weaknesses and reveal insights into how IT experts are to proceed. Copper SFP vs Optical SFP: Copper SFP Is a Balanced Choice in Environment Restrictions The Gigabit RJ45 copper SFP transceiver supports 1000Mbps over Cat5 ca

An optical fiber cable uses light wave for voice and data transmission, its data transmission capacity is 4.5 times more than conventional copper cables. So in the past several decades, we have seen that fiber optic cables are superior to traditional copper twisted-pair cable or coaxial cable because of its unique physical characteristics, allowing information to travel at speeds increasingly approaching the speed of light without interference between adjacent wavelengths. In leading market, the global drive to implement FTTx into more new venues is good news for the market of optical fiber cables. Another good trend is that the price erosion of optical fiber cables had been 10 to 15 percent annually, in result that the demand of optical fiber cable is expected to continue growing in the foreseeable future. And the growing data transmission workloads placed by high-performance computers, servers and network storage systems is helping spur growth in the market. Consequently, fiber opt

In the early stage of optical fiber communication, one optical fiber can only transmit signals of one wavelength. This is known as conventional two-fiber Bi-Directional communication - at least two fibers are needed to accomplish the full-duplex communication with TX and RX optical signals. With the development of WDM technology, transmitting and receiving of optical signals on separate wavelength can be achieved through only one single fiber. This single fiber BiDi transmission gradually becomes a popular and cost-effective solution for today’s data center and IT infrastructure, because it helps to maximize the capacity and usage of optical fibers. Consequently, BiDi optical transceiver as the basic component plays an irreplaceable role in the WDM BiDi transmission application. This article will generally introduce Cisco BiDi SFP transceivers, including GLC-BX-U, GLC-BX-D, GLC-BX-20U, GLC-BX-20D, GLC-BX40-D-I, GLC-BX40-U-I, GLC-BX80-D-I, GLC-BX80-U-I, GLC-BX120-U, GLC-BX120-D, etc.

SFP-GE-S-2 and GLC-SX-MM are Cisco 1000BASE-SX SFP multimode fiber transceivers. Since there are similar specifications for these two multimode modules, many end users may be confused when choosing a multimode fiber SFP LC connector SX transceiver for their Cisco switches. So, are they the same one? This post intends to give a simple explanation of SFP-GE-S-2 vs. GLC-SX-MM. SFP-GE-S-2 Module Cisco SFP-GE-S-2 is a 1 GbE SFP SX fiber transceiver that supports the maximum data rate of 1Gbps. It’s compatible with the IEEE 802.3z 1000BASE-SX standard, and can operate on standard multimode fiber optic link spans of up to 2 km. Module/Specs Cisco SFP-GE-S-2 Interface LC duplex Wavelength 1310nm Tx power -9.5 ~ -3dBm Receiver Sensitivity < -17dBm DOM Support Yes Temperature Range 32℉to 158℉ (0℃ to 70℃) Data Rat 1G Fiber Mode MMF GLC-SX-MM Module GLC-SX-MM transceiver is also a Cisco 1000BASE-SX fiber transceiver that designed for Gigab