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Autori principali: Zheng, Yong, Han, Zhen, Wang, LiHeng, Zhang, Pu, Jiang, YongHeng, Xiao, HuiFu, Zhou, XuDong, Yuan, Mingrui, Low, Mei Xian, Dubey, Aditya, Nguyen, Thach Giang, Boes, Andreas, Hao, Qinfen, Ren, Guanghui, Mitchell, Arnan, Tian, Yonghui
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.07817
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author Zheng, Yong
Han, Zhen
Wang, LiHeng
Zhang, Pu
Jiang, YongHeng
Xiao, HuiFu
Zhou, XuDong
Yuan, Mingrui
Low, Mei Xian
Dubey, Aditya
Nguyen, Thach Giang
Boes, Andreas
Hao, Qinfen
Ren, Guanghui
Mitchell, Arnan
Tian, Yonghui
author_facet Zheng, Yong
Han, Zhen
Wang, LiHeng
Zhang, Pu
Jiang, YongHeng
Xiao, HuiFu
Zhou, XuDong
Yuan, Mingrui
Low, Mei Xian
Dubey, Aditya
Nguyen, Thach Giang
Boes, Andreas
Hao, Qinfen
Ren, Guanghui
Mitchell, Arnan
Tian, Yonghui
contents Research on microwave signal measurement techniques is risen, driven by the expanding urgent demands of wireless communication, global positioning systems, remote sensing and 6G networks. In stark contrast with traditional electronic-based realization, the implementations of microwave signal measurement systems based on integrated compact photonic chip have exhibited distinct advantages in high operation bandwidth, light weight, and strong immunity to electromagnetic interference. However, although numerous integrated microwave photonic signal measurement systems have been reported, measurement bandwidth of the majority of them is still below 30 GHz due to the bandwidth limitation of electro-optical modulators (EOMs). Furthermore, previous studies often are more focused on the measurement of one single parameter (typically the frequency) of microwave signals, which has hindered their practical application in complex situations. Here, an integrated photonic microwave multi-parameter measurement system composed of microwave frequency measurement module and microwave phase amplitude measurement module based on thin-film lithium niobate (TFLN) platform is reported. Utilizing this system, not only the ultra-high bandwidth (up to 60GHz) of microwave frequency, phase and amplitude measurement with low root-mean-squares errors (450MHz, 3.43° and 1.64% of the measurement for frequency, phase and amplitude, respectively), but also the time-domain reconstruction of sinusoidal microwave signals is achieved. This demonstration further broadens the application of integrated TFLN photonic devices in microwave signal measurement technology to address the bandwidth bottleneck of the ever-growing microwave networks in the future information society.
format Preprint
id arxiv_https___arxiv_org_abs_2409_07817
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Ultra-wideband integrated microwave photonic multi-parameter measurement system on thin-film lithium niobate
Zheng, Yong
Han, Zhen
Wang, LiHeng
Zhang, Pu
Jiang, YongHeng
Xiao, HuiFu
Zhou, XuDong
Yuan, Mingrui
Low, Mei Xian
Dubey, Aditya
Nguyen, Thach Giang
Boes, Andreas
Hao, Qinfen
Ren, Guanghui
Mitchell, Arnan
Tian, Yonghui
Optics
Applied Physics
Research on microwave signal measurement techniques is risen, driven by the expanding urgent demands of wireless communication, global positioning systems, remote sensing and 6G networks. In stark contrast with traditional electronic-based realization, the implementations of microwave signal measurement systems based on integrated compact photonic chip have exhibited distinct advantages in high operation bandwidth, light weight, and strong immunity to electromagnetic interference. However, although numerous integrated microwave photonic signal measurement systems have been reported, measurement bandwidth of the majority of them is still below 30 GHz due to the bandwidth limitation of electro-optical modulators (EOMs). Furthermore, previous studies often are more focused on the measurement of one single parameter (typically the frequency) of microwave signals, which has hindered their practical application in complex situations. Here, an integrated photonic microwave multi-parameter measurement system composed of microwave frequency measurement module and microwave phase amplitude measurement module based on thin-film lithium niobate (TFLN) platform is reported. Utilizing this system, not only the ultra-high bandwidth (up to 60GHz) of microwave frequency, phase and amplitude measurement with low root-mean-squares errors (450MHz, 3.43° and 1.64% of the measurement for frequency, phase and amplitude, respectively), but also the time-domain reconstruction of sinusoidal microwave signals is achieved. This demonstration further broadens the application of integrated TFLN photonic devices in microwave signal measurement technology to address the bandwidth bottleneck of the ever-growing microwave networks in the future information society.
title Ultra-wideband integrated microwave photonic multi-parameter measurement system on thin-film lithium niobate
topic Optics
Applied Physics
url https://arxiv.org/abs/2409.07817