Apparatus and associated methods relate to quasi-adiabatic logic gates in which at least one supply terminal receives a periodic power signal. The quasi-adiabatic logic gate is configured to perform a specific logic function operative upon one or more input signals. When the quasi-adiabatic logic gate switches the output from one logic state to another logic state, the transient switching portion of the output signal substantially tracks the periodic supply signal. Such a periodic supply signal can be one that transitions gradually between low and high voltage levels. Such periodic supply signals results in a transient switching portion of the logic signal having lower frequency components than have traditional CMOS logic gate transients. The quasi-adiabatic logic gate has a periodic clock signal that is not in phase with the periodic power signal.

In a method computer storage element operation, first and second rising (or falling) clock edges are applied to first and second power inputs of the computer storage element having a transistor array between the first and second power inputs over time T1 whereupon a logic value applied to an input of the transistor array is stored therein. Thereafter, first and second falling (or rising) clock edges are applied to the first and second power inputs over time T2, whereupon part of an electrical charge or energy associated with the logic value stored in the transistor array is provided to circuitry that generates the first and/or second clock edge(s), wherein the value(s) of time T1 and/or time T2 is/are greater than a product of RC, where R is resistance associated with the computer storage element, and C is a load capacitance associated with the computer storage element.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.

Apparatus and associated methods relate to quasi-adiabatic logic gates in which at least one supply terminal receives sinusoidal power. The quasi-adiabatic logic gate is configured to perform a specific logic function operative upon one or more input signals. When the quasi-adiabatic logic gate switches the output from one logic state to another logic state, the transient switching portion of the output signal substantially tracks the sinusoidal supply signal. Such a sinusoidal transient switching portion of the signal has lower frequency components than have traditional CMOS logic gate transients. Some embodiments include an inductor through which the sinusoidal supply signal is provided to the quasi-adiabatic logic gate. Such an inductor can both provide charge to and recover charge from switching quasi-adiabatic logic gates, thereby further reducing power.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.

A memory cell in capacitive logic, including a bistable system including a fixed element and a mobile element capable of taking one or the other of two stable positions with respect to the fixed element; a read device including a variable-capacitance capacitor including a first fixed electrode and a second mobile electrode rigidly fixed to the mobile element; and an electrically controllable write device for placing the mobile element in one or the other of its two stable positions.

A display is provided that includes an array of display pixels that receive data signals from display driver circuitry and that receive control signals from gate driver circuitry. The gate driver circuitry may include a chain of row driver circuits. Each row driver circuit in the chain of row driver circuits may include a master driver stage, a slave driver stage, and associated control circuitry configured to receive a clock signal and a pulse signal from a preceding row driver in the chain. The master driver stage may be biased using fixed nominal power supply voltages, whereas the slave driver stage may be biased using dynamically adjustable power supply voltages that are optionally reduced relative to that of the nominal power supply voltages. One or more of the master and slave driver stages may be a bootstrapping driver stage having a bootstrapping capacitor.

A quantum charge parametron (QCP) includes a load capacitor; two quantum phase-slip junctions (QPSJs) coupled to each other through the load capacitor so as to define two charge islands, each charge island being located between the load capacitor and a respective one of the two QPSJs; at least one input voltage source coupled to the two QPSJs so that the two QPSJs, the load capacitor and the at least one input voltage source define a loop; and an excitation voltage source coupled to the two charge islands through first and second capacitors, respectively.

An adiabatic logic-in-memory based complementary metal-oxide-semiconductor/magnetic-tunnel-junction (ALiM CMOS/MTJ) circuit utilizes an adiabatic logic based pre-charged sense amplifier (PCSA) to recover energy from its output load capacitors. The ALiM CMOS/MTJ includes a non-volatile magnetic-tunnel-junction (MTJ) based memory. The ALiM CMOS/MTJ also includes a dual rail complementary metal-oxide-semiconductor (CMOS) logic that performs logic operations in association with the MTJ, and thereby generates logic outputs based on logic inputs. The ALiM CMOS/MTJ also includes the adiabatic PCSA, which is operatively coupled to the dual rail CMOS logic. The adiabatic logic based PCSA includes PCSA circuitry for which an input is a multi-phase power clock, and a charge recovery circuit having the output load capacitors. The charge recovery circuit is operatively coupled to the PCSA circuitry such that the ALiM CMOS/MTJ circuit uses the power clock to recover energy from the output load capacitors.

A logic cell, including a first capacitor connected between an application node for applying a supply voltage of the cell and a floating node for providing an output logic signal of the cell, and, connected in parallel with the first capacitor, an association in series of a second capacitor and a first variable-resistance element, the first variable-resistance element including a control electrode connected to an application node for applying a first input logic signal of the cell.