Adiabatic Capacitive Logic using Voltage-controlled Variable Capacitors

“…This requires signal conditioning circuits which consist of buffers to prevent distortion of the source signals, parasitic signal removing elements to get rid of the parasitic signals and amplifier for amplifying the output signals of one resonator as input into the next resonator. Note that the approach in this study is compatible with adiabatic CMOS approach as reported in [37][38][39][40] and both CMOS and NEMS can be integrated together to harness the advantages of both concepts. Ankur et al [41,42] also reported quantum computations using microring resonator in manipulating polarization encoded Qubit to perform reversible logic operations.…”

Toward cascadable MEMS logic device based on mode localization

“…This requires signal conditioning circuits which consist of buffers to prevent distortion of the source signals, parasitic signal removing elements to get rid of the parasitic signals and amplifier for amplifying the output signals of one resonator as input into the next resonator. Note that the approach in this study is compatible with adiabatic CMOS approach as reported in [37][38][39][40] and both CMOS and NEMS can be integrated together to harness the advantages of both concepts. Ankur et al [41,42] also reported quantum computations using microring resonator in manipulating polarization encoded Qubit to perform reversible logic operations.…”

Toward cascadable MEMS logic device based on mode localization

A nanoelectromechanical energy-reversible switch: theoretical study and verification by experiment of its applicability to adiabatic computing

RF Reflectometry of NEMS Motional Capacitance with Micromanipulator Probe