The Experts below are selected from a list of 168 Experts worldwide ranked by ideXlab platform
Dmitri B. Strukov - One of the best experts on this subject based on the ideXlab platform.
-
Memristor―CMOS Hybrid Integrated Circuits for Reconfigurable Logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches in a data routing network and were connected to gate-level CMOS components that acted as logic elements, in a manner similar to a field programmable gate array. We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
-
Memristor-CMOS Hybrid Integrated Circuits for reconfigurable logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Xuema Li, Wei Wu, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches In a data routing network and were connected to gate-level CMOS components that acted as logic elements, In a manner similar to a field programmable gate array, We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
Qiangfei Xia - One of the best experts on this subject based on the ideXlab platform.
-
Memristor―CMOS Hybrid Integrated Circuits for Reconfigurable Logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches in a data routing network and were connected to gate-level CMOS components that acted as logic elements, in a manner similar to a field programmable gate array. We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
-
Memristor-CMOS Hybrid Integrated Circuits for reconfigurable logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Xuema Li, Wei Wu, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches In a data routing network and were connected to gate-level CMOS components that acted as logic elements, In a manner similar to a field programmable gate array, We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
José M. L. Figueiredo - One of the best experts on this subject based on the ideXlab platform.
-
Stochastic induced dynamics in neuromorphic optoelectronic oscillators
Optical and Quantum Electronics, 2014Co-Authors: Bruno Romeira, Julien Javaloyes, Salvador Balle, Charles N. Ironside, José M. L. FigueiredoAbstract:We investigate the dynamics of optoelectronic oscillator (OEO) systems based on resonant tunneling diode photodetector (RTD-PD) and laser diode Hybrid Integrated Circuits. We demonstrate that RTD-based OEOs can be noise-activated in either monostable or bistable operating conditions, providing a rich variety of signal outputs—spiking, square pulses, bursting—and behaviours—stochastic and coherence resonances—that are similar to that of biological systems such as neurons. The potential for fully monolithic integration of our OEO confers them a great potential in novel neuromorphic optoelectronic Circuits for signal processing tasks including re-timing and re-shaping of pulsed signals exploiting either the monostable or the bistable operating conditions.
-
Stochastic induced dynamics in neuromorphic optoelectronic oscillators
Optical and Quantum Electronics, 2014Co-Authors: Bruno Romeira, Julien Javaloyes, Salvador Balle, Charles N. Ironside, Ricardo Avó, José M. L. FigueiredoAbstract:We investigate the dynamics of optoelectronic oscillator (OEO) systems based on resonant tunneling diode photodetector (RTD-PD) and laser diode Hybrid Integrated Circuits. We demonstrate that RTD-based OEOs can be noise-activated in either monostable or bistable operating conditions, providing a rich variety of signal outputs—spiking, square pulses, bursting—and behaviours—stochastic and coherence resonances—that are similar to that of biological systems such as neurons. The potential for fully monolithic integration of our OEO confers them a great potential in novel neuromorphic optoelectronic Circuits for signal processing tasks including re-timing and re-shaping of pulsed signals exploiting either the monostable or the bistable operating conditions.
Thomas J. Cardinali - One of the best experts on this subject based on the ideXlab platform.
-
Memristor―CMOS Hybrid Integrated Circuits for Reconfigurable Logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches in a data routing network and were connected to gate-level CMOS components that acted as logic elements, in a manner similar to a field programmable gate array. We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
-
Memristor-CMOS Hybrid Integrated Circuits for reconfigurable logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Xuema Li, Wei Wu, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches In a data routing network and were connected to gate-level CMOS components that acted as logic elements, In a manner similar to a field programmable gate array, We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
William M. Tong - One of the best experts on this subject based on the ideXlab platform.
-
Memristor―CMOS Hybrid Integrated Circuits for Reconfigurable Logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches in a data routing network and were connected to gate-level CMOS components that acted as logic elements, in a manner similar to a field programmable gate array. We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
-
Memristor-CMOS Hybrid Integrated Circuits for reconfigurable logic
Nano Letters, 2009Co-Authors: Qiangfei Xia, Thomas J. Cardinali, Warren Robinett, Michael W Cumbie, Neel Banerjee, William M. Tong, J. Joshua Yang, Xuema Li, Wei Wu, Dmitri B. StrukovAbstract:Hybrid reconfigurable logic Circuits were fabricated by integrating memristor-based crossbars onto a foundry-built CMOS (complementary metal-oxide-semiconductor) platform using nanoimprint lithography, as well as materials and processes that were compatible with the CMOS. Titanium dioxide thin-film memristors served as the configuration bits and switches In a data routing network and were connected to gate-level CMOS components that acted as logic elements, In a manner similar to a field programmable gate array, We analyzed the chips using a purpose-built testing system, and demonstrated the ability to configure individual devices, use them to wire up various logic gates and a flip-flop, and then reconfigure devices.
