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姓 名: 池灏毕业院校: 浙江大学 职 称: 教授 部 门: 通信工程学院 研究方向: 无线与光子融合通信、微波光子学
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姓 名: 池灏毕业院校: 浙江大学 职 称: 教授 部 门: 通信工程学院 研究方向: 无线与光子融合通信、微波光子学
职 务:
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联系电话: 传 真: 办公地点: 下沙校区一教300D 通讯地址: 杭州下沙 电子邮箱: chihao@hdu.edu.cn |
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个人简介 池灏,男,博士、教授、博士生导师。2001年毕业于浙江大学并获得博士学位。2003年至2018年在浙江大学信息与电子工程学院任教,2008年晋升为教授,2010年任博士生导师。2018年11月起在杭州电子科技大学通信工程学院从事教学科研工作。2010年受教育部新世纪优秀人才计划资助,2012年被评为浙江省151人才工程第二层次资助对象。2020年至2024年,连续五年入选美国斯坦福大学与荷兰爱思唯尔联合发布的“全球前2%顶尖科学家榜单”的 “单年度科学影响力榜单”(Single-year impact)和“职业生涯科学影响力榜单”(Career-long impact)两个排行榜。 主要从事光通信与光网络、无线与光子融合通信、微波光子信号处理等领域的研究工作。先后主持包括国家自然科学基金、国防重点课题、省基金重点项目在内的多项国家级和省部级项目以及若干企业委托课题。作为第一作者、通信作者和共同作者在Optics Letters、Journal of Lightwave of Technology、IEEE Transactions on Microwave Theory and Techniques、Optics Express等国际一流期刊论文发表SCI期刊论文一百余篇,目前的论文总引用超过6500次,H-index为47(据GoogleScholar)。授权发明专利十余项。 他目前是IEEE高级会员、IEEE Photonics Technology Letters副主编浙江省通信学会高级会员。
通信地址:杭州下沙杭州电子科技大学通信工程学院
Google scholar page:Link
工作研究领域 无线与光子融合通信、微波光子信号处理、光通信与光网络,如果你有志于在上述领域攻读研究生(硕士、博士或直博),并有良好的数理和专业基础,请与我电邮联系。 联系方式 电子信箱:chihao (AT) hdu.edu.cn 教育经历
工作经历
2. Bo Yang, Zhipeng Liu, Shuna Yang, and Hao Chi , Stable bias control of Mach-Zehnder modulator for arbitrary optical pulse picking via reference pulse power monitoring, Optics Express, vol. 33, no. 4, pp. 6689-6696, Feb. 2025. 3. Wei Dai, Bo Yang , Shuna Yang, Yanrong Zhai, Jun Ou, and Hao Chi, Photonic compressive sensing of microwave signals with enhanced compression ratio and frequency range via optical pulse random mixing, Optics Letters, vol. 50, no. 2, pp.261-264, Jan. 2025. 4. Haonan Zheng, Shuna Yang , Zhaoyang Qiu, Yiran Gao, Bo Yang, and Hao Chi, Photonic Nyquist folding receiver using optical pulses with discrete pulse position modulation, Optics Express, vol. 33, no. 6, pp. 12699-12708, Mar. 2025.
2024 1. H. Wang, B. Yang , S. Yang, Y. Gao, J. Ou, Y. Zhai, and H. Chi, Simultaneous frequency and angle-of-arrival measurement of microwave signals utilizing the Talbot effect and pulse interference, Optics Communications, Vol. 573, 131047, Dec. 2024 2. S. Yang , X. Qu. B. Yang, and H. Chi, Photonic generation and programmable switching of variable-band chirped waveforms with immunity to power fading, Optics Letters, Vol. 49, No. 18, pp. 5107-5110, 15 Sept. 2024. 3. L. Yin, S. Yang , X. Yang, Y. Yao, B. Yang, and H. Chi, All-optical generation of full-range symmetry-tunable triangular-shaped pulses via wavelength multiplexing, Applied Optics, Vol. 63, No. 24, 20 Aug. 2024. 4. Y. Pan, J. Ou , H. Chi, High-dimensional signal encoding and decoding method based on multi-ring perfect vortex beam, Optics Express, Vol. 32, No. 17, pp. 30800-30812, 12 Aug. 2024. 5. W. Dai, B. Yang , H. Chi, H. He, Y. Zhai, J. Ou, and S. Yang, Wideband spectrum compressive sensing utilizing photonic multi-coset sampling with dual low-rate optical pulses, Applied Optics, Vol. 63, No. 18, pp. 4914-4915, 20 June 2024. 6. T. Zhang, Y. Li , B. Yang, W. Pan, L. Yan, H. Chi, X. Zou, Photonic-Assisted Multi-Antenna Frequency-Spatial Compressed Sensing Array for Joint Frequency and DOA Estimation, Journal of Lightwave Technology, vol. 42, no. 21, pp. 7678-7685, 1 Nov., 2024. 7. X. Qin, S. Yang , and H. Chi, Photonic generation and transmission of dual-band double-TBWP chirped microwave waveforms with frequency multiplication and immunity to dispersion-induced power fading, Journal of Modern Optics, Vol. 71, No. 4–6, pp.194–203, 17 Sept. 2024. 8. Xu Qin, Shuna Yang , Hongxia He, Bo Yang, Hao Chi, Photonic generation and anti-dispersion transmission of the quaternary phase-coded microwave waveforms, Optical Engineering, Vol. 63, No. 3, 038104, 17 Sept. 2024. 9. B. Yang, B. Bai, H. Chi , S. Yang, Y. Gao, and H. He, Harmonic active mode-locking optoelectronic oscillator with suppressed supermode noise based on pulse intensity feedback, Optics Letters, Vol. 49, No. 5, pp. 1265-1268,1265-1268, 1 March, 2024. 10. B. Yang, J. Sun, H. Chi , K. Xu, S. Yang, Joint radar and communication system based on a chaotic optoelectronic oscillator, Optics Communications, Vol. 554, 130123, 1 March, 2024. 11. X. Cai, S. Yang, B. Yang, Y. Zhai, T. Jin, and H. Chi , Scalable photonic reservoir computing based on pulse propagation in parallel passive dispersive links, Applied Optics, Vol. 63, No. 22, pp.5785-5791, Aug. 2024. 12. X. Zhang, S. Yang , B. Yang, Y. Gao, H. He, and H. Chi , Simultaneous Measurement of AOA and Frequency based on Stimulated Brillouin Scattering and Frequency-to-Time Mapping, Journal of Lightwave Technology, Vol. 42, No. 16, pp.5606-5615, Aug. 2024. 13. Y. Wang, S. Yang, B. Yang, H. Chi , Photonic architecture for remote multi-parameter measurement and transmission of microwave signals, Optics Express, Vol. 32, No. 10, pp. 18033-18043, 6 May 2024. 14. Y. Qiu, S. Yang, B. Yang, H. Chi , Optical computation of discrete Fourier transform utilizing the temporal Talbot effect with input pulse trains of finite duration, Optical Review, Vol.31, pp. 383-394, May, 2024. 15. 杨波、赵雷、杨淑娜、池灏,基于分数阶Talbot效应的宽带射频信号实时频谱分析,光子学报,Vol. 53, No. 4, 0406006, April 2004. 16. R. Li, S. Yang, B. Yang, Y. Gao, H. He, and H. Chi , Instantaneous frequency measurement based on photonic compressive sensing with sub-Nyquist pseudo-random binary sequences, Optics Letters, Vol. 49, No. 7, pp. 1832-1835, April 2024.
2023 1. C. Huang, H. Chi , S. Yang, B. Yang, Y. Zhai, and J. Ou, Photonic generation of dual-mode multi-format chirp microwave signals, Applied Optics, Vol. 62, No. 31, pp. 8224-8228, Nov. 2023. 2. X. Zhang, H. Chi , Y. Gao, H. He, and Y. Zhai, Photonic angle-of-arrival measurement of microwave signals using a triangular wave, Optics Letters, Vol. 48, No. 19, pp. 5013-5016, Oct. 2023. 3. G. Lyu, H. Chi, S. Yang , and B. Yang, All-optical digital-to-analog conversion based on time-domain pulse spectrum encoding, Optical Engineering, Vol. 62, No. 6, 06510, June 2023. 4. S. Yang, L. Yin, H. Chi , B. Yang, J. Ou and Y. Zhai, Symmetry-Tunable Full-Duty Triangular-Shaped Waveform Generation Using a Simple Single-Drive Mach-Zehnder Modulator, IEEE Photonics Journal, vol. 15, no. 3, Art no. 5500906, pp. 1-6, June 2023. 5. J. Ou , Z. Yin, H. Chi , Q. Li, B. Yang, S. Yang, Y. Zhai, Partially coherent anomalous vortex beam in anisotropic turbulence, Optics Communications, Vol. 537, 129411, June 2023. 6. S. Yang, W. Zhu, H. Chi , B. Yang, J. Ou, and Y. Zhai, Photonic generation of dual-band dual-chirp waveforms with anti-dispersion transmission, Applied Optics, Vol. 62, No. 13, pp. 3512-3518, May 2023. 7. B. Yang, Q. Xu, H. Chi , Z. Liu, and S. Yang, Photonic compressive sampling of wideband sparse radio frequency signals with 1-bit quantization, Optics Express, Vol. 31, No. 11, pp.18159-18166,May 2023. 8. B. Yang , Z. Ma, S. Yang, and H. Chi, Broadband and linearized photonic time-stretch analog-to-digital converter based on a compact dual-polarization modulator, Applied Optics, Vol. 62, No. 4, pp.921-926, Feb. 2023. 9. R. Li, H. Chi , B. Yang, S. Yang, and T. Jin, Photonics-assisted compressed sensing of radio frequencies with a rate-doubled bipolar random sequence, Optics Letters, Vol. 48, No. 3, pp.692-695, Feb. 2023 10. Y. Gao, H. Chi, J. Dai , and K. Xu, Ku-band analog photonic down-conversion link with coherent I/Q image rejection and digital linearization, Optics Express, Vol. 31, No. 2, pp. 2135-2146, Jan. 2023. 11. S. Yang, Y. Huai, B. Yang, H. Chi , High-stable and reconfigurable photonic generation of radio-frequency arbitrary waveforms with multi-tone inputs, Optical Engineering, Vol. 62, No.1, 015101, Jan. 2023. 12. J. Dan, T., Jin , H. Chi, S. Dong, and Y. Shen, Uncertainty-guided joint unbalanced optimal transport for unsupervised domain adaptation, Neural Computing and Applications, Vol. 35, No. 7, pp. 5351–5367, March 2023. 13. J. Dan, T. Jin , Hao Chi, Y. Shen, J. Yu, J. Zhou, HOMDA: High-Order Moment-Based Domain Alignment for unsupervised domain adaptation, Knowledge-Based Systems, Volume 261, 110205, Feb. 2023. 14. J. Dan, T. Jin , H. Chi, S. Dong, H. Xie, K. Cao, X. Yang, Trust-aware conditional adversarial domain adaptation with feature norm alignment, Neural Networks, Vol. 168, pp. 518-530, Nov. 2023.
2022 1. Y. Zhang and H. Chi , An Optical Front-End for Wideband Transceivers Based on Photonic Time Compression and Stretch, Photonics, Vol.9, No.6, 658, September, 2022. 2. H. Zhou, R. Li, H. Chi , Optical Signal Sampling Based on Compressive Sensing with Adjustable Compression Ratio, Current Optics and Photonics, Vol. 6, No. 3, 288-296, June 2022. 3. S. Yu, S. Yang, B. Yang, and H. Chi , Photonic Generation of Switchable Dual-Band Dual-Chirp Microwave Waveforms, IEEE Photonics Journal, Vol.14, No.1, art no. 5504305, Feb. 2022. 4. H. Chi, Q. Zhang, S. Yang , B. Yang, Y. Zhai, and J. Ou, Photonic analog-to-digital conversion based on time-to-frequency mapping, Optics Communications, Vol.502, 127440, Jan. 2022. 5. J. Dan, T. Jin , H. Chi, Y. Shen, Uncertainty-guided joint unbalanced optimal transport for unsupervised domain adaptation, Neural Computing and Applications, 1-17, Nov. 2022. 6. B. Yang, J. Yu, H. Chi , S. Yang, Y. Zhai, and J. Ou, Polarization multiplexed active mode-locking optoelectronic oscillator for frequency tunable dual-band microwave pulse signals generation, Optics Express, Vol. 30, No.15 27132-27139, July 2022. 7. S. Yang, J. Wang, B. Yang, H. Chi , J. Ou, Y. Zhai, and Q. Li, A serial digital-to-analog conversion based on photonic time-stretch technology, Optics Communications, Vol. 510, 127949, May 2022. 8. B. Yang, Q. Xu, S. Yang, and H. Chi , Wideband sparse signal acquisition with ultrahigh sampling compression ratio based on continuous-time photonic time stretch and photonic compressive sampling, Applied Optics, Vol.61, No.6, pp.1344-1348, June, 2022. 9. 杨淑娜、许嘉丽、杨鸿珍、赵玉虎、池灏,基于链路失效模型的多级电力业务路由规划,电子与信息学报,Vol.44, No. 11, pp.3788-3795, Nov. 2022.
2021 1. Q. Zhang, H. Chi, Photonic digital-to-analog converter based on spectral encoding, Microwave and Optical Technology Letters, Vol. 63, No. 10, pp. 2670-2674, Oct. 2021. 2. B. Yang, H. Zhao, S. Yang , H. Chi, Wideband Doppler frequency shift measurement and direction discrimination based on optical single sideband modulation with a fixed low-frequency reference signal, Optics Communications, vol. 499, 127306, Nov. 2021 3. H. He, S. Yang, B. Yang, Y. Zhai, T. Jin, and H. Chi , Photonic time-stretch based on phase modulation for sub-octave applications, Applied Optics, Vol.60, No.22, pp.6481-6488, Aug. 2021. 4. H. Chi, C. Wang, and J. P. Yao , Photonic Generation of Wideband Chirped Microwave Waveforms, IEEE Journal of Microwaves, Vol.1, No.3, pp. 787-803, July 2021. (Invited) 5. H. Chi, S. Wang, S. Yang, Y. Zhai , X. Zou, B. Yang, Q. Li, Photonic arbitrary waveform generation based on the temporal Talbot effect, Optics Express, Vol. 29, No. 11, pp. 16927-16938, May 2021. 6. H. Chi, H. Zhou, S. Yang, J. Ou, Y. Zhai, and B. Yang , Compressive sensing based on optical mixing using a spectral shaper with bipolar coding, Optics Express, Vol. 29, No. 11, pp.16422-16431, May 2021 7. C. Yi, S. Yang, B. Yang, T. Jin, and Hao Chi , Photonic approach for generating bandwidth-doubled and switchable multi-format chirp waveforms, Optics Letters, Vol. 46, No. 7, pp.1578-1581, April 2021. 8. S. Yang, J. Wang, H. Chi H, B. Yang , Distortion compensation in continuous-time photonic time-stretched ADC based on redundancy detection. Applied Optics, vol. 60, no. 6, pp.1646-1652, 2021. 9. X. Zhu, T. Jin , Y. Fu, H. Chi, W. Liu, Q. Wang, and P. Feng, A dispersion-free multi-access RF dissemination link with phase jitter compensation. Electronics Letters, Vol.57, No. 1, pp.30-31, Jan. 2021.
2020 1. S. Yang, X. Hu, B. Yang, H. Chi , Resolution-enhanced photonic quantization scheme based on weighted modulation transfer functions of lithium niobate Mach–Zehnder modulators, Applied Optics, Vol. 59, No. 31, pp. 9780-9785, Nov. 2020. 2. B. Yang, H. Zhao, Z. Cao, S. Yang, Y. Zhai, J. Ou, H. Chi , Active mode-locking optoelectronic oscillator, Optics Express, Vol. 28, No. 22, pp. 33220-33227, Oct. 2020. 3. B. Yang, S. Yang, Z. Cao, J. Ou, Y. Zhai, and H. Chi , Photonic compressive sensing of sparse radio frequency signals with a single dual-electrode Mach–Zehnder modulator, Optics Letters, Vol. 45, No. 20, pp. 5708-5711, Oct. 2020. 4. C. Yi, H. Chi , T. Jin, A photonic approach for Doppler frequency shift measurement with dispersion medium, IEEE Photonics Journal, Vol. 12, No. 5, 7102708, Oct. 2020. 5. Shuna Yang, Zhiwei Liu, Hao Chi , Ran Zeng, Bo Yang, A Photonic Digitization Scheme With Enhanced Bit Resolution Based on Hierarchical Quantization, IEEE Access, vol.8, pp. 150242-150247, Aug. 2020. 6. H. Chi, S. Hu, Y. Zhai, B. Yang, Z. Cao, J. Ou, S. Yang, Real-time discrete Fourier transformer with complex-valued outputs based on the inverse temporal Talbot effect, Optics Express, Vol. 287, No. 14, 20543, July 2020. 7. X. Zhu, T. Jin , Y. Fu. H. Chi, et al, A frequency-stable optoelectronic oscillator based on passive phase compensation, IEEE Photonics Technology Letters, Vol. 32, No. 10, pp.612-615, May 2020. 8. H. He, S. Yang, H. Chi , and T. Jin, Photonic serial implementation of a flash analog-to-digital converter, Optics Letters, Vol. 45, No. 7, pp.1643-1646, April 2020. 9. B. Yang, H. He, S. Yang, J. Ou, Y. Zhai, and H. Chi , Analysis on predistortion algorithm for improving adjacent channel leakage ratio of radio over fiber systems, Microwave and Optical Technology Letters, Vo. 62, No. 4, 1483-1488, April 2020. 10. Y. Zhai, H. Chi , J. Tong, J. Xi, Capacity Maximized Linear Precoder Design for Spatial-Multiplexing MIMO VLC Systems, IEEE Access, Vol. 8, pp. 63901- 63909, April 2020. 11. C. Yi, H. Chi , B. Yang, and T. Jin, A PM-based approach for Doppler frequency shift measurement and direction discrimination, Optics Communications, Vol. 458, 124796, March, 2020. 12. B. Yang, H. Chi , S. Yang, Z. Cao, J. Ou, and Y. Zhai, Broadband Microwave Spectrum Sensing Based on Photonic RF Channelization and Compressive Sampling, IEEE Photonics Journal, Vol. 12, No.1, 5500109, Feb. 2020. 13. H. Chi, S. Jiang, J. Ou, and T. Jin, Comprehensive study of orbital angular momentum shift keying systems with a CNN-based image identifier, Optics Communications, Vol. 454, 124518, Jan. 2020. 14. 池灏、张秋林、杨淑娜,基于MZ干涉结构的光子模数转换技术研究进展,杭州电子科技大学学报(自然科学版),pp.1-7, Vol.40, No.1, Jan. 2020.
2019 1. S. Yang, H. He, H. Chi , and R. Zeng, Photonic quantization and encoding scheme with improved bit resolution based on waveform folding, Optics Express, Vol. 27, No. 24, pp. 35565-35573, Dec. 2019. 2. S. Yang, H. Chi , B. Yang, R. Zeng, J. Ou, Y. Zhai, Q. Li, Photonic digitization with differential encoding based on orthogonal vector superposition, IEEE Photonics Journal, Vol. 11, No. 6, 7104509, Dec. 2019. 3. J. Ou, M. Hu, F. Li, R. Zeng, M. Bi, S. Yang, Y. Zhai, H. Chi , Average capacity of wireless optical links using Laguerre-Gaussian beam through non-Kolmogorov turbulence based on generalized modified atmospheric spectral model, Optics Communications, Vol. 452, 487-493, Dec. 2019. 4. X. Zhu, T. Jin, Y. Fu, H. Chi, L. Zuo, W. Liu, and Q. Wang, Stable photonic transmitting link based on passive phase compensation with active-assisted control method, Electronics Letters, Vol. 55, No. 20, pp. 1097-1098, Oct. 2019. 5. H. He, S. Yang, T. Jin, and H. Chi , Photonic quantization using dual-output Mach–Zehnder modulators and balanced photodetectors, Optics Communications, Vol. 446, 72-76, Sept. 2019. 6. H. Chi, J. Xing, S. Yang, and T. Jin, Evolution of Amplitude Fluctuation in Fractional Temporal Talbot Effect, IEEE Access, Vol. 7, 86177, June 2019. 7. X. Zhu, T. Jin, Y. Fu, H. Chi, D. Li, L. Zuo, W. Liu, and Q. Wang, Compensation of dispersion-induced power fading with adjustment-free operation, Optical Engineering, Vol. 58, No. 6, 060504-1-4, June, 2019. 8. S. Jiang, H. Chi , X. Yu, S. Zheng, X. Jin, and X. Zhang, Coherently demodulated orbital angular momentum shift keying system using a CNN-based image identifier as demodulator, Optics Communications, Vol. 435, 367-373, March 2019 9. H. Chi and Z. Zhu, Analytical model for photonic compressive sensing with pulse stretch and compression, IEEE Photonics Journal, vol. 11, no. 1, 5500410, Feb. 2019. 10. X. Zhu, T. Jin, H. Chi, G. Tong, D. Li, L. Zuo, W. Liu and Y. Fu, Photonic down-conversion and linearisation with tunable IF bandwidth and improved spurious-free dynamic range, Electronics Letters, Vol. 55, No. 2, pp. 105-107, Jan. 2019.
2018 1. G. Tong, T. Jin, H. Chi, X. Zhu, T. Lai, D. Li and L. Zuo, Stable radio frequency dissemination in a multi-access link based on passive phase fluctuation cancellation, Optics Communication, vol. 423, pp. 53-56, 2018. 2. X. Zhu, T. Jin, H. Chi, G. Tong, T. Lai, A coherent RF scanning receiver based on a flat optical frequency comb, Optics Communications, vol. 421, pp. 41-45, 2018. 3. X. Zhu, T. Jin, H. Chi, G. Tong, T. Lai, D. Li, Photonic receiving and linearization of RF signals with improved spurious free dynamic range, Optics Communications, vol. 423, pp. 17-20, 2018. 4. X. Zhu, T. Jin, H. Chi, J. Zhou, G. Tong, D. Li, L. Zuo, Y. Fu, Linearization of two cascaded intensity-modulator-based analog photonic link, Optical Engineering, vol. 57, no. 8, pp. 080501(1-4), 2018. 5. J. Xing, C. Wang, H. Chi, X. Yu, S. Zheng, X. Jin, and X. Zhang, Modulation fading in temporal Talbot effect, IEEE Photonics Technology Letters, Vol. 30, No.15, pp. 1376-1379, Aug. 2018. 6. B Xu, C Liu, X Jin, X Jin, H Chi, S Zheng, X Zhang, Time-Division Multiplexed Vector Signal Synthesizer Based on Continuous PTS, IEEE Photonics Technology Letters, vol. 30, no. 11, 1020-1023, June 2018. 7. H. He, H. Chi , X. Yu, T. Jin, S. Zheng, X. Jin, and X. Zhang, An improved photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Communications, Vol. 425, pp.157-160, March 2018. 8. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Yu, X. Jin, and X. Zhang, Photonics-enabled compressive sensing with spectral encoding using an incoherent broadband source, Optics Letters, Vol. 43, No.2, pp. 330-333, Jan. 2018.
2017 1. Y. Xu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, On the undesired frequency chirping in photonic time-stretch systems, Optics Communications, Vol. 405, pp.192-196, Dec. 2017. 2. H. Zhang, S. Wang, S. Jia, X. Yu, X. Jin, S. Zheng, H. Chi, X. Zhang, Experimental Generation of Linearly Chirped 350 GHz band Pulses with beyond 60 GHz Bandwidth, Optics Letters, Vol. 42, No. 24 pp. 5242-5245, 2017 4. S. Yang, M. Hu, H. Chi , Q. Li, Photonic digital-to-analog conversion based on wavelength multiplexing, Optics Communications, Vol. 401, pp.1-5, Oct. 2017. 5. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, All-positive-coefficient microwave photonic filter with rectangular response, Optics Letters, Vol. 42, No. 15, Aug. 2017, pp.3012-3015. 6. G. Tong, T. Jin, H. Chi, X. Zhu, T. Lai and X. Wu, A novel optoelectronic oscillator based on Brillouin-induced slow light effect, IEEE Photonics Technology Letters, Vol.29, No.16, pp.1375-1378, Aug. 2017. 7. Y Xu, T Jin, H Chi , S Zheng, X Jin, X Zhang, Photonic generation of dual-chirp waveforms with improved time bandwidth product, IEEE Photonics Technology Letters, Vol. 29, No.15, pp. 1253-1256, Aug. 2017. 8. Y. Mei, Y. Xu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, Spurious-Free Dynamic Range of the Photonic Time-Stretch System, IEEE Photonics Technology Letters, Vol.29, No.10, pp.794-797, May 2017. 9. R. Fu, X. Jin, Y. Zhu, X. Jin, X. Yu, S. Zheng, H. Chi, and X. Zhang, Frequency stability optimization of an OEO using phase-locked-loop and self-injection-locking, Optics Communications, Vol. 386, pp. 27-30, 2017.
2016 2. G. Tong, T. Jin, H. Chi, J. Zheng, X. Zhu, T. Lai, X. Wu, and Z. Shi, Reducing the noise floor in optoelectronic oscillator by optimizing the operation of modulator, Optical Engineering, Vol.55, No.10, pp.100504-1-4, Oct. 2016. 5. Y. L. Chen, S. Zheng, Y. Li, X. Hui, X. Jin, H. Chi, and X. Zhang, A Flat-Lensed Spiral Phase Plate Based on Phase-Shifting Surface for Generation of Millimeter-Wave OAM Beam, IEEE Antennas and Wireless Propagation Letters, Vol. 15, pp.1156-1158, 2016. 6. X. Hui, S. Zheng, w. Zhang, X. Jin, H. Chi, and X. Zhang, Local topological charge analysis of electromagnetic vortex beam based on empirical mode decomposition, Optics Express, Vol. 24, No.5, pp.5423-5430, March 2016. 7. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, Photonic compressive sensing for analog-to-information conversion with a delay-line based microwave photonic filter, Optics Communications, Vol.371, pp.83-88, July 2016. 8. Y. Chen, Y. Ding, Z. Zhu, H. Chi , S. Zheng, X. Zhang, X. Jin. M. Galili, and X. Yu, Photonic compressive sensing with a micro-ring-resonator-based microwave photonic filter, Optics Communications, Vol.373, pp.65-69, Aug. 2016. 9. C. Xu, S. Zheng, X. Chen, H. Chi, X. Jin, and X. Zhang, Photonic-assisted time-interleaved ADC based on optical delay line, Journal of Optics, Vol.18, No.1, Jan. 2016. 10. Z. Zhang, S. Zheng, Y. Chen, X. Jin, H. Chi, and X. Zhang, The Capacity Gain of Orbital Angular Momentum Based Multiple-Input-Multiple-Output System, Scientific Reports, Vol.6, DOI: 10.1038/srep25418, May 2016.
2015 1. Y. Zhu, J. Zhou, X. Jin, H. Chi, X. Zhang, and S. Zheng, An optoelectronic oscillator‐ased strain sensor with extended measurement range, Microwave and Optical Technology Letters, Vol. 57, pp. 2336-2339, Oct. 2015. 2. Shilie Zheng, Xiaonan Hui, Jiangbo Zhu, Hao Chi, Xiaofeng Jin, Siyuan Yu, and Xianmin Zhang, Orbital angular momentum mode-demultiplexing scheme with partial angular receiving aperture, Optics Express, Vol. 23, No. 9, May 4, 2015, pp. 12251-12257. 3. S. Qu, T. Jin, H. Chi, G. Tong, F. Ren, and X. Zhao, An optoelectronic oscillator using an FBG and an FBG-based Fabry-Perot filter, Optics Communications, Vol. 342, pp.141-143, May 2015 4. X. Zhao, T. Jin, H. Chi, and S. Qu, Modeling and simulation of the background light in underwater imaging under different illumination conditions, Acta, Physica Sinica, Vol.64, No.10, pp.104201, May 2015. In Chinese 5. Xiannan Hui, Shilie Zheng, Yiling Chen, Yiping Hu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Multiplexed millimeter wave communication with dual orbital angular momentum (OAM) mode antennas, Scientific Reports, Vol. 5, 10148, May 19, 2015. 7. Yi Wang, Xiaofeng Jin, Yanhong Zhu, Xianmin Zhang, Shilie Zheng, Hao Chi, A wideband tunable optoelectronic oscillator based on a spectral-subtraction-induced MPF, IEEE Photonics Technology Letters, Vol. 27, No. 9, May 1, 2015, pp. 947-950. 8. Xiaonan Hui, Shilie Zheng, Yiping Hu, Chen Xu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Ultralow reflectivity spiral phase plate for generation of millimeter-wave OAM beam, IEEE Antennas and Wireless Propagation Letters, Vol. 14, April 2015, pp. 966-969. 9. Shilie Zheng, Xiaonan Hui, Xiaofeng Jin, and Hao Chi, and Xianmin Zhang, Transmission characteristics of a twisted radio wave based on circular traveling-wave antenna, IEEE Transactions on Antennas and Propagation, Vol. 63, No. 4, April 2015, pp. 1530-1536. 11. Y. Chen, X. Yu, H. Chi , S. Zheng, X. Zhang, X. Jin, and M. Galili, Compressive sensing with a microwave photonic filter, Optics Communications, Vol. 338, pp.428-432, March 2015
2014 1. X. Hui, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Hilbert-Huang Transform Time-Frequency Analysis in phi-OTDR Distributed Sensor, IEEE Photonics Technology Letters, Vol. 26, No. 23, pp. 2403-2406, Dec. 2014. 3. X. Hui, T. Ye, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Space-frequency analysis with parallel computing in a phase-sensitive optical time-domain reflectometer distributed sensor, Applied Optics, Vol. 53, No. 28, pp. 6586-6590, Oct. 2014. 4. Y. Zhu, X. Jin, H. Chi, S. Zheng, and X. Zhang, High-sensitivity temperature sensor based on an optoelectronic oscillator, Applied Optics, Vol. 53, Vol. 22, pp.5084-5087, Aug. 2014. 5. Y. Pan, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Analyses of Whispering Gallery Modes in Circular Resonators by Transmission Line Theory, IEEE/OSA Journal of Lightwave Technology, Vol.32, No. 13, pp.2345-2352, July 2014 7. Y. Chen, X. Yu. H. Chi , X. Jin, X. Zhang, S. Zheng, and M. Galili, Compressive sensing in a photonic link with optical integration, Optics Letters, Vol.39, No.8, pp. 2222-2224, April 2014. 8. Y. Mei, Y. Xu, H. Chi , X. Zhang, X. Jin, S. Zheng, and T. Jin, Photonic generation of chirped microwave signals with high time-bandwidth product, Optics Communications, Vol.316, pp106-110, April 2014.
2013 1. Y. Chen, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Sub-Nyquist Sampled Analog-to-Digital Conversion Based on Photonic Time Stretch and Compressive Sensing With Optical Random Mixing, Journal of Lightwave Technology, No.31, No.21, pp.3395-3401, Nov. 2013. 2. B. Yang, X. Jin, Y. Chen, H. Chi, X. Zhang, S. Zheng, E. Tangdiongga, T. Koonen, Photonic Microwave Up-Conversion of Vector Signals Based on an Optoelectronic Oscillator, IEEE Photonics Technology Letters, Vol.25, No.18, pp.1758-1761, Sept. 2013. 3. F. Zhou, X. Jin, B. Yang, J. Zhou, X. Zhou, S. Zheng, and H. Chi, Photonic generation of frequency quadrupling signal for millimeter-wave communication, Optics Communications, Vol.304, pp.71-74, Sept. 2013. 4. Y. Wang, X. Jin, H. Chi, X. Zhang, and S. Zheng, Tunable multi-tap microwave photonic filter with complex coefficients using a dual-parallel Mach-Zehnder modulator, Journal of Modern Optics, Vol.60, No.13, pp.1069-1073, July 2013. 5. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang, All-optical modulator with long range surface plasmon resonance, Optics and Laser Technology, Vol.49, pp.316-319, July 2013. 6. Bo Yang, Xiaofeng Jin, Ying Chen, Jinhai Zhou, Xianmin Zhang, Shilie Zheng, Hao Chi, A Tunable Optoelectronic Oscillator Based on a Dispersion-Induced Microwave Photonic Filter, IEEE Photonics Technology Letters, Vol.25, No.10, pp.921-924, May 2013. 7. Ying Chen, Bo Yang, Hao Chi, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Photonic instantaneous frequency measurement with digital output based on dispersion induced power fading functions, Optics Communications, Vol.292, No.1, pp. 53–56, April 2013. 8. Y. Qiao, M. Pan, S. Zheng, H. Chi, X. Jin, and X. Zhang, An electrically tunable frequency-doubling optoelectronic oscillator with operation based on stimulated Brillouin scattering, Journal of Optics, Vol.15, No.3, March 2013. 9. Hao Chi, Ying Chen, Yuan Mei, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Microwave spectrum sensing based on photonic time stretch and compressive sampling, Optics Letters, Vol. 38, No. 2, pp.136-138, Jan. 2013.
2012 1. Ying Chen, Hao Chi, Shilie Zheng, Xiaofeng Jin, Xianmin Zhang Photonic analog-to-digital converter based on the robust symmetrical number system, Optics Communications, Vol.285, No.24, pp. 4966–4970, Nov. 2012. 2. Xiaofeng Jin, Jinhai Ou, Ran Hao, Feng Zhou, Xianmin Zhang, Shilie Zheng, Hao Chi, Novel Demodulation Method for Fiber-Optic Interferometers Based on pi/2 Phase Modulation, IEEE Photonics Technology Letters, Vol.24, No.22, pp.1981-1983, Nov. 2012. 3. Hao Chi, Yuan Mei, Ying Chen, Donghui Wang, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Microwave spectral analysis based on photonic compressive sampling with random demodulation, Optics Letters, Vol. 37, No. 22, pp.4636-4638, Nov. 2012. 4. Y. Wang, X. Jin, K. Xu, J. Ou, H. Chi, X. Zhang, and S. Zheng, Four-tap microwave photonic filter with tunable center frequency and reconfigurable transfer function, Microwave and Optical Technology Letters, Vol.54, No.7, pp.1740-1743, July 2012. 5. S. Zheng, S. Ge, X. Zhang, H. Chi, and X. Jin, High-resolution multiple microwave frequency measurement based on stimulated Brillouin scattering, IEEE Photonics Technology Letters, Vol.24, Vol.13, pp.1115-1117, July 2012. 6. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang , All-optical modulator with long range surface Plasmon resonance, Optics & Laser Technology, Vol.44, No.5, pp.1442-1445, July 2012. 7. B. Yang, X. Jin, H. Chi, X. Zhang, and S. Zheng, Optically tunable frequency-doubling optoelectronic oscillator with carrier phase-shifted double sideband modulation, IEEE Photonics Technology Letters, Vol.24, No.12, pp.1051-1053, June 2012. 8. Z. Li, Y. Han, H. Chi, X. Zhang, and J. P. Yao, A continuously tunable microwave fractional Hibert transformer based on a nonuniformly spaced photonic microwave delay-line filter, Journal of Lightwave Technology, Vol.30, No.12, pp.1948-1953, June 2012. 9. Z. Li, X. Zhang , H. Chi, S. Zheng, X. Jin, and J. P. Yao, A reconfigurable microwave photonic channelized receiver based on dense wavelength division multiplexing using an optical comb, Optics Communications, Vol.285, No.9, pp.2311-2315, May 2012. 10. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang, Refractive index sensor based on tilted fiber Bragg grating and stimulated Brillouin scattering, Optics Express, Vol.20, No.10, pp.10853-10858, May 2012. 11. W. Kang, S. Zheng, X. Zhang, X. Jin, H. Chi, and Y. Zou, Quadratic electro-optic properties of Pb(Mg1/3Nb2/3)O-3-PbTiO3 transparent ceramics under both DC and AC bias, Applied Optics, Vol.51, No.15, pp.2870-2876, May 2012. 12. H. Shao, W. Chen, Y. Zhao, H. Chi, J. Yang, and X. Jiang, Performance evaluation of photonic UWB generation based on silicon MZM, Optics Express, Vol.20, No.7, pp.7398-7403, Mar. 2012. 13. B. Yang, X. Jin, X. Zhang, S. Zheng, H. Chi, Y. Wang, A Wideband Frequency-Tunable Optoelectronic Oscillator based on a Narrowband Phase-Shifted FBG and Wavelength tuning of Laser, IEEE Photonics Technology Letters,Vol.24, No.1, pp.73-75, Jan. 2012.
2011 1. Ying Chen, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Differentially- Encoded Photonic Analog-to-Digital Conversion based on Phase Modulation and Interferometric Demodulation, IEEE Photonics Technology Letters, Vol.23, No.24, pp. 1890-1892, Dec. 2011. 2. Z. Li, M. Li, H. Chi, X. Zhang, and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal With Large Frequency Tunability Using a Polarization-Maintaining Fiber Bragg Grating, IEEE Microwave and Wireless Components Letters, Vol.21, No.12, pp.694-696, Dec. 2011. 3. X. L. Shi, S. L. Zheng, H. Chi, X. F. Jin, and X. M. Zhang, A wideband electro-optic modulator based on long range surface plasmon resonances, Journal of Optics, Vol.13, No.12, pp.1-5, Dec. 2011. 4. Z. Li, H. Chi, X. Zhang, and J. P. Yao, A Continuously Tunable Microwave Fractional Hilbert Transformer Based on a Photonic Microwave Delay-Line Filter Using a Polarization Modulator, IEEE Photonics Technology Letters, Vol.23, No.22, pp.1694-1696, Nov. 2011. 5. Yun Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic approach for microwave spectral analysis based on Fourier cosine transform, Optics Letters, vol. 36, no.19, pp.3897-3899, Oct. 2011. 6. Yun Wang, Juan Ni, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic Instantaneous Microwave Frequency Measurement Based on Two Different Phase Modulation to Intensity Modulation Conversions, Optics Communications, vol.284, no.16-17, pp.3928-3932, Aug. 2011. 7. L. Liu, Y. Shen, S. Zheng, X. Jin, H. Chi, and X. Zhang, Optical generation of microwave/millimetre-wave based on Brillouin-erbium fiber laser, Microwave and Optical Technology Letters, vol.53, no.8, pp.1761-1763, Aug. 2011. 8. H. Chi, Z. Li, X. Zhang, S. Zheng, X. Jin, and J. P. Yao, Proposal for photonic quantization with differential encoding using a phase modulator and delay-line interferometers, Optics Letters, vol.36, no.9, pp.1629-1631, May 2011. 9. Z. Li, W. Li, H. Chi, X. Zhang, and J. P. Yao, Photonic generation of phase-coded microwave signal with large frequency tunability, IEEE Photonics Technology Letters, vol. 23, no.11, pp.712-714, June 2011. 10. Z. Li, H. Chi, X. Zhang, J. P. Yao, Optical single-sideband modulation using a fiber-Bragg-grating-based optical Hilbert transformer, IEEE Photonics Technology Letters, vol.23, no.9, pp.558-560, May 2011. 11. J. Ni, X. M. Zhang, S. L. Zheng, X.F.Jin, H.Chi, and X. M. Zhang, Microwave frequency measurement based on phase modulation to intensity modulation conversion using fiber Bragg grating, Journal of Electromagnetic Waves and Applications, vol.25, no.5-6, pp.755-764, May 2011. 12. Z. Li, C. Wang, M. Li, H. Chi, X. Zhang, and J. P. Yao, Instantaneous microwave frequency measurement using a special fiber Bragg grating, IEEE Microwave and Wireless Components Letters, vol.21, no.1, pp.52-54, Jan. 2011.
2010 1. Lan Liu, Shilie Zheng, Jun Ji, Minghui Guo, Xianmin Zhang, Xiaofeng Jin, Hao Chi, and Yingyin Kevin Zou, Tunable frequency equalization using variable optical tilt filter in radio-over-fiber links, Microwave and Optical Technology Letters, Vol. 52, No. 11, pp.2456-2459, November 2010. 2. Z. Li, H. Chi, X. Zhang, and J. P. Yao, Pulse distortions due to third-order dispersion and dispersion mismatches in a phase-modulator-based temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology,Vol.28, No.19, pp.2865-2872, Oct. 2010. 3. Yubin Ji, Shilie Zheng, Ze Li, Xiaofeng Jin, Xianmin Zhang, and Hao Chi, Tunable fiber fabry-perot filter for PM-IM conversion and efficiency improvement in radio-over-fiber links, Microwave and Optical Technology Letters, Vol.52, No.9, pp.2090-2095, Sept. 2010. 4. Jun Ji, Shilie Zheng, Xiaofeng Jin, Xianmin Zhang, Hao Chi, and Yingyin Kevin Zou, Optical variable gain tilt filter with temperature compensation, Microwave and Optical Technology Letters, Vol.52, No.8, pp.1906-1909, Aug.2010. 5. Bo Yang, Xiao-Feng Jin, Xian-Min Zhang, Hao Chi, Shi Lie Zheng,Photonic generation of 60 GHz millimeter-wave by frequency quadrupling based on a mode-locking SOA fiber ring laser with a low modulation depth MZM, Journal of Electromagnetic Waves and Applications, Vol. 24, No. 13, pp.1773-1782, Aug. 2010. 6. Lan Liu, Shilie Zheng, Xianmin Zhang, Xiaofeng Jin, and Hao Chi, Performances improvement in raido over fiber link through carrier suppression using stimulated Brillouin scattering, Optics Express, Vol.18, No.11, pp.11827-11837, May 2010. 7. J. Ni, B. Chen, S. L. Zheng, X. M. Zhang, X. F. Jin, and H. Chi, Ultra-wideband bandpass filter with notched band based on electrooptic phase modulator and phase-shift fiber Bragg grating, Journal of Electromagnetic Waves and Application, Vol.24, No.5-6, pp.795-802, June 2010. 8. Ze Li, Bo Yang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, Photonic instantaneous measurement of microwave frequency using fiber Bragg grating, Optics Communications, Vol.283, No.3, pp.396-399, Feb. 2010. 9. Fei Zhang, Xiaofeng Jin, Xianmin Zhang, Shilie Zheng, Hao Chi, Yingyin Kevin Zou, and Jianping Yao, Fibre-optic comb filter with tunable central wavelength and channel islation at sub-microsecond speed, Electronics Letters, Vol.46, No.1, pp.71-72, Jan. 2010. 10. L. Liu, S. L. Zheng, X. M. Zhang, X. F. Jin, and H. Chi, Performance improvement of phase modulation with interferometeric detection through low-biasing, Journal of Electromagnetic Waves and Applications, Vol.24, No.1, pp.123-132, Jan. 2010.
2009 1. Shuna Yang, Chao Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin and Jianping Yao, Photonic analog-to-digital converter using Mach-Zehnder modulators having identical half-wave voltages with improved bit resolution, Applied Optics, Vol.48, No.22, pp.4458-4467, Aug. 2009. 2. Xiaomin Zhang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, and Jianping Yao, Instantaneous Microwave Frequency Measurement Using an Optical Phase Modulator, IEEE Microwave and Wireless Components Letters, Vol.19, No.6, pp.422-424, June 2009. 3. X. Zou, H. Chi, and J. P. Yao, Microwave frequency measurement based on optical power monitoring using a complementary optical filter pair, IEEE Transactions on Microwave Theory and Techniques, Vol.57, No.2, pp.505-511, Feb. 2009. 4. H. Chi, X. Zou and J. P. Yao, Analytical models for phase-modulation-based microwave photonic systems with phase modulation to intensity modulation conversion using a dispersive device, IEEE/OSA Journal of Lightwave Technology, Vol.27, No.5, pp.511-521, March 2009. 5. B. Chen, S. L. Zheng, X. M. Zhang, X. M. Zhang, X. F. Jin, and H. Chi, Simultaneously realizing PM-IM conversion and efficiency improvement of fiber-optic links using FBG, Journal of Electromagnetic Waves and Applications, Vol.23, No.2-3 , pp.161-170, 2009. 6. Shuna Yang, Zhigu Shi, Hao Chi; Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, and Jianping Yao, Photonic Analog-to-Digital Conversion using Multiple Comparators and Mach-Zehnder Modulators with Identical Half-Wave Voltage, Optics Communications, Vol.282, No.4, pp.504-507, Feb. 2009. 7. Yang Liu, Hao Chi, Xianmin Zhang, Xiaofeng Jin, and Shilie Zheng, A Novel Control Scheme for 4-Plate Retardation Polarization Controller, Microwave and Optical Technology Letters, Vol.51, No.1, pp.124-128, Jan. 2009.
2008 1. X. M. Zhang, S. L. Zheng, L. Liu, X. M. Liu, X. M. Zhang, X. F. Jin and H. Chi, Flattened frequency response using fiber Bragg grating V-shape filter in radio over fiber links, Journal of Electromagnetic Waves and Applications, Vol.22, No.14-15, pp.2053-2061, 2008. 2. B. Chen, S. Zheng, H. Chi, X. Zhang, and X. Jin, An optical millimeter-wave generation technique based on phase modulation and Brillouin-assisted notch-filtering, IEEE Photonics Technology Letters, Vol.20, No.24, pp.2057-2059, Dec. 2008. 3. Hao Chi, Jianping Yao, Frequency quadrupling and upconversion in a radio over fiber link, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.15, pp.2706-2711, Aug. 2008. 4. H. Chi, X. Zou and J. P. Yao, An approach to the measurement of microwave frequency based on optical power monitoring, IEEE Photonics Technology Letters, Vol.20, No.17, pp.1249-1251, July 2008. 5. H. Chi and J. P. Yao, Chirped RF pulse generation based on optical spectral shaping and wavelength-to-time mapping using a nonlinearly chirped fiber Bragg grating, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.10, pp.1282-1287, May 2008. 6. H. Chi and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator, IEEE Microwave and Wireless Components Letters, Vol.18, No.5, pp.371-373, May 2008. 7. Hao Chi, Xianmin Zhang and Jianping Yao, A Novel Wavelength Shift Keying Transmitter using a Pair of Mach-Zehnder Modulators, Optics Communications, Vol.281, No.9, pp.2517-2521, May 2008. 8. Minglei Gong, Hao Chi, Xianmin Zhang, Xiaofeng Jin, and Yingyin K Zou, Reconfigurable Microwave Photonic Transversal Filter Using a Variable Gain Tilt Filter, Optics Communications, Vol.281, No.5, pp.998-1002, March 2008. 9. H. Chi and J. P. Yao, Power distribution of phase-modulated microwave signals in a dispersive fiber-optic link, IEEE Photonics Technology Letters, Vol.20, No.4, pp.315-317, Feb. 2008. 10. Guo-Feng Shen, Xian-Min Zhang, Hao Chi, Xiao-Feng Jin, Microwave/millimeter-wave generation using multi-wavelength photonic crystal fiber Brillouin laser, Progress in Electromagnetics Research (PIER), Vol.80, No.1, pp.307-329, Jan.2008. 11. H. Chi and J. P. Yao, A photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Express, Vol.16, No.2, pp.567-574, Jan. 2008.
2007 1. H. Chi and J. P. Yao, Fiber chromatic dispersion measurement based on wavelength-to-time mapping using a femtosecond pulse laser and an optical comb filter, Optics Communications, Vol.280, No.2, pp.337-342, Dec.2007. 2. H. Chi and J. P. Yao, Waveform distortions due to second-order dispersion and dispersion mismatches in a temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology, vol. 25, no.11, pp.3528-3535, November 2007. 3. H. Chi and J. P. Yao, All-fiber chirped microwave pulse generation based on spectral shaping and wavelength-to-time conversion, IEEE Transactions on Microwave Theory and Techniques, vol. 55, no. 9, pp. 1958-1963, September 2007. 4. H. Chi and J. P. Yao, An approach to photonic generation of high-frequency phase-coded RF pulses, IEEE Photonics Technology Letters, vol. 19, no. 10, pp. 768-770, May 2007. 5. H. Chi, F. Zeng, and J. P. Yao, Photonic generation of microwave signals based on pulse shaping, IEEE Photonics Technology Letters, vol. 19, no. 9, pp. 668-670, May 2007. 6. H. Chi and J. P. Yao, Symmetrical waveform generation based on temporal pulse shaping using an amplitude-only modulator, Electronics Letters, vol. 43, no. 7, pp. 415-417, March 2007.
2006 and previous 1. Wei Jiang, Linfang Shen, Daru Chen and Hao Chi, An extended FDTD method with inclusion of material dispersion for the full-vectorial analysis of photonic crystal fibers, Journal of Lightwave Technology, Vol.24, No.11, pp.4417-4423, Nov. 2006. 2. Daru Chen, Shan Qin, Linfang Shen, Hao Chi and Sailing He, An all-fiber multi-wavelength Raman laser based on a PCF sagnac loop filter, Microwave & Optical Technology Letters, Vol.48, No.12, pp.2416-2418, Sept. 2006. 3. Qiaoqiao Cheng, Xiaofeng Jin, Hao Chi and Xianming Zhang, Tunable Fiber Fabry-Perot Filter for Optical Carrier-Suppression and Single-Sideband Modulation in Radio over Fiber Links, International Journal of Infrared and Millimeter Waves, Vol.27, No.3, pp.381-390, March 2006. 4. X. Jin, H. Chi and X. Zhang, Improving frequency response of radio over fibre system by fibre Bragg grating, Electronics Letters, Vol.42, No.6 pp.369-370, March 2006. 5. Jinyue Lu, Hao Chi, Xianmin Zhang and Linfang Shen, Noise reduction using photonic microwave filter for radio over fiber system, Microwave & Optical Technology Letters, Vol.48, No.2, pp.305-307, Feb. 2006. 6. Chi Hao, Zhang Xianmin and Shen Linfang, Design of photonic crystal fibers with anomalous dispersion, Optoelectronics Letters, Vol.2, No.1, pp.1-4, Jan. 2006. 7. Xianbin Yu, Xianmin Zhang, Hao Chi, and Kangsheng Chen, A flexible and incoherent microwave photonic filter with a flat-top passband, Microwave & Optical Technology Letters, Vol.46, No.2, pp.132-134, July 2005. 8. Xianbin Yu, Xianmin Zhang, Hao Chi, and Kangsheng Chen, Photonic Microwave Transversal Filter Employing a Fiber-Bragg-Grating-Based Resonator, Microwave & Optical Technology Letters, Vol.44, No.4, pp.369-371, April 2005. 9. Yu Xianbin, Zhang Xianmin, Chi Hao, Chen Kangsheng, Characteristics of a tunable microwave photonics notch filter based on two fiber Bragg gratings, Chinese Journal of Electronics, Vol.14, No.1, pp.184-186, Jan 2005. 10. Hao Chi and Xianmin Zhang, FIR Photonic Microwave Filter Design Employing Simulated Annealing Algorithm, International Journal of Infrared and Millimeter Waves,Vol.25, No.12, pp.1757-1764, Dec. 2004. 11. Hao Chi and Xianmin Zhang, A novel tunable fiber-optic microwave notch filter using fiber loop and cascaded fiber Bragg gratings, Microwave & Optical Technology Letters, Vol.41, No.5, pp.386-388, June 2004. 12. Chi Hao, Zeng Qingji, Zhao Huandong, Luo Jiangtao, and Zhang Zhizhong, Scheduling algorithms for OBS switch with shared buffer, IEICE Transaction on Communications, Vol.E86-B, No.7, pp.2220-2223, July 2003. 13. Jun Huang,Qingji Zeng,Hao Chi,Pengcheng Xiao,Jimin Liu,Hua Liu, Performance analysis of a novel architecture for contention resolution of optical packet switching, Chinese Optics Letters, Vol.1, No.6, pp.314-316, June 2003. 14. CHI Hao, ZENG Qingji, Zhao Huandong, Liu Hua, Xiao Shilin, Analysis on Dispersion Characteristics of Photonic Crystal Fiber, Journal of Infrared and Millimeter Waves, Vol.22, No.2, pp.149-153, Feb. 2003. 15. Jianxin Wang, Qingji Zeng, Zhizhong Zhang, Hao Chi, A novel differentiated services supporting scheme for optical burst switched networks, Chinese Optics Letters, Vol.1, No.7, pp.392-394, Jan. 2003. 16. Chi H, Tao XM, Yang DX, Chen KS, Simultaneous measurement of axial strain, temperature, and transverse load by a superstructure fiber grating, Optics Letters, Vol.26, No.24, pp.1949-1951, Dec. 2001. 著作: 专利成果: 软件成果: |
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Selected publications: 2025 1. Yizai Cai, Shuna Yang , Hao Chi, All-optical digital-to-analog conversion based on pulse walk-off effect, Optical Fiber Technology, Vol.90, art. 104084, March 2025. 2. Bo Yang, Zhipeng Liu, Shuna Yang, and Hao Chi , Stable bias control of Mach-Zehnder modulator for arbitrary optical pulse picking via reference pulse power monitoring, Optics Express, vol. 33, no. 4, pp. 6689-6696, Feb. 2025. 3. Wei Dai, Bo Yang , Shuna Yang, Yanrong Zhai, Jun Ou, and Hao Chi, Photonic compressive sensing of microwave signals with enhanced compression ratio and frequency range via optical pulse random mixing, Optics Letters, vol. 50, no. 2, pp.261-264, Jan. 2025. 4. Haonan Zheng, Shuna Yang , Zhaoyang Qiu, Yiran Gao, Bo Yang, and Hao Chi, Photonic Nyquist folding receiver using optical pulses with discrete pulse position modulation, Optics Express, vol. 33, no. 6, pp. 12699-12708, Mar. 2025.
2024 1. H. Wang, B. Yang , S. Yang, Y. Gao, J. Ou, Y. Zhai, and H. Chi, Simultaneous frequency and angle-of-arrival measurement of microwave signals utilizing the Talbot effect and pulse interference, Optics Communications, Vol. 573, 131047, Dec. 2024 2. S. Yang , X. Qu. B. Yang, and H. Chi, Photonic generation and programmable switching of variable-band chirped waveforms with immunity to power fading, Optics Letters, Vol. 49, No. 18, pp. 5107-5110, 15 Sept. 2024. 3. L. Yin, S. Yang , X. Yang, Y. Yao, B. Yang, and H. Chi, All-optical generation of full-range symmetry-tunable triangular-shaped pulses via wavelength multiplexing, Applied Optics, Vol. 63, No. 24, 20 Aug. 2024. 4. Y. Pan, J. Ou , H. Chi, High-dimensional signal encoding and decoding method based on multi-ring perfect vortex beam, Optics Express, Vol. 32, No. 17, pp. 30800-30812, 12 Aug. 2024. 5. W. Dai, B. Yang , H. Chi, H. He, Y. Zhai, J. Ou, and S. Yang, Wideband spectrum compressive sensing utilizing photonic multi-coset sampling with dual low-rate optical pulses, Applied Optics, Vol. 63, No. 18, pp. 4914-4915, 20 June 2024. 6. T. Zhang, Y. Li , B. Yang, W. Pan, L. Yan, H. Chi, X. Zou, Photonic-Assisted Multi-Antenna Frequency-Spatial Compressed Sensing Array for Joint Frequency and DOA Estimation, Journal of Lightwave Technology, vol. 42, no. 21, pp. 7678-7685, 1 Nov., 2024. 7. X. Qin, S. Yang , and H. Chi, Photonic generation and transmission of dual-band double-TBWP chirped microwave waveforms with frequency multiplication and immunity to dispersion-induced power fading, Journal of Modern Optics, Vol. 71, No. 4–6, pp.194–203, 17 Sept. 2024. 8. Xu Qin, Shuna Yang , Hongxia He, Bo Yang, Hao Chi, Photonic generation and anti-dispersion transmission of the quaternary phase-coded microwave waveforms, Optical Engineering, Vol. 63, No. 3, 038104, 17 Sept. 2024. 9. B. Yang, B. Bai, H. Chi , S. Yang, Y. Gao, and H. He, Harmonic active mode-locking optoelectronic oscillator with suppressed supermode noise based on pulse intensity feedback, Optics Letters, Vol. 49, No. 5, pp. 1265-1268,1265-1268, 1 March, 2024. 10. B. Yang, J. Sun, H. Chi , K. Xu, S. Yang, Joint radar and communication system based on a chaotic optoelectronic oscillator, Optics Communications, Vol. 554, 130123, 1 March, 2024. 11. X. Cai, S. Yang, B. Yang, Y. Zhai, T. Jin, and H. Chi , Scalable photonic reservoir computing based on pulse propagation in parallel passive dispersive links, Applied Optics, Vol. 63, No. 22, pp.5785-5791, Aug. 2024. 12. X. Zhang, S. Yang , B. Yang, Y. Gao, H. He, and H. Chi , Simultaneous Measurement of AOA and Frequency based on Stimulated Brillouin Scattering and Frequency-to-Time Mapping, Journal of Lightwave Technology, Vol. 42, No. 16, pp.5606-5615, Aug. 2024. 13. Y. Wang, S. Yang, B. Yang, H. Chi , Photonic architecture for remote multi-parameter measurement and transmission of microwave signals, Optics Express, Vol. 32, No. 10, pp. 18033-18043, 6 May 2024. 14. Y. Qiu, S. Yang, B. Yang, H. Chi , Optical computation of discrete Fourier transform utilizing the temporal Talbot effect with input pulse trains of finite duration, Optical Review, Vol.31, pp. 383-394, May, 2024. 15. 杨波、赵雷、杨淑娜、池灏,基于分数阶Talbot效应的宽带射频信号实时频谱分析,光子学报,Vol. 53, No. 4, 0406006, April 2004. 16. R. Li, S. Yang, B. Yang, Y. Gao, H. He, and H. Chi , Instantaneous frequency measurement based on photonic compressive sensing with sub-Nyquist pseudo-random binary sequences, Optics Letters, Vol. 49, No. 7, pp. 1832-1835, April 2024.
2023 1. C. Huang, H. Chi , S. Yang, B. Yang, Y. Zhai, and J. Ou, Photonic generation of dual-mode multi-format chirp microwave signals, Applied Optics, Vol. 62, No. 31, pp. 8224-8228, Nov. 2023. 2. X. Zhang, H. Chi , Y. Gao, H. He, and Y. Zhai, Photonic angle-of-arrival measurement of microwave signals using a triangular wave, Optics Letters, Vol. 48, No. 19, pp. 5013-5016, Oct. 2023. 3. G. Lyu, H. Chi, S. Yang , and B. Yang, All-optical digital-to-analog conversion based on time-domain pulse spectrum encoding, Optical Engineering, Vol. 62, No. 6, 06510, June 2023. 4. S. Yang, L. Yin, H. Chi , B. Yang, J. Ou and Y. Zhai, Symmetry-Tunable Full-Duty Triangular-Shaped Waveform Generation Using a Simple Single-Drive Mach-Zehnder Modulator, IEEE Photonics Journal, vol. 15, no. 3, Art no. 5500906, pp. 1-6, June 2023. 5. J. Ou , Z. Yin, H. Chi , Q. Li, B. Yang, S. Yang, Y. Zhai, Partially coherent anomalous vortex beam in anisotropic turbulence, Optics Communications, Vol. 537, 129411, June 2023. 6. S. Yang, W. Zhu, H. Chi , B. Yang, J. Ou, and Y. Zhai, Photonic generation of dual-band dual-chirp waveforms with anti-dispersion transmission, Applied Optics, Vol. 62, No. 13, pp. 3512-3518, May 2023. 7. B. Yang, Q. Xu, H. Chi , Z. Liu, and S. Yang, Photonic compressive sampling of wideband sparse radio frequency signals with 1-bit quantization, Optics Express, Vol. 31, No. 11, pp.18159-18166,May 2023. 8. B. Yang , Z. Ma, S. Yang, and H. Chi, Broadband and linearized photonic time-stretch analog-to-digital converter based on a compact dual-polarization modulator, Applied Optics, Vol. 62, No. 4, pp.921-926, Feb. 2023. 9. R. Li, H. Chi , B. Yang, S. Yang, and T. Jin, Photonics-assisted compressed sensing of radio frequencies with a rate-doubled bipolar random sequence, Optics Letters, Vol. 48, No. 3, pp.692-695, Feb. 2023 10. Y. Gao, H. Chi, J. Dai , and K. Xu, Ku-band analog photonic down-conversion link with coherent I/Q image rejection and digital linearization, Optics Express, Vol. 31, No. 2, pp. 2135-2146, Jan. 2023. 11. S. Yang, Y. Huai, B. Yang, H. Chi , High-stable and reconfigurable photonic generation of radio-frequency arbitrary waveforms with multi-tone inputs, Optical Engineering, Vol. 62, No.1, 015101, Jan. 2023. 12. J. Dan, T., Jin , H. Chi, S. Dong, and Y. Shen, Uncertainty-guided joint unbalanced optimal transport for unsupervised domain adaptation, Neural Computing and Applications, Vol. 35, No. 7, pp. 5351–5367, March 2023. 13. J. Dan, T. Jin , Hao Chi, Y. Shen, J. Yu, J. Zhou, HOMDA: High-Order Moment-Based Domain Alignment for unsupervised domain adaptation, Knowledge-Based Systems, Volume 261, 110205, Feb. 2023. 14. J. Dan, T. Jin , H. Chi, S. Dong, H. Xie, K. Cao, X. Yang, Trust-aware conditional adversarial domain adaptation with feature norm alignment, Neural Networks, Vol. 168, pp. 518-530, Nov. 2023.
2022 1. Y. Zhang and H. Chi , An Optical Front-End for Wideband Transceivers Based on Photonic Time Compression and Stretch, Photonics, Vol.9, No.6, 658, September, 2022. 2. H. Zhou, R. Li, H. Chi , Optical Signal Sampling Based on Compressive Sensing with Adjustable Compression Ratio, Current Optics and Photonics, Vol. 6, No. 3, 288-296, June 2022. 3. S. Yu, S. Yang, B. Yang, and H. Chi , Photonic Generation of Switchable Dual-Band Dual-Chirp Microwave Waveforms, IEEE Photonics Journal, Vol.14, No.1, art no. 5504305, Feb. 2022. 4. H. Chi, Q. Zhang, S. Yang , B. Yang, Y. Zhai, and J. Ou, Photonic analog-to-digital conversion based on time-to-frequency mapping, Optics Communications, Vol.502, 127440, Jan. 2022. 5. J. Dan, T. Jin , H. Chi, Y. Shen, Uncertainty-guided joint unbalanced optimal transport for unsupervised domain adaptation, Neural Computing and Applications, 1-17, Nov. 2022. 6. B. Yang, J. Yu, H. Chi , S. Yang, Y. Zhai, and J. Ou, Polarization multiplexed active mode-locking optoelectronic oscillator for frequency tunable dual-band microwave pulse signals generation, Optics Express, Vol. 30, No.15 27132-27139, July 2022. 7. S. Yang, J. Wang, B. Yang, H. Chi , J. Ou, Y. Zhai, and Q. Li, A serial digital-to-analog conversion based on photonic time-stretch technology, Optics Communications, Vol. 510, 127949, May 2022. 8. B. Yang, Q. Xu, S. Yang, and H. Chi , Wideband sparse signal acquisition with ultrahigh sampling compression ratio based on continuous-time photonic time stretch and photonic compressive sampling, Applied Optics, Vol.61, No.6, pp.1344-1348, June, 2022. 9. 杨淑娜、许嘉丽、杨鸿珍、赵玉虎、池灏,基于链路失效模型的多级电力业务路由规划,电子与信息学报,Vol.44, No. 11, pp.3788-3795, Nov. 2022.
2021 1. Q. Zhang, H. Chi, Photonic digital-to-analog converter based on spectral encoding, Microwave and Optical Technology Letters, Vol. 63, No. 10, pp. 2670-2674, Oct. 2021. 2. B. Yang, H. Zhao, S. Yang , H. Chi, Wideband Doppler frequency shift measurement and direction discrimination based on optical single sideband modulation with a fixed low-frequency reference signal, Optics Communications, vol. 499, 127306, Nov. 2021 3. H. He, S. Yang, B. Yang, Y. Zhai, T. Jin, and H. Chi , Photonic time-stretch based on phase modulation for sub-octave applications, Applied Optics, Vol.60, No.22, pp.6481-6488, Aug. 2021. 4. H. Chi, C. Wang, and J. P. Yao , Photonic Generation of Wideband Chirped Microwave Waveforms, IEEE Journal of Microwaves, Vol.1, No.3, pp. 787-803, July 2021. (Invited) 5. H. Chi, S. Wang, S. Yang, Y. Zhai , X. Zou, B. Yang, Q. Li, Photonic arbitrary waveform generation based on the temporal Talbot effect, Optics Express, Vol. 29, No. 11, pp. 16927-16938, May 2021. 6. H. Chi, H. Zhou, S. Yang, J. Ou, Y. Zhai, and B. Yang , Compressive sensing based on optical mixing using a spectral shaper with bipolar coding, Optics Express, Vol. 29, No. 11, pp.16422-16431, May 2021 7. C. Yi, S. Yang, B. Yang, T. Jin, and Hao Chi , Photonic approach for generating bandwidth-doubled and switchable multi-format chirp waveforms, Optics Letters, Vol. 46, No. 7, pp.1578-1581, April 2021. 8. S. Yang, J. Wang, H. Chi H, B. Yang , Distortion compensation in continuous-time photonic time-stretched ADC based on redundancy detection. Applied Optics, vol. 60, no. 6, pp.1646-1652, 2021. 9. X. Zhu, T. Jin , Y. Fu, H. Chi, W. Liu, Q. Wang, and P. Feng, A dispersion-free multi-access RF dissemination link with phase jitter compensation. Electronics Letters, Vol.57, No. 1, pp.30-31, Jan. 2021.
2020 1. S. Yang, X. Hu, B. Yang, H. Chi , Resolution-enhanced photonic quantization scheme based on weighted modulation transfer functions of lithium niobate Mach–Zehnder modulators, Applied Optics, Vol. 59, No. 31, pp. 9780-9785, Nov. 2020. 2. B. Yang, H. Zhao, Z. Cao, S. Yang, Y. Zhai, J. Ou, H. Chi , Active mode-locking optoelectronic oscillator, Optics Express, Vol. 28, No. 22, pp. 33220-33227, Oct. 2020. 3. B. Yang, S. Yang, Z. Cao, J. Ou, Y. Zhai, and H. Chi , Photonic compressive sensing of sparse radio frequency signals with a single dual-electrode Mach–Zehnder modulator, Optics Letters, Vol. 45, No. 20, pp. 5708-5711, Oct. 2020. 4. C. Yi, H. Chi , T. Jin, A photonic approach for Doppler frequency shift measurement with dispersion medium, IEEE Photonics Journal, Vol. 12, No. 5, 7102708, Oct. 2020. 5. Shuna Yang, Zhiwei Liu, Hao Chi , Ran Zeng, Bo Yang, A Photonic Digitization Scheme With Enhanced Bit Resolution Based on Hierarchical Quantization, IEEE Access, vol.8, pp. 150242-150247, Aug. 2020. 6. H. Chi, S. Hu, Y. Zhai, B. Yang, Z. Cao, J. Ou, S. Yang, Real-time discrete Fourier transformer with complex-valued outputs based on the inverse temporal Talbot effect, Optics Express, Vol. 287, No. 14, 20543, July 2020. 7. X. Zhu, T. Jin , Y. Fu. H. Chi, et al, A frequency-stable optoelectronic oscillator based on passive phase compensation, IEEE Photonics Technology Letters, Vol. 32, No. 10, pp.612-615, May 2020. 8. H. He, S. Yang, H. Chi , and T. Jin, Photonic serial implementation of a flash analog-to-digital converter, Optics Letters, Vol. 45, No. 7, pp.1643-1646, April 2020. 9. B. Yang, H. He, S. Yang, J. Ou, Y. Zhai, and H. Chi , Analysis on predistortion algorithm for improving adjacent channel leakage ratio of radio over fiber systems, Microwave and Optical Technology Letters, Vo. 62, No. 4, 1483-1488, April 2020. 10. Y. Zhai, H. Chi , J. Tong, J. Xi, Capacity Maximized Linear Precoder Design for Spatial-Multiplexing MIMO VLC Systems, IEEE Access, Vol. 8, pp. 63901- 63909, April 2020. 11. C. Yi, H. Chi , B. Yang, and T. Jin, A PM-based approach for Doppler frequency shift measurement and direction discrimination, Optics Communications, Vol. 458, 124796, March, 2020. 12. B. Yang, H. Chi , S. Yang, Z. Cao, J. Ou, and Y. Zhai, Broadband Microwave Spectrum Sensing Based on Photonic RF Channelization and Compressive Sampling, IEEE Photonics Journal, Vol. 12, No.1, 5500109, Feb. 2020. 13. H. Chi, S. Jiang, J. Ou, and T. Jin, Comprehensive study of orbital angular momentum shift keying systems with a CNN-based image identifier, Optics Communications, Vol. 454, 124518, Jan. 2020. 14. 池灏、张秋林、杨淑娜,基于MZ干涉结构的光子模数转换技术研究进展,杭州电子科技大学学报(自然科学版),pp.1-7, Vol.40, No.1, Jan. 2020.
2019 1. S. Yang, H. He, H. Chi , and R. Zeng, Photonic quantization and encoding scheme with improved bit resolution based on waveform folding, Optics Express, Vol. 27, No. 24, pp. 35565-35573, Dec. 2019. 2. S. Yang, H. Chi , B. Yang, R. Zeng, J. Ou, Y. Zhai, Q. Li, Photonic digitization with differential encoding based on orthogonal vector superposition, IEEE Photonics Journal, Vol. 11, No. 6, 7104509, Dec. 2019. 3. J. Ou, M. Hu, F. Li, R. Zeng, M. Bi, S. Yang, Y. Zhai, H. Chi , Average capacity of wireless optical links using Laguerre-Gaussian beam through non-Kolmogorov turbulence based on generalized modified atmospheric spectral model, Optics Communications, Vol. 452, 487-493, Dec. 2019. 4. X. Zhu, T. Jin, Y. Fu, H. Chi, L. Zuo, W. Liu, and Q. Wang, Stable photonic transmitting link based on passive phase compensation with active-assisted control method, Electronics Letters, Vol. 55, No. 20, pp. 1097-1098, Oct. 2019. 5. H. He, S. Yang, T. Jin, and H. Chi , Photonic quantization using dual-output Mach–Zehnder modulators and balanced photodetectors, Optics Communications, Vol. 446, 72-76, Sept. 2019. 6. H. Chi, J. Xing, S. Yang, and T. Jin, Evolution of Amplitude Fluctuation in Fractional Temporal Talbot Effect, IEEE Access, Vol. 7, 86177, June 2019. 7. X. Zhu, T. Jin, Y. Fu, H. Chi, D. Li, L. Zuo, W. Liu, and Q. Wang, Compensation of dispersion-induced power fading with adjustment-free operation, Optical Engineering, Vol. 58, No. 6, 060504-1-4, June, 2019. 8. S. Jiang, H. Chi , X. Yu, S. Zheng, X. Jin, and X. Zhang, Coherently demodulated orbital angular momentum shift keying system using a CNN-based image identifier as demodulator, Optics Communications, Vol. 435, 367-373, March 2019 9. H. Chi and Z. Zhu, Analytical model for photonic compressive sensing with pulse stretch and compression, IEEE Photonics Journal, vol. 11, no. 1, 5500410, Feb. 2019. 10. X. Zhu, T. Jin, H. Chi, G. Tong, D. Li, L. Zuo, W. Liu and Y. Fu, Photonic down-conversion and linearisation with tunable IF bandwidth and improved spurious-free dynamic range, Electronics Letters, Vol. 55, No. 2, pp. 105-107, Jan. 2019.
2018 1. G. Tong, T. Jin, H. Chi, X. Zhu, T. Lai, D. Li and L. Zuo, Stable radio frequency dissemination in a multi-access link based on passive phase fluctuation cancellation, Optics Communication, vol. 423, pp. 53-56, 2018. 2. X. Zhu, T. Jin, H. Chi, G. Tong, T. Lai, A coherent RF scanning receiver based on a flat optical frequency comb, Optics Communications, vol. 421, pp. 41-45, 2018. 3. X. Zhu, T. Jin, H. Chi, G. Tong, T. Lai, D. Li, Photonic receiving and linearization of RF signals with improved spurious free dynamic range, Optics Communications, vol. 423, pp. 17-20, 2018. 4. X. Zhu, T. Jin, H. Chi, J. Zhou, G. Tong, D. Li, L. Zuo, Y. Fu, Linearization of two cascaded intensity-modulator-based analog photonic link, Optical Engineering, vol. 57, no. 8, pp. 080501(1-4), 2018. 5. J. Xing, C. Wang, H. Chi, X. Yu, S. Zheng, X. Jin, and X. Zhang, Modulation fading in temporal Talbot effect, IEEE Photonics Technology Letters, Vol. 30, No.15, pp. 1376-1379, Aug. 2018. 6. B Xu, C Liu, X Jin, X Jin, H Chi, S Zheng, X Zhang, Time-Division Multiplexed Vector Signal Synthesizer Based on Continuous PTS, IEEE Photonics Technology Letters, vol. 30, no. 11, 1020-1023, June 2018. 7. H. He, H. Chi , X. Yu, T. Jin, S. Zheng, X. Jin, and X. Zhang, An improved photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Communications, Vol. 425, pp.157-160, March 2018. 8. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Yu, X. Jin, and X. Zhang, Photonics-enabled compressive sensing with spectral encoding using an incoherent broadband source, Optics Letters, Vol. 43, No.2, pp. 330-333, Jan. 2018.
2017 1. Y. Xu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, On the undesired frequency chirping in photonic time-stretch systems, Optics Communications, Vol. 405, pp.192-196, Dec. 2017. 2. H. Zhang, S. Wang, S. Jia, X. Yu, X. Jin, S. Zheng, H. Chi, X. Zhang, Experimental Generation of Linearly Chirped 350 GHz band Pulses with beyond 60 GHz Bandwidth, Optics Letters, Vol. 42, No. 24 pp. 5242-5245, 2017 4. S. Yang, M. Hu, H. Chi , Q. Li, Photonic digital-to-analog conversion based on wavelength multiplexing, Optics Communications, Vol. 401, pp.1-5, Oct. 2017. 5. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, All-positive-coefficient microwave photonic filter with rectangular response, Optics Letters, Vol. 42, No. 15, Aug. 2017, pp.3012-3015. 6. G. Tong, T. Jin, H. Chi, X. Zhu, T. Lai and X. Wu, A novel optoelectronic oscillator based on Brillouin-induced slow light effect, IEEE Photonics Technology Letters, Vol.29, No.16, pp.1375-1378, Aug. 2017. 7. Y Xu, T Jin, H Chi , S Zheng, X Jin, X Zhang, Photonic generation of dual-chirp waveforms with improved time bandwidth product, IEEE Photonics Technology Letters, Vol. 29, No.15, pp. 1253-1256, Aug. 2017. 8. Y. Mei, Y. Xu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, Spurious-Free Dynamic Range of the Photonic Time-Stretch System, IEEE Photonics Technology Letters, Vol.29, No.10, pp.794-797, May 2017. 9. R. Fu, X. Jin, Y. Zhu, X. Jin, X. Yu, S. Zheng, H. Chi, and X. Zhang, Frequency stability optimization of an OEO using phase-locked-loop and self-injection-locking, Optics Communications, Vol. 386, pp. 27-30, 2017.
2016 2. G. Tong, T. Jin, H. Chi, J. Zheng, X. Zhu, T. Lai, X. Wu, and Z. Shi, Reducing the noise floor in optoelectronic oscillator by optimizing the operation of modulator, Optical Engineering, Vol.55, No.10, pp.100504-1-4, Oct. 2016. 5. Y. L. Chen, S. Zheng, Y. Li, X. Hui, X. Jin, H. Chi, and X. Zhang, A Flat-Lensed Spiral Phase Plate Based on Phase-Shifting Surface for Generation of Millimeter-Wave OAM Beam, IEEE Antennas and Wireless Propagation Letters, Vol. 15, pp.1156-1158, 2016. 6. X. Hui, S. Zheng, w. Zhang, X. Jin, H. Chi, and X. Zhang, Local topological charge analysis of electromagnetic vortex beam based on empirical mode decomposition, Optics Express, Vol. 24, No.5, pp.5423-5430, March 2016. 7. Z. Zhu, H. Chi , T. Jin, S. Zheng, X. Jin, and X. Zhang, Photonic compressive sensing for analog-to-information conversion with a delay-line based microwave photonic filter, Optics Communications, Vol.371, pp.83-88, July 2016. 8. Y. Chen, Y. Ding, Z. Zhu, H. Chi , S. Zheng, X. Zhang, X. Jin. M. Galili, and X. Yu, Photonic compressive sensing with a micro-ring-resonator-based microwave photonic filter, Optics Communications, Vol.373, pp.65-69, Aug. 2016. 9. C. Xu, S. Zheng, X. Chen, H. Chi, X. Jin, and X. Zhang, Photonic-assisted time-interleaved ADC based on optical delay line, Journal of Optics, Vol.18, No.1, Jan. 2016. 10. Z. Zhang, S. Zheng, Y. Chen, X. Jin, H. Chi, and X. Zhang, The Capacity Gain of Orbital Angular Momentum Based Multiple-Input-Multiple-Output System, Scientific Reports, Vol.6, DOI: 10.1038/srep25418, May 2016.
2015 1. Y. Zhu, J. Zhou, X. Jin, H. Chi, X. Zhang, and S. Zheng, An optoelectronic oscillator‐ased strain sensor with extended measurement range, Microwave and Optical Technology Letters, Vol. 57, pp. 2336-2339, Oct. 2015. 2. Shilie Zheng, Xiaonan Hui, Jiangbo Zhu, Hao Chi, Xiaofeng Jin, Siyuan Yu, and Xianmin Zhang, Orbital angular momentum mode-demultiplexing scheme with partial angular receiving aperture, Optics Express, Vol. 23, No. 9, May 4, 2015, pp. 12251-12257. 3. S. Qu, T. Jin, H. Chi, G. Tong, F. Ren, and X. Zhao, An optoelectronic oscillator using an FBG and an FBG-based Fabry-Perot filter, Optics Communications, Vol. 342, pp.141-143, May 2015 4. X. Zhao, T. Jin, H. Chi, and S. Qu, Modeling and simulation of the background light in underwater imaging under different illumination conditions, Acta, Physica Sinica, Vol.64, No.10, pp.104201, May 2015. In Chinese 5. Xiannan Hui, Shilie Zheng, Yiling Chen, Yiping Hu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Multiplexed millimeter wave communication with dual orbital angular momentum (OAM) mode antennas, Scientific Reports, Vol. 5, 10148, May 19, 2015. 7. Yi Wang, Xiaofeng Jin, Yanhong Zhu, Xianmin Zhang, Shilie Zheng, Hao Chi, A wideband tunable optoelectronic oscillator based on a spectral-subtraction-induced MPF, IEEE Photonics Technology Letters, Vol. 27, No. 9, May 1, 2015, pp. 947-950. 8. Xiaonan Hui, Shilie Zheng, Yiping Hu, Chen Xu, Xiaofeng Jin, Hao Chi, and Xianmin Zhang, Ultralow reflectivity spiral phase plate for generation of millimeter-wave OAM beam, IEEE Antennas and Wireless Propagation Letters, Vol. 14, April 2015, pp. 966-969. 9. Shilie Zheng, Xiaonan Hui, Xiaofeng Jin, and Hao Chi, and Xianmin Zhang, Transmission characteristics of a twisted radio wave based on circular traveling-wave antenna, IEEE Transactions on Antennas and Propagation, Vol. 63, No. 4, April 2015, pp. 1530-1536. 11. Y. Chen, X. Yu, H. Chi , S. Zheng, X. Zhang, X. Jin, and M. Galili, Compressive sensing with a microwave photonic filter, Optics Communications, Vol. 338, pp.428-432, March 2015
2014 1. X. Hui, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Hilbert-Huang Transform Time-Frequency Analysis in phi-OTDR Distributed Sensor, IEEE Photonics Technology Letters, Vol. 26, No. 23, pp. 2403-2406, Dec. 2014. 3. X. Hui, T. Ye, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Space-frequency analysis with parallel computing in a phase-sensitive optical time-domain reflectometer distributed sensor, Applied Optics, Vol. 53, No. 28, pp. 6586-6590, Oct. 2014. 4. Y. Zhu, X. Jin, H. Chi, S. Zheng, and X. Zhang, High-sensitivity temperature sensor based on an optoelectronic oscillator, Applied Optics, Vol. 53, Vol. 22, pp.5084-5087, Aug. 2014. 5. Y. Pan, S. Zheng, J. Zhou, H. Chi, X. Jin, and X. Zhang, Analyses of Whispering Gallery Modes in Circular Resonators by Transmission Line Theory, IEEE/OSA Journal of Lightwave Technology, Vol.32, No. 13, pp.2345-2352, July 2014 7. Y. Chen, X. Yu. H. Chi , X. Jin, X. Zhang, S. Zheng, and M. Galili, Compressive sensing in a photonic link with optical integration, Optics Letters, Vol.39, No.8, pp. 2222-2224, April 2014. 8. Y. Mei, Y. Xu, H. Chi , X. Zhang, X. Jin, S. Zheng, and T. Jin, Photonic generation of chirped microwave signals with high time-bandwidth product, Optics Communications, Vol.316, pp106-110, April 2014.
2013 1. Y. Chen, H. Chi, T. Jin, S. Zheng, X. Jin, and X. Zhang, Sub-Nyquist Sampled Analog-to-Digital Conversion Based on Photonic Time Stretch and Compressive Sensing With Optical Random Mixing, Journal of Lightwave Technology, No.31, No.21, pp.3395-3401, Nov. 2013. 2. B. Yang, X. Jin, Y. Chen, H. Chi, X. Zhang, S. Zheng, E. Tangdiongga, T. Koonen, Photonic Microwave Up-Conversion of Vector Signals Based on an Optoelectronic Oscillator, IEEE Photonics Technology Letters, Vol.25, No.18, pp.1758-1761, Sept. 2013. 3. F. Zhou, X. Jin, B. Yang, J. Zhou, X. Zhou, S. Zheng, and H. Chi, Photonic generation of frequency quadrupling signal for millimeter-wave communication, Optics Communications, Vol.304, pp.71-74, Sept. 2013. 4. Y. Wang, X. Jin, H. Chi, X. Zhang, and S. Zheng, Tunable multi-tap microwave photonic filter with complex coefficients using a dual-parallel Mach-Zehnder modulator, Journal of Modern Optics, Vol.60, No.13, pp.1069-1073, July 2013. 5. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang, All-optical modulator with long range surface plasmon resonance, Optics and Laser Technology, Vol.49, pp.316-319, July 2013. 6. Bo Yang, Xiaofeng Jin, Ying Chen, Jinhai Zhou, Xianmin Zhang, Shilie Zheng, Hao Chi, A Tunable Optoelectronic Oscillator Based on a Dispersion-Induced Microwave Photonic Filter, IEEE Photonics Technology Letters, Vol.25, No.10, pp.921-924, May 2013. 7. Ying Chen, Bo Yang, Hao Chi, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Photonic instantaneous frequency measurement with digital output based on dispersion induced power fading functions, Optics Communications, Vol.292, No.1, pp. 53–56, April 2013. 8. Y. Qiao, M. Pan, S. Zheng, H. Chi, X. Jin, and X. Zhang, An electrically tunable frequency-doubling optoelectronic oscillator with operation based on stimulated Brillouin scattering, Journal of Optics, Vol.15, No.3, March 2013. 9. Hao Chi, Ying Chen, Yuan Mei, Xiaofeng Jin, Shilie Zheng, and Xianmin Zhang, Microwave spectrum sensing based on photonic time stretch and compressive sampling, Optics Letters, Vol. 38, No. 2, pp.136-138, Jan. 2013.
2012 1. Ying Chen, Hao Chi, Shilie Zheng, Xiaofeng Jin, Xianmin Zhang Photonic analog-to-digital converter based on the robust symmetrical number system, Optics Communications, Vol.285, No.24, pp. 4966–4970, Nov. 2012. 2. Xiaofeng Jin, Jinhai Ou, Ran Hao, Feng Zhou, Xianmin Zhang, Shilie Zheng, Hao Chi, Novel Demodulation Method for Fiber-Optic Interferometers Based on pi/2 Phase Modulation, IEEE Photonics Technology Letters, Vol.24, No.22, pp.1981-1983, Nov. 2012. 3. Hao Chi, Yuan Mei, Ying Chen, Donghui Wang, Shilie Zheng, Xiaofeng Jin, and Xianmin Zhang, Microwave spectral analysis based on photonic compressive sampling with random demodulation, Optics Letters, Vol. 37, No. 22, pp.4636-4638, Nov. 2012. 4. Y. Wang, X. Jin, K. Xu, J. Ou, H. Chi, X. Zhang, and S. Zheng, Four-tap microwave photonic filter with tunable center frequency and reconfigurable transfer function, Microwave and Optical Technology Letters, Vol.54, No.7, pp.1740-1743, July 2012. 5. S. Zheng, S. Ge, X. Zhang, H. Chi, and X. Jin, High-resolution multiple microwave frequency measurement based on stimulated Brillouin scattering, IEEE Photonics Technology Letters, Vol.24, Vol.13, pp.1115-1117, July 2012. 6. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang , All-optical modulator with long range surface Plasmon resonance, Optics & Laser Technology, Vol.44, No.5, pp.1442-1445, July 2012. 7. B. Yang, X. Jin, H. Chi, X. Zhang, and S. Zheng, Optically tunable frequency-doubling optoelectronic oscillator with carrier phase-shifted double sideband modulation, IEEE Photonics Technology Letters, Vol.24, No.12, pp.1051-1053, June 2012. 8. Z. Li, Y. Han, H. Chi, X. Zhang, and J. P. Yao, A continuously tunable microwave fractional Hibert transformer based on a nonuniformly spaced photonic microwave delay-line filter, Journal of Lightwave Technology, Vol.30, No.12, pp.1948-1953, June 2012. 9. Z. Li, X. Zhang , H. Chi, S. Zheng, X. Jin, and J. P. Yao, A reconfigurable microwave photonic channelized receiver based on dense wavelength division multiplexing using an optical comb, Optics Communications, Vol.285, No.9, pp.2311-2315, May 2012. 10. X. Shi, S. Zheng, H. Chi, X. Jin, and X. Zhang, Refractive index sensor based on tilted fiber Bragg grating and stimulated Brillouin scattering, Optics Express, Vol.20, No.10, pp.10853-10858, May 2012. 11. W. Kang, S. Zheng, X. Zhang, X. Jin, H. Chi, and Y. Zou, Quadratic electro-optic properties of Pb(Mg1/3Nb2/3)O-3-PbTiO3 transparent ceramics under both DC and AC bias, Applied Optics, Vol.51, No.15, pp.2870-2876, May 2012. 12. H. Shao, W. Chen, Y. Zhao, H. Chi, J. Yang, and X. Jiang, Performance evaluation of photonic UWB generation based on silicon MZM, Optics Express, Vol.20, No.7, pp.7398-7403, Mar. 2012. 13. B. Yang, X. Jin, X. Zhang, S. Zheng, H. Chi, Y. Wang, A Wideband Frequency-Tunable Optoelectronic Oscillator based on a Narrowband Phase-Shifted FBG and Wavelength tuning of Laser, IEEE Photonics Technology Letters,Vol.24, No.1, pp.73-75, Jan. 2012.
2011 1. Ying Chen, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Differentially- Encoded Photonic Analog-to-Digital Conversion based on Phase Modulation and Interferometric Demodulation, IEEE Photonics Technology Letters, Vol.23, No.24, pp. 1890-1892, Dec. 2011. 2. Z. Li, M. Li, H. Chi, X. Zhang, and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal With Large Frequency Tunability Using a Polarization-Maintaining Fiber Bragg Grating, IEEE Microwave and Wireless Components Letters, Vol.21, No.12, pp.694-696, Dec. 2011. 3. X. L. Shi, S. L. Zheng, H. Chi, X. F. Jin, and X. M. Zhang, A wideband electro-optic modulator based on long range surface plasmon resonances, Journal of Optics, Vol.13, No.12, pp.1-5, Dec. 2011. 4. Z. Li, H. Chi, X. Zhang, and J. P. Yao, A Continuously Tunable Microwave Fractional Hilbert Transformer Based on a Photonic Microwave Delay-Line Filter Using a Polarization Modulator, IEEE Photonics Technology Letters, Vol.23, No.22, pp.1694-1696, Nov. 2011. 5. Yun Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic approach for microwave spectral analysis based on Fourier cosine transform, Optics Letters, vol. 36, no.19, pp.3897-3899, Oct. 2011. 6. Yun Wang, Juan Ni, Hao Chi, Xianmin Zhang, Shilie Zheng, and Xiaofeng Jin, Photonic Instantaneous Microwave Frequency Measurement Based on Two Different Phase Modulation to Intensity Modulation Conversions, Optics Communications, vol.284, no.16-17, pp.3928-3932, Aug. 2011. 7. L. Liu, Y. Shen, S. Zheng, X. Jin, H. Chi, and X. Zhang, Optical generation of microwave/millimetre-wave based on Brillouin-erbium fiber laser, Microwave and Optical Technology Letters, vol.53, no.8, pp.1761-1763, Aug. 2011. 8. H. Chi, Z. Li, X. Zhang, S. Zheng, X. Jin, and J. P. Yao, Proposal for photonic quantization with differential encoding using a phase modulator and delay-line interferometers, Optics Letters, vol.36, no.9, pp.1629-1631, May 2011. 9. Z. Li, W. Li, H. Chi, X. Zhang, and J. P. Yao, Photonic generation of phase-coded microwave signal with large frequency tunability, IEEE Photonics Technology Letters, vol. 23, no.11, pp.712-714, June 2011. 10. Z. Li, H. Chi, X. Zhang, J. P. Yao, Optical single-sideband modulation using a fiber-Bragg-grating-based optical Hilbert transformer, IEEE Photonics Technology Letters, vol.23, no.9, pp.558-560, May 2011. 11. J. Ni, X. M. Zhang, S. L. Zheng, X.F.Jin, H.Chi, and X. M. Zhang, Microwave frequency measurement based on phase modulation to intensity modulation conversion using fiber Bragg grating, Journal of Electromagnetic Waves and Applications, vol.25, no.5-6, pp.755-764, May 2011. 12. Z. Li, C. Wang, M. Li, H. Chi, X. Zhang, and J. P. Yao, Instantaneous microwave frequency measurement using a special fiber Bragg grating, IEEE Microwave and Wireless Components Letters, vol.21, no.1, pp.52-54, Jan. 2011.
2010 1. Lan Liu, Shilie Zheng, Jun Ji, Minghui Guo, Xianmin Zhang, Xiaofeng Jin, Hao Chi, and Yingyin Kevin Zou, Tunable frequency equalization using variable optical tilt filter in radio-over-fiber links, Microwave and Optical Technology Letters, Vol. 52, No. 11, pp.2456-2459, November 2010. 2. Z. Li, H. Chi, X. Zhang, and J. P. Yao, Pulse distortions due to third-order dispersion and dispersion mismatches in a phase-modulator-based temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology,Vol.28, No.19, pp.2865-2872, Oct. 2010. 3. Yubin Ji, Shilie Zheng, Ze Li, Xiaofeng Jin, Xianmin Zhang, and Hao Chi, Tunable fiber fabry-perot filter for PM-IM conversion and efficiency improvement in radio-over-fiber links, Microwave and Optical Technology Letters, Vol.52, No.9, pp.2090-2095, Sept. 2010. 4. Jun Ji, Shilie Zheng, Xiaofeng Jin, Xianmin Zhang, Hao Chi, and Yingyin Kevin Zou, Optical variable gain tilt filter with temperature compensation, Microwave and Optical Technology Letters, Vol.52, No.8, pp.1906-1909, Aug.2010. 5. Bo Yang, Xiao-Feng Jin, Xian-Min Zhang, Hao Chi, Shi Lie Zheng,Photonic generation of 60 GHz millimeter-wave by frequency quadrupling based on a mode-locking SOA fiber ring laser with a low modulation depth MZM, Journal of Electromagnetic Waves and Applications, Vol. 24, No. 13, pp.1773-1782, Aug. 2010. 6. Lan Liu, Shilie Zheng, Xianmin Zhang, Xiaofeng Jin, and Hao Chi, Performances improvement in raido over fiber link through carrier suppression using stimulated Brillouin scattering, Optics Express, Vol.18, No.11, pp.11827-11837, May 2010. 7. J. Ni, B. Chen, S. L. Zheng, X. M. Zhang, X. F. Jin, and H. Chi, Ultra-wideband bandpass filter with notched band based on electrooptic phase modulator and phase-shift fiber Bragg grating, Journal of Electromagnetic Waves and Application, Vol.24, No.5-6, pp.795-802, June 2010. 8. Ze Li, Bo Yang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, Photonic instantaneous measurement of microwave frequency using fiber Bragg grating, Optics Communications, Vol.283, No.3, pp.396-399, Feb. 2010. 9. Fei Zhang, Xiaofeng Jin, Xianmin Zhang, Shilie Zheng, Hao Chi, Yingyin Kevin Zou, and Jianping Yao, Fibre-optic comb filter with tunable central wavelength and channel islation at sub-microsecond speed, Electronics Letters, Vol.46, No.1, pp.71-72, Jan. 2010. 10. L. Liu, S. L. Zheng, X. M. Zhang, X. F. Jin, and H. Chi, Performance improvement of phase modulation with interferometeric detection through low-biasing, Journal of Electromagnetic Waves and Applications, Vol.24, No.1, pp.123-132, Jan. 2010.
2009 1. Shuna Yang, Chao Wang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin and Jianping Yao, Photonic analog-to-digital converter using Mach-Zehnder modulators having identical half-wave voltages with improved bit resolution, Applied Optics, Vol.48, No.22, pp.4458-4467, Aug. 2009. 2. Xiaomin Zhang, Hao Chi, Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, and Jianping Yao, Instantaneous Microwave Frequency Measurement Using an Optical Phase Modulator, IEEE Microwave and Wireless Components Letters, Vol.19, No.6, pp.422-424, June 2009. 3. X. Zou, H. Chi, and J. P. Yao, Microwave frequency measurement based on optical power monitoring using a complementary optical filter pair, IEEE Transactions on Microwave Theory and Techniques, Vol.57, No.2, pp.505-511, Feb. 2009. 4. H. Chi, X. Zou and J. P. Yao, Analytical models for phase-modulation-based microwave photonic systems with phase modulation to intensity modulation conversion using a dispersive device, IEEE/OSA Journal of Lightwave Technology, Vol.27, No.5, pp.511-521, March 2009. 5. B. Chen, S. L. Zheng, X. M. Zhang, X. M. Zhang, X. F. Jin, and H. Chi, Simultaneously realizing PM-IM conversion and efficiency improvement of fiber-optic links using FBG, Journal of Electromagnetic Waves and Applications, Vol.23, No.2-3 , pp.161-170, 2009. 6. Shuna Yang, Zhigu Shi, Hao Chi; Xianmin Zhang, Shilie Zheng, Xiaofeng Jin, and Jianping Yao, Photonic Analog-to-Digital Conversion using Multiple Comparators and Mach-Zehnder Modulators with Identical Half-Wave Voltage, Optics Communications, Vol.282, No.4, pp.504-507, Feb. 2009. 7. Yang Liu, Hao Chi, Xianmin Zhang, Xiaofeng Jin, and Shilie Zheng, A Novel Control Scheme for 4-Plate Retardation Polarization Controller, Microwave and Optical Technology Letters, Vol.51, No.1, pp.124-128, Jan. 2009.
2008 1. X. M. Zhang, S. L. Zheng, L. Liu, X. M. Liu, X. M. Zhang, X. F. Jin and H. Chi, Flattened frequency response using fiber Bragg grating V-shape filter in radio over fiber links, Journal of Electromagnetic Waves and Applications, Vol.22, No.14-15, pp.2053-2061, 2008. 2. B. Chen, S. Zheng, H. Chi, X. Zhang, and X. Jin, An optical millimeter-wave generation technique based on phase modulation and Brillouin-assisted notch-filtering, IEEE Photonics Technology Letters, Vol.20, No.24, pp.2057-2059, Dec. 2008. 3. Hao Chi, Jianping Yao, Frequency quadrupling and upconversion in a radio over fiber link, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.15, pp.2706-2711, Aug. 2008. 4. H. Chi, X. Zou and J. P. Yao, An approach to the measurement of microwave frequency based on optical power monitoring, IEEE Photonics Technology Letters, Vol.20, No.17, pp.1249-1251, July 2008. 5. H. Chi and J. P. Yao, Chirped RF pulse generation based on optical spectral shaping and wavelength-to-time mapping using a nonlinearly chirped fiber Bragg grating, IEEE/OSA Journal of Lightwave Technology, Vol.26, No.10, pp.1282-1287, May 2008. 6. H. Chi and J. P. Yao, Photonic Generation of Phase-Coded Millimeter-Wave Signal Using a Polarization Modulator, IEEE Microwave and Wireless Components Letters, Vol.18, No.5, pp.371-373, May 2008. 7. Hao Chi, Xianmin Zhang and Jianping Yao, A Novel Wavelength Shift Keying Transmitter using a Pair of Mach-Zehnder Modulators, Optics Communications, Vol.281, No.9, pp.2517-2521, May 2008. 8. Minglei Gong, Hao Chi, Xianmin Zhang, Xiaofeng Jin, and Yingyin K Zou, Reconfigurable Microwave Photonic Transversal Filter Using a Variable Gain Tilt Filter, Optics Communications, Vol.281, No.5, pp.998-1002, March 2008. 9. H. Chi and J. P. Yao, Power distribution of phase-modulated microwave signals in a dispersive fiber-optic link, IEEE Photonics Technology Letters, Vol.20, No.4, pp.315-317, Feb. 2008. 10. Guo-Feng Shen, Xian-Min Zhang, Hao Chi, Xiao-Feng Jin, Microwave/millimeter-wave generation using multi-wavelength photonic crystal fiber Brillouin laser, Progress in Electromagnetics Research (PIER), Vol.80, No.1, pp.307-329, Jan.2008. 11. H. Chi and J. P. Yao, A photonic analog-to-digital conversion scheme using Mach-Zehnder modulators with identical half-wave voltages, Optics Express, Vol.16, No.2, pp.567-574, Jan. 2008.
2007 1. H. Chi and J. P. Yao, Fiber chromatic dispersion measurement based on wavelength-to-time mapping using a femtosecond pulse laser and an optical comb filter, Optics Communications, Vol.280, No.2, pp.337-342, Dec.2007. 2. H. Chi and J. P. Yao, Waveform distortions due to second-order dispersion and dispersion mismatches in a temporal pulse shaping system, IEEE/OSA Journal of Lightwave Technology, vol. 25, no.11, pp.3528-3535, November 2007. 3. H. Chi and J. P. Yao, All-fiber chirped microwave pulse generation based on spectral shaping and wavelength-to-time conversion, IEEE Transactions on Microwave Theory and Techniques, vol. 55, no. 9, pp. 1958-1963, September 2007. 4. H. Chi and J. P. Yao, An approach to photonic generation of high-frequency phase-coded RF pulses, IEEE Photonics Technology Letters, vol. 19, no. 10, pp. 768-770, May 2007. 5. H. Chi, F. Zeng, and J. P. Yao, Photonic generation of microwave signals based on pulse shaping, IEEE Photonics Technology Letters, vol. 19, no. 9, pp. 668-670, May 2007. 6. H. Chi and J. P. Yao, Symmetrical waveform generation based on temporal pulse shaping using an amplitude-only modulator, Electronics Letters, vol. 43, no. 7, pp. 415-417, March 2007.
2006 and previous 1. Wei Jiang, Linfang Shen, Daru Chen and Hao Chi, An extended FDTD method with inclusion of material dispersion for the full-vectorial analysis of photonic crystal fibers, Journal of Lightwave Technology, Vol.24, No.11, pp.4417-4423, Nov. 2006. 2. Daru Chen, Shan Qin, Linfang Shen, Hao Chi and Sailing He, An all-fiber multi-wavelength Raman laser based on a PCF sagnac loop filter, Microwave & Optical Technology Letters, Vol.48, No.12, pp.2416-2418, Sept. 2006. 3. Qiaoqiao Cheng, Xiaofeng Jin, Hao Chi and Xianming Zhang, Tunable Fiber Fabry-Perot Filter for Optical Carrier-Suppression and Single-Sideband Modulation in Radio over Fiber Links, International Journal of Infrared and Millimeter Waves, Vol.27, No.3, pp.381-390, March 2006. 4. X. Jin, H. Chi and X. Zhang, Improving frequency response of radio over fibre system by fibre Bragg grating, Electronics Letters, Vol.42, No.6 pp.369-370, March 2006. 5. Jinyue Lu, Hao Chi, Xianmin Zhang and Linfang Shen, Noise reduction using photonic microwave filter for radio over fiber system, Microwave & Optical Technology Letters, Vol.48, No.2, pp.305-307, Feb. 2006. 6. Chi Hao, Zhang Xianmin and Shen Linfang, Design of photonic crystal fibers with anomalous dispersion, Optoelectronics Letters, Vol.2, No.1, pp.1-4, Jan. 2006. 7. Xianbin Yu, Xianmin Zhang, Hao Chi, and Kangsheng Chen, A flexible and incoherent microwave photonic filter with a flat-top passband, Microwave & Optical Technology Letters, Vol.46, No.2, pp.132-134, July 2005. 8. Xianbin Yu, Xianmin Zhang, Hao Chi, and Kangsheng Chen, Photonic Microwave Transversal Filter Employing a Fiber-Bragg-Grating-Based Resonator, Microwave & Optical Technology Letters, Vol.44, No.4, pp.369-371, April 2005. 9. Yu Xianbin, Zhang Xianmin, Chi Hao, Chen Kangsheng, Characteristics of a tunable microwave photonics notch filter based on two fiber Bragg gratings, Chinese Journal of Electronics, Vol.14, No.1, pp.184-186, Jan 2005. 10. Hao Chi and Xianmin Zhang, FIR Photonic Microwave Filter Design Employing Simulated Annealing Algorithm, International Journal of Infrared and Millimeter Waves,Vol.25, No.12, pp.1757-1764, Dec. 2004. 11. Hao Chi and Xianmin Zhang, A novel tunable fiber-optic microwave notch filter using fiber loop and cascaded fiber Bragg gratings, Microwave & Optical Technology Letters, Vol.41, No.5, pp.386-388, June 2004. 12. Chi Hao, Zeng Qingji, Zhao Huandong, Luo Jiangtao, and Zhang Zhizhong, Scheduling algorithms for OBS switch with shared buffer, IEICE Transaction on Communications, Vol.E86-B, No.7, pp.2220-2223, July 2003. 13. Jun Huang,Qingji Zeng,Hao Chi,Pengcheng Xiao,Jimin Liu,Hua Liu, Performance analysis of a novel architecture for contention resolution of optical packet switching, Chinese Optics Letters, Vol.1, No.6, pp.314-316, June 2003. 14. CHI Hao, ZENG Qingji, Zhao Huandong, Liu Hua, Xiao Shilin, Analysis on Dispersion Characteristics of Photonic Crystal Fiber, Journal of Infrared and Millimeter Waves, Vol.22, No.2, pp.149-153, Feb. 2003. 15. Jianxin Wang, Qingji Zeng, Zhizhong Zhang, Hao Chi, A novel differentiated services supporting scheme for optical burst switched networks, Chinese Optics Letters, Vol.1, No.7, pp.392-394, Jan. 2003. 16. Chi H, Tao XM, Yang DX, Chen KS, Simultaneous measurement of axial strain, temperature, and transverse load by a superstructure fiber grating, Optics Letters, Vol.26, No.24, pp.1949-1951, Dec. 2001. 著作: 专利成果: 软件成果: |
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研究领域
无线与光子融合通信研究中心 杭州电子科技大学无线与光子融合通信研究中心简介
杭州电子科技大学无线与光子融合通信研究中心专注于无线和光融合通信领域相关的研究,目前成员:池灏教授、杨波副教授(链接)、杨淑娜副教授(链接)、卢旸副教授、欧军博士、翟彦蓉博士、吕韵欣博士、高一然博士、杨镓华博士(特聘副教授)。 主要研究方向包括:可见光通信与光载无线通信、光传感、微波光子学、光接入与光网络等。目前在上述领域承担国家重点研发计划课题、国家自然科学基金面上项目和青年项目、浙江省自然科学基金重点项目和面上项目、国家重点课题以及企业委托项目等。目前实验室已经具备了较为完善的光纤电子学和微波光子学方面的实验条件,拥有微波信号发生器、任意波形发生器、矢量网络分析仪、频谱仪、光谱分析仪、实时示波器、数字采样示波器、码型发生器、误码仪、可编程光滤波器、无源脉冲激光器、可调谐激光器、空间光调制器、各类光放大器等重要仪器,以及其他各类光电和微波器件,如微波放大器、电光调制器、光电探测器、光衰减器、光纤熔接机等。 本研究中心在研众多国家/省/企业/国家重点科研项目,研究中心学术气氛浓厚,师生关系融洽,经费充足,科研条件完备,欢迎有志科研的学子报考本研究中心的研究生!
实验室地址:杭州下沙杭州电子科技大学通信工程学院(一教)202室 联系人:池灏 电话:138 5714 9768 电邮:chihao(AT)hdu.edu.cn
实验室一角
研究中心成员: 池灏,教授,硕士/博士生导师。 杨波(链接),副教授,硕士生导师。 杨淑娜(链接),副教授,硕士生导师。 卢旸,副教授,硕士生导师。 欧军,讲师。 翟彦蓉,讲师。 吕韵欣,讲师。 高一然,讲师。 杨镓华博士(特聘副教授)。
近期科研项目:
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教学与课程
教学工作 Teaching 目前主讲课程: 本科生课程:《信号与系统》 秋冬学期 研究生课程:《微波光子学》 春夏学期
××××××××××××××××××××××× ××××××××××××××××××××××× ××××××××××××××××××××××× 《信号与系统》课程 Signals and Systems 本科课程:信号与系统 课程类别:学科基础课 课程代码:A080626s 总学时数:48 开课学院:通信工程学院 面向专业:通信工程、信息对抗技术 2024-2025学年第一学期 六教-北208 周五下午 第6、7、8节,13:30~
助教:刘若晗 18868442159 一教400B --------------------------------------------------- QQ课程群 群名称:2024课程群 群 号:*** ---------------------------------------------------
交作业:每章的作业交一次,交作业的时间在该章内容讲完的下一次课。
主要章节内容: Chap.1 信号与系统 Chap.2 线性时不变系统 Chap.3 周期信号的傅里叶级数表示 Chap.4 连续时间傅里叶变换 Chap.5 离散时间傅里叶变换 Chap.6 信号与系统的时域和频域特性 Chap.7 采样 Chap.9 拉普拉斯变换
课件资料下载(包含课程讲义、英文版课件、英文教材等): 链接:https://pan.baidu.com/s/1rr0nsHarczuaq_pUdrn7oQ 提取码:课堂提供
作业 Chap.1 1.21(d); 1.22 (d), (f); 1.25 (b), (c); 1.26 (b); (d); 1.27(a); 1.28(c); 1.41
Chap.2 2.8; 2.18; 2.22(a); 2.29(a)(b); 2.38 (b); 2.39 (b); 2.46
Chap.3 3.4; 3.9; 3.15; 3.16(b); 3.21; 3.24; 3.25;
Chap.4
4.21(a); 4.22(a)(b); 4.26(a1); 4.28(a); 4.31(a); 4.44
Chap.5 5.1(a); 5.3(a) Chap.6 6.1;6.28(a)vi; Chap.7
Chap.9 9.32; 9.34; 9.37(a); 9.51
××××××××××××××××××××××× ××××××××××××××××××××××× ××××××××××××××××××××××× 《微波光子学》课程 Microwave Photonics
课程资源:包含课件、文献和参考资料、作业、报告要求等 Link Course resources: including courseware, references, homework, requirement on reportLink Chapter 1 Introduction and basic knowledge Chapter 2 Radio over Fiber Chapter 3 Microwave photonic signal generation Chapter 4 Microwave photonic signal processing Chapter 5 Photonic ADC Chapter 6 Optical OFDM Chapter 7 Optoelectronic Oscillator Chapter 8 Space-time duality Chapter 9 Microwave photonic measurement
课后习题:包括理论作业、仿真作业、专题报告及口头报告 (Exercises after class: including theoretical work, simulation work, report and oral presentation)
理论和仿真作业(Theory and simulation work): Link
专题报告和口头presentation要求 (Report and presentation): Link
口头报告时间安排(Schedule of Oral Presentation): 口头报告,请在自己理解的基础上,分享有关内容。 () 请提前准备好ppt(可转化为pdf)。 时间:每人15分钟左右
6月*日 周三 报告人:
6月*日 周三 报告人:
6月*日 周三 报告人:
另外,理论作业和仿真作业,请在最后一次上课(6月*日)的时候上交。
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