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Your search keyword '"Nguyen, Thach Giang"' showing total 19 results
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19 results on '"Nguyen, Thach Giang"'

1. Ultra-wideband integrated microwave photonic multi-parameter measurement system on thin-film lithium niobate

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, and Tian, Yonghui

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

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{\deg} 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., Comment: 23 pages,3 figures

Published
2024

2. Integrated Ultra‐Wideband Dynamic Microwave Frequency Identification System in Lithium Niobate on Insulator.

Author

Wang, LiHeng, Han, Zhen, Zheng, Yong, Zhang, Pu, Jiang, YongHeng, Xiao, HuiFu, Wang, BinJie, Low, Mei Xian, Dubey, Aditya, Nguyen, Thach Giang, Boes, Andreas, Ren, Guanghui, Li, Ming, Mitchell, Arnan, and Tian, Yonghui

Subjects
LITHIUM niobate, MILLIMETER waves, MICROWAVE photonics, TELECOMMUNICATION satellites, ELECTROMAGNETIC interference
Abstract

The capability to identify the frequency of unknown microwave signals with an ultra‐wide measurement bandwidth is highly desirable in radar astronomy, satellite communication, and 6G networks. Compared to electronic solutions, the integrated photonic technology‐enabled dynamic instantaneous frequency measurement (DIFM) approach is attractive as it offers unique advantages, such as ultra‐wide frequency measurement bandwidth, high flexibility, and immunity to electromagnetic interference. However, so far the bandwidth of the reported DIFM systems based on integrated photonic technology is limited to below 30 GHz due to the finite bandwidth of electro‐optical modulators (EOMs), limiting their applications, particularly in the field of millimeter wave technology (30–300 GHz). Here, the first integrated dynamic microwave instantaneous frequency measurement system with a record‐breaking operation bandwidth (ranging from 5 to 65 GHz) and low root‐mean‐square (RMS) error (≈300 MHz) is presented on the lithium niobate on insulator (LNOI) integrated photonic platform. This demonstration paves the way for high‐performance millimeter wave photonic integrated devices using the LNOI platform. [ABSTRACT FROM AUTHOR]

Published
2024
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3. Photonic Metamaterial‐Inspired Polarization Manipulating Devices on Etchless Thin Film Lithium Niobate Platform.

Author

Liao, Hongtao, Chen, Li, Zhou, Xudong, Guo, Siyuan, Jiang, Yongheng, Xiao, Huifu, Low, Mei Xian, Nguyen, Thach Giang, Boes, Andreas, Ren, Guanghui, Mitchell, Arnan, and Tian, Yonghui

Subjects
THIN film devices, LITHIUM niobate, SILICON nitride, NONLINEAR optics, INTEGRATED circuits, METAMATERIALS
Abstract

Photonic metamaterials interact with light at the micro–nano scale, enabling unprecedented optical manipulation capabilities, which play a key role in nonlinear optics, spin optics, negative index, and zero index materials. Recently, thin‐film lithium niobate on insulator (LNOI) has emerged as a promising platform for integrated photonics due to its unique material properties, including an excellent electro–optic effect, wide transparency window, and low waveguide losses. Metamaterial structures are promising for constructing novel integrated photonic circuit building blocks on LNOI as they can provide advantageous circuit functionality. In this work, as a proof of concept, high‐performance polarization manipulating devices including polarization splitter rotator (PSR), polarization rotator (PR), and polarizer are demonstrated using photonic metamaterials on the etchless LNOI platform by introducing a silicon nitride layer on the top of LNOI wafer as the loading material. In this way, full advantage of lithium niobate (LN) can be taken to achieve various high‐performance integrated photonic devices, while avoiding the etching of LN and simplifying the fabrication process greatly, which can bring bright prospects for achieving large‐scale lithium niobate integrated photonic circuits. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Multimode Waveguide Bends in Lithium Niobate on Insulator

Author

Ma, Mingyang, primary, Yuan, Mingrui, additional, Zhou, Xudong, additional, Xiao, Huifu, additional, Cao, Pengfei, additional, Cheng, Lin, additional, Nguyen, Thach Giang, additional, Boes, Andreas, additional, Ren, Guanghui, additional, Su, Yikai, additional, Mitchell, Arnan, additional, and Tian, Yonghui, additional

Published
2023
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9. High-Speed Optical Mode Switch in Lithium Niobate on Insulator

Author

Jiang, Yongheng, primary, Han, Xu, additional, Li, Yiyang, additional, Xiao, Huifu, additional, Huang, Haijin, additional, Zhang, Pu, additional, Dubey, Aditya, additional, Yuan, Mingrui, additional, Nguyen, Thach Giang, additional, Boes, Andreas, additional, Li, Yingtao, additional, Ren, Guanghui, additional, Xue, Jiuzhi, additional, Hao, Qinfen, additional, Su, Yikai, additional, Mitchell, Arnan, additional, and Tian, Yonghui, additional

Published
2023
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11. Monolithic Photonic Integrated Circuit Based on Silicon Nitride and Lithium Niobate on Insulator Hybrid Platform

Author

Jiang, Yongheng, primary, Han, Xu, additional, Huang, Haijin, additional, Zhang, Pu, additional, Dubey, Aditya, additional, Xiao, Huifu, additional, Yuan, Mingrui, additional, Frigg, Andreas, additional, Nguyen, Thach Giang, additional, Boes, Andreas, additional, Li, Yingtao, additional, Ren, Guanghui, additional, Su, Yikai, additional, Mitchell, Arnan, additional, and Tian, Yonghui, additional

Published
2022
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12. Integrated Subwavelength Gratings on a Lithium Niobate on Insulator Platform for Mode and Polarization Manipulation (Laser Photonics Rev. 16(7)/2022)

Author

Han, Xu, primary, Chen, Li, additional, Jiang, Yongheng, additional, Frigg, Andreas, additional, Xiao, Huifu, additional, Nguyen, Thach Giang, additional, Boes, Andreas, additional, Yang, Jianhong, additional, Ren, Guanghui, additional, Su, Yikai, additional, Mitchell, Arnan, additional, and Tian, Yonghui, additional

Published
2022
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13. Mode and Polarization‐Division Multiplexing Based on Silicon Nitride Loaded Lithium Niobate on Insulator Platform (Laser Photonics Rev. 16(1)/2022)

Author

Han, Xu, primary, Jiang, Yongheng, additional, Frigg, Andreas, additional, Xiao, Huifu, additional, Zhang, Pu, additional, Nguyen, Thach Giang, additional, Boes, Andreas, additional, Yang, Jianhong, additional, Ren, Guanghui, additional, Su, Yikai, additional, Mitchell, Arnan, additional, and Tian, Yonghui, additional

Published
2022
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19. Integrated lithium niobate polarization beam splitter based on a photonic-crystal-assisted multimode interference coupler.

Author

Yuan M, Han X, Xiao H, Nguyen TG, Boes A, Ren G, Hao Q, Xue J, Mitchell A, and Tian Y

Abstract

Lithium niobate on insulator (LNOI) is a promising platform for high-speed photonic integrated circuits (PICs) that are used for communication systems due to the excellent electro-optic properties of lithium niobate (LN). In such circuits, the high-speed electro-optical modulators and switches need to be integrated with passive circuit components that are used for routing the optical signals. Polarization beam splitters (PBSs) are one of the fundamental passive circuit components for high-speed PICs that can be used to (de)multiplex two orthogonal polarization optical modes, enabling on-chip polarization division multiplexing (PDM) systems, which are suitable for enhancing the data capacity of PICs. In this Letter, we design and experimentally demonstrate a high-performance PBS constructed by a photonic crystal (PC)-assisted multimode interference (MMI) coupler. The measured polarization extinction ratio (ER) of the fabricated device is 15 dB in the wavelength range from 1525 to 1565 nm, which makes them suitable for the high-speed and large data capacity PICs required for future communication systems.

Published
2023
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