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ORCIDXingyuan Tong
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2020 – today
- 2024
[j29]Xin Xin, Chang Zhang, Xingyuan Tong
:
An 11-bit Nyquist SAR-VCO Hybrid ADC with a Reused Ring-VCO for Power Reduction. Circuits Syst. Signal Process. 43(3): 1339-1365 (2024)- [j28]Dong Chen, Gaoxu Dong, Zheng Hao, Zhenfu Feng, Guifang Li, Xingyuan Tong:
An Enhanced Measurement Method With Voltage-Frequency-Voltage Conversion of EISCAP Sensor. IEEE Trans. Instrum. Meas. 73: 1-11 (2024) - 2023
- [j27]Siwan Dong, Sen Bu, Xingyuan Tong:
A 0.6-1.8 V/0.4-1.6 V Input/Output LDO with High PSRR over 50 dB/30 dB in Dual-Modes. Circuits Syst. Signal Process. 42(1): 84-106 (2023) - [j26]Chang Zhang, Xin Xin, Xingyuan Tong:
A 14-bit 1-MS/s SAR ADC with a segmented capacitor array and background mismatch calibration for IoT sensing applications. Microelectron. J. 141: 105991 (2023) - [j25]Xin Xin, Linxiao Shen, Xiyuan Tang, Yi Shen, Jueping Cai, Xingyuan Tong, Nan Sun:
A Power-Efficient 13-Tap FIR Filter and an IIR Filter Embedded in a 10-Bit SAR ADC. IEEE Trans. Circuits Syst. I Regul. Pap. 70(6): 2293-2305 (2023) - [j24]Dong Chen, Zheng Hao, Xueliang Li, Xingyuan Tong:
Enhancing the Measurement Sensitivity and Repeatability of Electrolyte-Insulator-Semiconductor Capacitor Sensor With Impedance Conversion. IEEE Trans. Instrum. Meas. 72: 1-7 (2023) - 2022
- [j23]Xin Xin, Yuanhao Hu, Jueping Cai, Siwan Dong, Xingyuan Tong:
A 0.6-V, 1.56-nW, 5.87-ppm/°C, 0.23%/V CMOS-Only Subthreshold Voltage Reference with the Threshold Voltage Difference. Circuits Syst. Signal Process. 41(8): 4256-4274 (2022) - [j22]Xingyuan Tong, Shimei Zhao, Xin Xin:
High Energy Efficiency and Linearity Switching Scheme Without Reset Energy for SAR ADC. Circuits Syst. Signal Process. 41(10): 5872-5894 (2022) - [j21]Kaiqiang Zhang, Xingyuan Tong:
A 0.6 V Fast-Transient-Response 180 nm CMOS Digital LDO with Coarse-Fine Tuning and Analog Enhancement. Circuits Syst. Signal Process. 41(11): 6513-6529 (2022) - [j20]Xingyuan Tong, Wei Jin, Chunming Zhang, Xin Xin, Siwan Dong, Qinqin Li:
A 0.6-V 12-bit 13.2-fJ/conversion-step SAR ADC with time-domain VCDL-based comparator and metastability immunity technique. Microelectron. J. 122: 105406 (2022) - [j19]Xingyuan Tong, Yuming Wei, Wen Mao, Xin Xin:
A 200 Hz-to-10 kHz bandwidth 11.83-ENOB level-crossing ADC with single continuous-time comparator. Microelectron. J. 126: 105482 (2022) - [j18]Xingyuan Tong, Hui Guo, Xin Xin, Chang Zhang, Yuanhao Hu:
A 14-bit 1.2-V low power SAR ADC with digital background calibration in 0.18 μm CMOS. Microelectron. J. 127: 105541 (2022) - [j17]Xingyuan Tong, Jinwu Wu, Dong Chen:
Low-Phase-Error Small-Area 4-Phase DLL With a Single-Ended-Differential-Single-Ended Voltage-Controlled Delay Line. IEEE Trans. Circuits Syst. II Express Briefs 69(1): 25-29 (2022) - [j16]Xingyuan Tong, Dong Liu:
High SFDR Current-Steering DAC With Splitting-and-Binary Segmented Architecture and Dynamic-Element-Matching Technique. IEEE Trans. Circuits Syst. II Express Briefs 69(11): 4233-4237 (2022) - [j15]Xingyuan Tong, Dong Liu, Ronghua Wang:
A 12-Bit Current-Steering DAC With Unary- Splitting -Binary Segmented Architecture and Improved Decoding Circuit Topology. IEEE Trans. Very Large Scale Integr. Syst. 30(10): 1391-1400 (2022) - 2021
- [j14]Siwan Dong, Yu Wang, Xingyuan Tong, Yarong Wang, Cong Liu:
A 0.3-V 8.72-nW OTA with Bulk-Driven Low-Impedance Compensation for Ultra-Low Power Applications. Circuits Syst. Signal Process. 40(5): 2209-2227 (2021) - [j13]Siwan Dong, Cong Liu, Xin Xin, Xingyuan Tong:
A three-stage OTA with hybrid active miller enhanced compensation technique for large to heavy load applications. Microelectron. J. 115: 105199 (2021) - [j12]Siwan Dong, Yarong Wang, Xin Xin, Xingyuan Tong:
A chaos-based true random number generator based on OTA sharing and non-flipped folded Bernoulli mapping for high-precision ADC calibration. Microelectron. J. 116: 105259 (2021) - [j11]Lei Wang, Wen Zhuo, Zhifang Pei, Xingyuan Tong, Wei Han, Shibo Fang:
Using Long-Term Earth Observation Data to Reveal the Factors Contributing to the Early 2020 Desert Locust Upsurge and the Resulting Vegetation Loss. Remote. Sens. 13(4): 680 (2021) - [j10]Xingyuan Tong, Dongwei An, Jie Li:
Area- and Energy-Efficient Sub-GHz Impulse Radio UWB Transmitter With Output Amplitude Enhancement for Biomedical Implants. IEEE Trans. Circuits Syst. II Express Briefs 68(6): 1807-1811 (2021) - [c10]Xin Xin, Yuanhao Hu, Xingyuan Tong:
A 10-bit SAR ADC with adaptive VCO-based comparator for sensor chip. ICTA 2021: 218-219 - [c9]Xin Xin, Shimei Zhao, Yuanhao Hu, Xingyuan Tong:
A 1st-order noise shaping SAR ADC with dual-capacitor merge-and-split switching scheme for sensor chip. ICTA 2021: 267-268 - 2020
- [j9]Xingyuan Tong, Andi Yang, Siwan Dong:
A 17.6-nW 35.7-ppm/°C Temperature Coefficient All-SVT-MOSFET Subthreshold Voltage Reference in Standard 0.18-μm N-Well CMOS. IEEE Access 8: 94043-94053 (2020)
2010 – 2019
- 2019
- [j8]Xingyuan Tong, Mengdi Song, Yawen Chen, Siwan Dong:
A 10-Bit 120 kS/s SAR ADC Without Reset Energy for Biomedical Electronics. Circuits Syst. Signal Process. 38(12): 5411-5425 (2019) - [j7]Byunghun Lee, Yaoyao Jia, S. Abdollah Mirbozorgi, Mark J. Connolly, Xingyuan Tong, Zhaoping Zeng, Babak Mahmoudi, Maysam Ghovanloo:
An Inductively-Powered Wireless Neural Recording and Stimulation System for Freely-Behaving Animals. IEEE Trans. Biomed. Circuits Syst. 13(2): 413-424 (2019) - 2017
- [j6]Xingyuan Tong, Yawen Chen:
Low-Power High-Linearity Switching Procedure for Charge-Redistribution SAR ADC. Circuits Syst. Signal Process. 36(9): 3825-3834 (2017) - [c8]Xingyuan Tong, Jie Li:
A sub-GHz UWB data transmitter with enhanced output amplitude for implantable bioelectronics. BioCAS 2017: 1-4 - [c7]Xingyuan Tong, Jie Wang:
A 1 V 10 bit 25 kS/s VCO-based ADC for implantable neural recording. BioCAS 2017: 1-4 - [c6]Xingyuan Tong, Ronghua Wang:
A 0.6 V 10 bit 120 kS/s SAR ADC for implantable multichannel neural recording. BioCAS 2017: 1-4 - [c5]Xingyuan Tong, Kangkang Wei:
A Fully Integrated Fast-Response LDO Voltage Regulator with Adaptive Transient Current Distribution. ISVLSI 2017: 651-654 - 2016
- [j5]Xingyuan Tong, Maysam Ghovanloo:
Multichannel Wireless Neural Recording AFE Architectures: Analysis, Modeling, and Tradeoffs. IEEE Des. Test 33(4): 24-36 (2016) - [j4]Xingyuan Tong, Tiantian Sun:
Improved Switching Energy Reduction Approach in Low-Power SAR ADC for Bioelectronics. VLSI Design 2016: 6029254:1-6029254:6 (2016) - [c4]Pyungwoo Yeon, Xingyuan Tong, Byunghun Lee, S. Abdollah Mirbozorgi, Bruce Ash, Helmut Eckhardt, Maysam Ghovanloo:
Toward a distributed free-floating wireless implantable neural recording system. EMBC 2016: 4495-4498 - 2015
- [j3]Wenpian Paul Zhang, Xingyuan Tong:
Noise Modeling and Analysis of SAR ADCs. IEEE Trans. Very Large Scale Integr. Syst. 23(12): 2922-2930 (2015) - 2011
- [j2]Xingyuan Tong, Yintang Yang, Zhangming Zhu, Lianxi Liu:
Novel hybrid D/A structures for high-resolution SAR ADCs - analysis, modeling and realization. Microelectron. J. 42(7): 929-935 (2011) - 2010
- [j1]Xu-Guang Guan, Xingyuan Tong, Yintang Yang:
Quasi Delay-Insensitive High Speed Two-Phase Protocol Asynchronous Wrapper for Network on Chips. J. Comput. Sci. Technol. 25(5): 1092-1100 (2010) - [c3]Shan Chen, Xingyuan Tong, Naiqiong Cai, Yintang Yang:
A 12-bit 1MS/s Non-calibrating SAR A/D Converter Based on 90nm CMOS Process. MVHI 2010: 784-787
2000 – 2009
- 2009
- [c2]Xingyuan Tong, Yintang Yang, Zhangming Zhu, Yan Xiao, Jianming Chen:
A Novel R-C Combination Based Pseudo-differential SAR A/D Converter in 90nm CMOS Process. PACCS 2009: 289-292 - [c1]Xingyuan Tong, Zhangming Zhu, Yintang Yang:
Low-power Capacitor Arrays for Charge Redistribution SAR A-D Converter in 65nm CMOS. PACCS 2009: 293-296
Coauthor Index
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