徐权 副高职称



部门： 电子信息工程系
办公地址： 文约楼603
E-MAIL： xuquan@cczu.edu.cn


办公电话： **












教育经历
2018.08 – 2019.08 英国利物浦大学 电气工程与电子系访问****2007.09 – 2011.06 电子科技大学光电信息学院 光学工程专业 工学博士2005.09 – 2007.07 电子科技大学物理与电子学院 光学专业 理学硕士2001.09 – 2005.07 淮阴师范学院物理与电子学系 物理学专业 理学学士

工作履历
2018.07 – 至今 常州大学 副教授、硕士生导师2011.07 – 2018.06 常州大学 讲师


学术兼职
担任IEEE Trans. Circuits and System I、IEEE Trans. Circuits and System II、IEEE ACCESS、Chaos Solitons and Fractals等学术刊物的论文评审人；
担任中国电子学会电路与系统分会混沌与非线性电路专业委员会委员。



研究领域
研究方向：
神经元功能性电路；
神经元网络与同步；
非线性电路与系统。




教学工作
《通信电子电路》、《电工与电子技术》、《电工技术》。



科研项目
纵向项目：
省高校优秀科技创新团队项目。团队名称：忆阻电路与智能网络，资助金额：30万元，起止年月：2020.07-2022.06。（骨干成员）
国家自然科学基金面上项目。项目名称：忆阻电路的复杂动力学与多稳定状态控制策略研究，项目编号：**，资助金额：57万元，起止年月：2018.01-2021.12。（参与）
国家自然科学基金青年基金项目。项目名称：非自治忆阻振荡电路的动力学行为分析及在忆阻神经形态电路中的延拓，项目编号：**，资助金额：23万元，起止年月：2019.01-2021.12。（主持）
国家自然科学基金青年基金项目。项目名称：忆阻电路韦库降维建模、多稳定性重构及系统延拓研究，项目编号：**，资助金额：17万元，起止年月：2017.01-2019.12。（参与）
国家自然科学基金青年基金项目。项目名称：忆阻阈值模型及忆阻应用电路特性研究，项目编号：**，资助金额：17万元，起止年月：2017.01-2019.12。（参与）
江苏省基础研究计划（自然科学基金）青年基金项目。项目名称：周期激励忆阻电路的复杂动力学行为特性及其应用研究，项目编号：BK**，资助金额：20万元，起止年月：2016.07-2019.06。（主持）
江苏省高校自然科学研究面上项目。项目名称：8字形散射体光子晶体特性及应用研究，项目编号：14KJB430004，资助金额：3万元，起止年月：2014.08-2016.02。（主持）




奖励与荣誉
奖励：
“忆阻应用电路与多稳定性理论,”2018年度江苏省教育科学研究成果奖（高校自然科学类）一等奖, 2018.08.
“Extreme multistability in a memristive circuit,” “IET Premium Award Winner 2018” 最佳论文奖, 2018.06.
“‘双引擎四驱动’校企联合培养机制的构建与实践,” 江苏省教学成果奖（高等教育类）二等奖,2017.10.
“Numerical analyses and breadboard experiments of twin attractors in two-neuron-based non-autonomous Hopfieldneural network,” “IWAWA2018 Excellent theses”优秀论文，2018.09.
荣誉：
2019年立项省高校优秀科技创新团队“忆阻电路与智能网络”骨干成员，2019.11.
2016年常州大学信息科学与工程学院教书育人先进个人，2017.01.

2016年江苏省大学生创新创业优秀论文指导教师，2016.12.




学术成果
教材与专著

包伯成, 徐权, 包涵. 忆阻电路与多稳定性, 北京: 科学出版社, 30万字, 2018.7.
储开斌，武花干，徐权，何宝祥.“十二五”江苏省高等学校重点教材《模拟电路及其应用(第三版)》，北京：清华大学出版社，47.9万字，2017.6

发表论文（2016年以后，部分SCI检索论文）

“Symmetrically scaled coexisting behaviors in two types of simple jerk circuits,” Circuit World, 2020, doi: 10.1108/CW-02-2020-0028.
“Bifurcation analyses and hardware experiments for bursting dynamics in non-autonomous memristive FitzHugh-Nagumo circuit,” Science China Technological Sciences, 2020, doi:10.1007/s11431-019-1458-5.
“Hidden dynamics in a fractional-order memristive Hindmarsh-Rose model,”Nonlinear Dynamics, 2020, 100(1): 891-906.
“Hyperchaos, quasi-period and coexisting behaviors in second-order-memristor-based jerk circuit,” The European Physical Journal Special Topics, 2020, 229(6-7), 1045-1058.
“Memristor synapse-basedMorris-Lecar model:Bifurcation analyses and FPGA-based validations for periodic and chaotic bursting/spiking firings,” International Journal of Bifurcation and Chaos, 2020, 30(3): **.
“Interpreting initial offset boosting via reconstitution in integral domain,” Chaos, Solitons and Fractals, 2020, 131: 109544.
“Memristor synapse-based Morris-Lecar model: Bifurcation analyses and FPGA-based validations for periodic and chaotic bursting/spiking firings,” International Journal of Bifurcation and Chaos, 2020, 30(3): **.
“Inductor-free multi-stable Chua’s circuit constructed by improved PI-type memristor emulator and active Sallen-Key high-pass filter,” The European Physical Journal Special Topics, 2019, 228(10), 1983-1994.
“Periodically switched memristor initial boosting behaviors in memristive hypogenetic jerk system,” IEEE Access, 2019, 7: 145022-145029.
“Extremely slow passages in low-pass filter-based memristive oscillator,” Nonlinear Dynamics, 2019, 97: 2339–2353.
“Simple non-autonomous hidden chaotic system with a switchable stable node-focus,” Int. Journal of Bifurcation and Chaos, 2019, 29(11): **.
“Chaotic bursting dynamics and coexisting multi-stable firing patterns in 3D autonomous M-L model and microcontroller-based validations,” Int. Journal of Bifurcation and Chaos, 2019, 29(10): **.
“Non-ideal memristor synapse-coupled bi-neuron Hopfield neuralnetwork: Numerical simulations and breadboard experiments,” AEü-International Journal of Electronics and Communications, 2019, 111, 152894.
“Hybrid state variable incremental integral for reconstructing extreme multistability in memristive jerk system with cubic nonlinearity,” Complexity, 2019, Article ID **.
“Dynamical effects of neuron activation gradient on Hopfield neural network: Numerical analyses and hardware experiments,” Int. Journal of Bifurcation and Chaos, 2019, 29(4): **.
“Memristor initial boosting behaviors in a two-memristor-based hyperchaotic system,” Chaos, Solitons and Fractals, 2019, 121: 178-185.
“Initial conditions-related dynamical behaviors in PI-type memristor emulator-based canonical Chua’s circuit,” Circuit World, 2018, 44(4): 178-186.
“Two-neuron-based non-autonomous memristive Hopfield neural network: Numerical analyses and hardware experiments,” AEü-International Journal of Electronics and Communications, 2018, 96, 66-74.
“State variable mapping method for studying initial-dependent dynamics in memristive hyper-jerk system with line equilibrium,” Chaos, Solitons and Fractals, 2018, 115: 313-324.
“Numerical analyses and breadboard experiments of twin attractors in two-neuron-based non-autonomous Hopfield neural network,” The European Physical Journal Special Topics, 2018, 227, 777-786.
“Third-order RLCM-four-elements-based chaotic circuit and its coexisting bubbles,” AEü- International Journal of Electronics and Communications, 2018, 94, 26-35.
“Flux-charge analysis of initial state-dependent dynamical behaviors in a memristor emulator-based Chua's circuit,” Int. Journal of Bifurcation and Chaos, 2018, 28(10): **.
“Crisis induced coexisting multiple attractors in a second-order non-autonomous memristive diode bridge-based circuit,” International Journal of Circuit Theory and Applications, 2018, 46(10), 1917-1927.
“AC induced coexisting asymmetric bursters in the improved Hindmarsh-Rose model,” Nonlinear Dynamics, 2018(June), 92(4): 1695–1706.
“Chaos in a second-order non-autonomous Wien-bridge oscillator without extra nonlinearity,” Circuit World, 2018, 44(3): 108-114.
“Memristor-based canonical Chua’s circuit: Extreme multi-stability in voltage-current domain and its controllability in flux-charge domain,” Complexity, 2018, Article ID **.
“Three- dimensional memristive Hindmarsh-Rose neuron model with hidden coexisting asymmetric behaviors,” Complexity, 2018, Article ID **.
“Controlling extreme multistability of memristor emulator-based dynamical circuit in flux-charge domain,” Nonlinear Dynamics, 2018, 91(2): 1395-1412.
“Numerical and experimental confirmations of quasi-periodic behavior and chaotic bursting in third-order autonomous memristive oscillator,” Chaos, Solitons and Fractals, 2018(Jan.), 106: 161-170.
“Numerical analyses and experimental validations of coexisting multiple attractors in Hopfield neural network,” Nonlinear Dynamics, 2017, 90(4), 2359-2369.
“An improved memristive diode bridge-based band pass filter chaotic circuit,” Mathematical Problems in Engineering, 2017, 2017(4): **.
“Coexisting behaviors of asymmetric attractors in hyperbolic-type memristor based Hopfield neural network,” Frontiers in Computational Neuroscience, 2017, 11(Article 81): 1-14.
“Non-autonomous second-order memristive chaotic circuit,” IEEE Access, 2017, 5(1): 21039-21045.
“Chaotic bursting in memristive diode bridge coupled Sallen-Key low-pass filter,” Electronics Letters, 2017(Aug.), 53(16): 1104-1105.
“A simple third-order memristive band pass filter chaotic circuit,” IEEE Transactions on Circuits and Systems -II: Express Briefs, 2017, 64(8): 977-981.
“Multistability induced by two symmetric stable node-foci in modified canonical Chua’s circuit,” Nonlinear Dynamics, 2017(Jan.), 87(2): 789-802.
“Hidden extreme multistability in memristive hyperchaotic system,” Chaos, Solitons and Fractals, 2017(Jan.), 94: 102-111.
“Coexisting infinitely many attractors in active band-pass filter-based memristive circuit,” Nonlinear Dynamics, 2016 (Nov.), 86(3): 1711-1723.
“A feasible memristive Chua's circuit via bridging a generalized memristor,” Journal of Applied Analysis and Computation, 2016(Nov.), 6(4), 1152-1163.
“Extreme multistability in a memristive circuit,” Electronics Letters, 2016, 52(12): 1008-1010.
“Multistability in Chua's circuit with two stable node-foci,” Chaos, 2016, 26(4): 043111.
“Inductor-free simplified Chua’s circuit only using two-op-amps-based realization,” Nonlinear Dynamics, 2016 (Apr.), 84(2): 511-525.
“Hidden attractors in a practical Chua's circuit based on a modified Chua's diode,” Electronics Letters, 2016, 52(1): 23-25.
“Multiple attractors in a non-ideal active voltage-controlled memristor based Chua's circuit,” Chaos, Solitons and Fractals, 2016, 83, 186-200.
“Chaotic and periodic bursting phenomena in a memristive Wien-bridge oscillator,” Nonlinear Dynamics, 2016(Jan.), 83(1), 893-903.
专利成果
“基于广义忆阻Colpitts振荡器的混沌信号发生器,” 发明专利, 申请号：ZL-2014-1-**.9, 授权公告日：2017.07.14.