Ultra-high-speed Transmission of 5G High-frequency Signals and Large-bandwidth Integrated Circuits

Zhengyu Chen

doi:10.54097/khpsnr97

Authors

Zhengyu Chen

DOI:

https://doi.org/10.54097/khpsnr97

Keywords:

5G Communication, Integrated Circuit Manufacturing, High-frequency signal, High bandwidth, High-speed signal transmission.

Abstract

With the continuous advancement of the communications field and the constant updates and iterations of communication technologies, the development of 5G communication technology has accelerated the speed at which people can access information. Integrated circuits capable of ultra-high-speed signal transmission form the foundation for the reliable delivery of information, yet they also present a significant challenge. The high bandwidth and other factors in integrated circuits ensure high-speed, low-latency, and highly stable transmission of high-frequency signals. This study is based on existing communication module integrated circuits, summarizing the characteristics of high-frequency signal transmission within integrated circuits and the advantages of transmitting signals through wide-bandwidth integrated circuits. Communication module integrated circuits suffer from drawbacks such as low integration levels and significant signal transmission losses in the manufacturing technique. Additionally, they exhibit disadvantages in high-frequency signal transmission, including susceptibility to obstruction and interference, slow transmission speeds, and insufficient spectrum resources. To address these shortcomings, methods such as employing chemical plating technology, optimizing transimpedance amplifier chips, and designing impedance-matched self-calibration circuits have been proposed to enhance the bandwidth of integrated circuits and improve their capability to transmit high-frequency signals. Thereby optimizing the performance of integrated circuits. The research findings will accelerate data processing in integrated circuits and enhance communication speeds. Meanwhile, provide insights for the future realization of 6G and satellite communication technologies.

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