A gate driver includes a drive signal input terminal, a drive signal output terminal, a gate drive circuit, and a serial communication interface. The drive signal input terminal is configured to receive a gate drive signal. The gate drive circuit is coupled to the drive signal input terminal and the drive signal output terminal. The gate drive circuit is configured to provide the gate drive signal to the drive signal output terminal. The serial communication interface is coupled to the drive signal input terminal.

A voltage translator translates an input signal to an output signal spanning a wide range of low voltages. An input buffer receives the input signal. A level shifter provides an output control signal. A gate control circuit provides gate control signals. An output buffer provides the output signal. The level shifter includes a pair of cross coupled P-type metal oxide silicon (PMOS) transistors each in series with an N-type metal oxide silicon (NMOS) transistor. A third NMOS transistor is coupled between an upper rail and a drain of one PMOS transistor; the gate of the third NMOS transistor is controlled by a first input control signal. A fourth NMOS transistor is coupled between the upper rail and a drain of the other PMOS transistor; the gate of the fourth NMOS transistor is controlled by a second input control signal.

There is disclosed a self-timed processor. The self-timed processor includes a plurality of functional blocks comprising null convention logic. Each of the functional blocks outputs one or more multi-rail data values. A global acknowledge tree generates a global acknowledge signal provided to all of the plurality of functional blocks. The global acknowledge signal switches to a first state when all of the multi-rail data values output from the plurality of functional blocks are in respective valid states, and the global acknowledge signal switches to a second state when all of the multi-rail data values output from the plurality of functional blocks are in a null state.

According to the invention, only one type of enhancement MOS transistor type is used in implementing typical Boolean functions in hardware. Preferably, the MOS transistor type allows back bias control for adjusting and compensating the operation conditions. When implemented in PMOS only transistors, the pull-down functionality is performed by a single transistor with its gate and source connected to the output, This type of connection ensures that the pull-down functionality is performed by the leakage current of the pull-down transistor. The leakage currents of all the pull-up transistors need to be smaller than this pull-down current when all the pull-up paths are off. The ratio of these off-currents can be adjusted by the aspect ratios of the transistors. The logic type offers extremely low current consumption with low voltages and offers the possibility to avoid more complex shut-down circuitry often used in ultra low-power designs. The logic type offers higher operation speed compared to the existing solutions.

Integrated circuits described herein implement an x-input logic gate. The integrated circuit includes a plurality of Schottky diodes that includes x Schottky diodes and a plurality of source-follower transistors that includes x source-follower transistors. Each respective source-follower transistor of the plurality of source-follower transistors includes a respective gate node that is coupled to a respective Schottky diode. A first source-follower transistor of the plurality of source-follower transistors is connected serially to a second source-follower transistor of the plurality of source-follower transistors.

A buffer circuit includes a buffer group including an odd number of cascade buffers, where the buffers may be different from each other; a PMOS transistor and an NMOS transistor; where a source of the PMOS transistor is coupled to a power source, a drain thereof is connected to an output terminal of the buffer group, and a gate thereof is connected to an input terminal of the buffer group; a source of the NMOS transistor is coupled to ground, a drain thereof is connected to the output terminal of the buffer group, and a gate thereof is connected to the input terminal of the buffer group.

Electronic devices employing adiabatic logic circuits with wireless charging are disclosed. In one aspect, an electronic device is provided. The electronic device includes a power circuit employing an alternating current (AC) coupler circuit configured to receive a wireless AC signal and generate a wired AC signal based on the wireless AC signal. The power circuit includes a power output configured to provide an AC power signal based on the wired AC signal generated by the AC coupler circuit. The AC power signal is generated based on the wireless charging capability of the AC coupler circuit. The electronic device employs a digital logic system that includes a power rail electrically coupled to an adiabatic logic circuit. The AC power signal is provided to the power rail to provide power to the adiabatic logic circuit. Wirelessly charging the adiabatic logic circuit consumes less power than conventional non-wireless charging circuitry.

A Low Voltage Differential Signaling (LVDS) transmitter includes driver circuit with a first transistor, a second transistor, a third transistor, a fourth transistor, a first resistor, and a second resistor. The first transistor is coupled between a first node and first output. The second transistor is coupled between the first node and a second output. The third transistor is coupled between the first output and a second node. The fourth transistor is coupled between the second output and the second node. The first resistor is coupled between the first output and a common mode node. The second resistor is coupled between the second output and the common mode node. A pre-driver circuit generates gate control signals controlling the first, second, third, and fourth transistors in response to a data signal. A controlled timing delay is applied to the timing of logic state transistors for the control signals.

Integrated circuits described herein implement an x-input logic gate. The integrated circuit includes a plurality of Schottky diodes that includes x Schottky diodes and a plurality of source-follower transistors that includes x source-follower transistors. Each respective source-follower transistor of the plurality of source-follower transistors includes a respective gate node that is coupled to a respective Schottky diode. A first source-follower transistor of the plurality of source-follower transistors is connected serially to a second source-follower transistor of the plurality of source-follower transistors.

An asynchronous circuit including an asynchronous pipeline including two or more stages, each stage having: a buffering circuit for temporarily storing data to be transferred from one stage to the next based on a handshake protocol, the buffering circuit including a non-volatile memory; and a data presence detection circuit adapted to generate a data presence detection value indicating whether or not data is stored by the buffering circuit; and a control circuit adapted to perform a data back-up operation by independently controlling each buffering circuit to back-up the data it stores to its non-volatile memory based on the corresponding data presence detection value.