范世全,西安交通大学微电子学院副教授,博士生导师,工学博士学位。
Shiquan Fan, Ph.D.
Associate Professor
Welcome - 范 世全
欢迎对集成电路设计、测试、工艺及器件模型感兴趣的同学报考研究生!
CMOS mixed-signal integrated circuit, solid-state device, CMOS based MEMS/NEMS interface circuit
通信地址:西安市咸宁西路28号,西安交通大学微电子学院,邮编:710049
Address: School of Microelectronics, Xi'an Jiaotong University, No. 28 Xianning West Road, Xi'an, Shaanxi, 710049, China
E-mail: junjunfan@xjtu.edu.cn
Tel: 029-82663426(院办)
Phone:+86-13519188351
办公室: 1)交大兴庆校区西一楼238;
2)中国西部科技创新港泓理楼4-4046。
-
2019-07-13
-
2019-06-11
-
2019-03-15
-
2019-02-27
-
2019-02-13
-
2019-01-29
-
1) Integrated power management for portable device;
2) SRAM array with power management;
3) Wireless power transfer and energy harvester;
4) SOC(state-of-charge);
5) Wearable device;
6) CMOS based MEMS/NEMS interface circuit.
7) Vector control algorithm for BLDC motor.
19) 基本科研业务费(自由探索与创新)项目。
18) 横向课题,DC-DC芯片。
17) 横向课题,RRAM设计。
16) 国家自然科学基金项目,面向超宽频段声场的高效率音频能量俘获芯片关键技术研究。
15) XXXX,低功耗电源。
14) XXXX,ETPA。
13) 国家自然科学基金项目,高速、宽带移动通信功率放大器效率提升与线性放大的超数字增强关键问题研究。
12) 基本科研业务费(重点培育)项目。
11) 国家重点研发计划项目,3D打印。
10) 陕西省博士后科学基金项目,基于MOLDO结构全集成低噪声电源管理关键技术研究。
9) 国家自然科学基金项目,一种具有双工作模式的触觉传感器的研究。
8) 国家重点研发计划项目,移动关键技术。
7) 国家自然科学基金项目,基于动态匹配的高能量利用率多层堆叠结构SRAM关键技术。
6) 国家自然科学基金项目,超宽电压静态随机存储器及其多路动态电源管理关键技术。
5) 国家自然科学基金项目,基于DVS的高效动态电压变换器集成设计理论与方法。
4) 国家自然科学基金项目,随机掺杂纳米SOI MOSFETs器件模型研究。
3) 中国博士后科学基金项目,基于堆叠结构静态随机存储器的高效电源管理关键技术研究。
2) 陕西省博士后科研配套项目。
1) 西安交通大学新讲师科研启动项目。
1)英文期刊论文/English Journal Papers:
[17] A 100 MHz, 0.8-to-1.1 V, 170 mA Digital LDO with 8-Cycles Mean Settling Time and 9-Bit Regulating Resolution in 180-nm CMOS [J]. IEEE Transactions on Circuits and Systems II: Express Briefs, 2020.
[16] An Open Loop Digitally Controlled Hybrid Supply Modulator Achieving High Efficiency for Envelope Tracking With Baseband up to 200-MHz [J]. IEEE Transactions on Circuits and Systems I: Regular Papers, 2020.
[15] A 2.45-GHz Rectifier-Booster Regulator With Impedance Matching Converters for Wireless Energy Harvesting [J]. IEEE Transactions on Microwave Theory and Techniques, 2019.
[14] Stacked Multi-Channel Receiver Architecture for Power-Efficient High-Speed Optical Links [J]. IEEE Photonics Technology Letters, 2019.
[13] A 13.56 MHz, 94.1% Peak Efficiency CMOS Active Rectifier with Adaptive Delay Time Control for Wireless Power Transmission Systems [J]. IEEE Journal of Solid-State Circuits, 2019.
[12] Topological Classification Based Splitting-Combining Methodology for Analysis of Complex Multi-Loop Systems and Its Application in LDOs [J]. IEEE Transactions on Power Electronics, 2018.
[11] [TPE Highlighted Paper] An Ultra-Low Quiescent Current Power Management System with Maximum Power Point Tracking (MPPT) for Battery-Less Wireless Sensor Applications [J]. IEEE Transactions on Power Electronics, 2018.
[10] Theoretical Model of EnDP to Achieve Energy-Efficient SRAM [J]. IEEE Transactions on Circuits and Systems –I, 2017.
[9] A 5.2 μA Quiescent Current LDO Regulator with High Stability and Wide Load Range for CZT Detectors [J]. IEEE Transactions on Nuclear Science, 2017.
[8] Analysis and Implementation of High-Performance Integrated KY Converter [J]. IEEE Transactions on Power Electronics, 2017.
[7] A 0.6-V 10-bit 200-kSs Fully Differential SAR ADC With Incremental Converting Algorithm for Energy Efficient Applications [J]. IEEE Transactions on Circuits and Systems –I, 2016.
[6] VRSPV Soft-start Strategy and AICS Technique for Boost Converters to Improve the Start-up Performance [J]. IEEE Transactions on Power Electronics, 2015.
[5] Area-Efficient On-chip DC-DC Converter with Multiple-output for Bio-medical Applications [J]. IEEE Transactions on Circuits and Systems –I, 2014.
[4] A 0.2 V-1.8 V 8T SRAM with Bit-interleaving Capability [J]. IEICE Electronics Express, 2014.
[3] A transient enhanced DVS DC-DC converter based on state trajectory analysis [J]. Analog Integrated Circuit and Signal Process, 2014.
[2] A Novel Buck/LDO Dual-Mode DC-DC Converter for Efficiency Improvement [J]. Journal of Semiconductors, China, 2013.
[1] Design and implementation of a mixed-signal Boost converter with a novel multi-phase clock DPWM [J]. IEICE Electronics Express, 2010.
2)中文期刊论文/Chinese Journal Papers:
[4] DCM反向电流优化全集成KY变换器设计, 微电子学与计算机, 2017.
[3] 基于电容耦合技术的快瞬态高稳定性LDR设计, 微电子学与计算机, 2015.
[2] 2.2MHz,8.3mW多位量化连续时间Sigma-Delta 调制器设计, 微电子学与计算机, 2014.
[1] DC-DC变换器的改进型仿TYPE-III全集成补偿网络设计, 新型工业化, 2012.
3)会议论文/Conference Papers:
[31] A 100 MHz, 0.8-to-1.1 V, 170 mA Digital LDO with 8-Cycles Mean Settling Time and 9-Bit Regulating Resolution in 180-nm CMOS [C]. IEEE ISICAS, 2020.
[30] Design of Improved KY Converter with Low Power ZCD Circuit for Wide Load Current Application [C]. IEEE ICTA, 2020.
[29] A 100 mV Input Voltage, Multi-step Self-Startup Boost Converter Achieving 50X Voltage Step-up with Standard 0.18 µm CMOS Process for Energy Harvesting application [C]. IEEE ICTA, 2020.
[28] [Invited Talk] A Cross-Coupled Active Rectifier-Booster Regulator Integrated Circuit for Broadband Wireless Energy Harvesting System [C]. IEEE IWS, 2020.
[27] [Invited Talk] Active Rectifiers in Wireless Power Transmission Systems [C]. IEEE ICICDT, 2019.
[26] [Invited Talk] Vibration Energy Powered Wireless Temperature Sensors in Power Plant Application [C]. VEH2, 2019.
[25] A 225-mA Binary Searching Digital LDO with Transient Enhancement [C]. IEEE EDSSC, 2019.
[24] A Fully Integrated CMOS Active Rectifier-Booster Regulator for RF Energy Harvesting [C]. IEEE EDSSC, 2019.
[23] A Stacked 4X25Gb/s Optical Receiver in 28nm CMOS with 0.154mW/Gb/s Power Efficiency [C]. IEEE ISCAS, 2019.
[22] A Robust Differential 4x28Gb/s Stacked Optical Receiver in 28nm CMOS Realizing Crosstalk Suppression and Power Supply Rejection [C]. IEEE ICTA, 2019.
[21] A Low-Power 0.8% Sensing Error On-Chip Current Sensor with Auto-Accuracy Adjustment [C]. IEEE ICTA, 2018.
[20] A Novel Rectenna Array with RBR for Long-Distance WLAN Energy Harvesting System [C]. IEEE WPTC, 2018.
[19] Low Power On/Off Control Method for Active-Diode Applied in Wireless Power Transmission [C]. IEEE WPTC, 2018.
[18] A High-Efficiency Radio Frequency Rectifier-Booster Regulator for Ambient WLAN Energy Harvesting Applications [C]. IEEE IWS, 2018.
[17] A Reconfigurable Multi-Ratio Charge Pump with Wide Input/Output Voltage Range for Wireless Energy Harvesting System [C]. IEEE IWS, 2018.
[16] Microwave Surface Resistance/Resistivity Measurement Using Microstrip Complementary Split Ring Resonator Sensor [C]. IEEE IWS, 2018.
[15] Vibrational Energy Harvesting System with MPPT for IoT Applications [C]. IEEE WiPDA, 2018.
[14] Three-Layer Structure Triboelectric Electricity Generator with ULP Rectifier for Mechanical Energy Harvester [C]. IEEE WiPDA, 2018.
[13] A Near-Zero-Power Temperature Sensor with +/-0.24 ℃ Inaccuracy Using Only Standard CMOS Transistors for IoT Applications [C]. IEEE ISCAS, 2018.
[12] Single-Stage Dual-Output AC-DC Converter for Wireless Power Transmission [C]. IEEE CICC, 2018.
[11] [Invited Paper] An Ultra-Low Power (ULP) Zero-Current-Detector (ZCD) Circuit for Switching Inductor Converter Applied in Energy Harvesting System [C]. IEEE EDAPS, 2017.
[10] mm-Scale and MEMS Piezoelectric Energy Harvesters Powering on-Chip CMOS Temperature Sensing for IoTs Applications [C]. IEEE Transducers, 2017.
[9] An Ultra-Low Quiescent Current Power Management ASIC with MPPT for Vibrational Energy Harvesting [C]. IEEE ISCAS, 2017.
[8] An Auxiliary Switched-Capacitor Power Converter (SCPC) Applied in Stacked Digital Architecture for Energy Utilization Enhancement [C]. IEEE ISCAS, 2017.
[7] A Battery-Less, 255 nA Quiescent Current Temperature Sensor with Voltage Regulator Fully Powered by Harvesting Ambient Vibrational Energy [C]. IEEE ISCAS, 2017.
[6] A Delay Time Controlled Active Rectifier with 95.3% Peak Efficiency for Wireless Power Transmission Systems [C]. IEEE ISCAS, 2017.
[5] On-Chip Type III Compensator by Using Constant-Gm OTAs and Capacitor-Multipliers for Fully Integrated Buck Converters [C]. IEEE ICSICT, 2016.
[4] Minimized Start-up Transient and Initial Inrush Current of Boost Converter for LED Lighting [C]. IEEE ISIE, 2013.
[3] A Novel Zero-Current-Detector for DCM Operation in Synchronous Converter [C]. IEEE ISIE, 2012.
[2] A Novel Adaptive Delay-Tracking ADC for DVS Power Management Applications [C]. IEEE RFIT, 2011.
[1] An Algorithmic ADC Applied in Digital Controlled Switched DC-DC Converters [C]. IEEE ICSICT, 2010.
4)授权专利/Authorized Patents:
[14] 一种适用于多层堆叠负载的多路输出开关电容变换器. 中国,ZL201810699845.2 [P].
[13] 一种具有纳米结构的摩擦发电机. 中国,ZL201810434177.0 [P].
[12] 一种CMOS全集成近零功耗温度传感器. 中国,ZL201810237184.1 [P].
[11] DC-DC变换器的导通时间校正定频跨周期控制器及方法. 中国,ZL201510505777.8 [P].
[10] 逐次逼近型模数转换器的全差分增量采样方法. 中国,ZL201510378978.6 [P].
[9] 双沿超前校正增强比较器及其有源全桥整流器: 中国, ZL 201410627705.6 P].
[8] 基于DAC技术的新型软启动电路及软启动方法: 中国, ZL 201110237831.7 [P].
[7] 高效宽电压转换范围多模DC-DC变换器: 中国, ZL 200910022844.5 [P].
[6] 一种无电感双输出降压型DC-DC变换器: 中国, ZL 201210003885.1 [P].
[5] 基于恒定跨导放大器和电容乘法器的片上全集成补偿网络: 中国, ZL 201310208472.1 [P].
[4] 栅压摆幅控制BUCK-BOOST开关电源变换器: 中国, ZL 201010246326 [P].
[3] 一种数字控制开关DC-DC变换器用模数转换器: 中国, ZL 201010246353.1 [P]
[2] 一种提高集成开关DC-DC变换器轻载效率非均匀变化栅宽的方法: 中国, ZL 201010246249 [P].
[1] 数据后续处理软件: 中国, ZL 2010SR060721[P].
5)其他/Others:
[21] 西安交通大学本科生专业实习优秀团队,2020.
[20] Lam Research Thesis Award奖学金1项, 2020.
[19] 西安交通大学优秀硕士学位论文,2020.
[18] “华为杯”第三届中国研究生创“芯”大赛优秀指导教师, 2020.
[17] 指导学生获“华为杯”第三届中国研究生创“芯”大赛全国总决赛二等奖, 2020.
[16] 第三届全国大学生集成电路创新创业大赛优秀指导教师2项, 2019.
[15] 指导学生获第三届全国大学生集成电路创新创业大赛--燕东微电子杯西北赛区三等奖2项, 2019.
[14] 西安交通大学优秀班主任,2019.
[13] 西安交通大学本科生专业实习优秀团队,2019.
[12] 陕西省高等学校科学技术一等奖, 2019.
[11] 第二届全国大学生集成电路创新创业大赛优秀指导教师2项, 2018.
[10] 指导学生获第二届全国大学生集成电路创新创业大赛--紫光展锐杯全国总决赛一等奖, 2018.
[9] 指导学生获第二届全国大学生集成电路创新创业大赛--ARM杯全国总决赛三等奖, 2018.
[8] 指导学生获第二届全国大学生集成电路创新创业大赛--紫光展锐杯西北赛区一等奖, 2018.
[7] 指导学生获第二届全国大学生集成电路创新创业大赛--ARM杯西北赛区一等奖, 2018.
[6] 西安交通大学优秀博士学位论文, 2017.
[5] 信源通优秀博士论文基金, 2016.
[4] 陕西省科学技术三等奖, 2015.
[3] Lam Research奖学金2项, 2015.
[2] 国家优秀博士研究生奖学金, 2013.
[1] 全国大学生节能减排大赛特等奖, 2011.
(创新港)
