The 400G transceiver is mainly used for photoelectric conversion. The electrical signal is converted into an optical signal at the transmitting end, and then transmitted through the optical fiber. At the receiving end, the optical signal is converted into an electrical signal. The transmission rate of 400G transceivers is 400G, which was born to adapt to the gradually deducted network market. 400G transceivers play a vital role and influence in the construction of 400G network systems.
The main function of 400G transceivers is to improve data throughput and maximize the bandwidth and port density of the data center. The future trend of 400G transceivers is to achieve wide gain, low noise, miniaturization and integration, and to provide high-quality optical communication modules for next-generation wireless networks and ultra-large data centers.
The 400G transceiver market is experiencing rapid growth due to the increasing demand for high-speed data transmission in various industries, such as telecommunications, data centers, and cloud computing, driving the adoption of advanced optical technologies.
Although 10G, 25G, 40G and even 100G transceivers have become the mainstream of the market, as the requirements for bandwidth, port density and system energy consumption continue to increase, 400G transceivers will further push the technology to a higher level of development.
Compared with 10G, 25G and 40G transceivers, the arrival of 400G transceivers will enable optical communications to enter a new era. Optical communications is transforming from single-carrier modulation coherent detection of low-end transceivers to polarization multiplexing multi-carrier applications. We provide 10g sfp+ transceiver for sale.
And if you want information about arista transceiver, you can contact us. Photonic integration and electronic integration, ADC / DSP technology will become the key to the commercialization of 400G optical communication modules and systems. With the urgent need for Ethernet standardization, the need for optical parallelization will greatly promote the development of photonic integration technology.
Equipment manufacturers of optical modules will encrypt their devices to varying degrees, also known as compatibility. Modules of a particular brand can only be used with devices of the same brand, and cannot be matched with other brand optical modules. Compatibility manufacturers need to conduct different compatibility adaptations on the optical modules. Whether or not they can perfectly solve compatibility issues is particularly important.