A combinational logic circuit includes input circuitry to receive a first and second input signals that transition between supply voltages of first and second voltage domain, respectively. The input circuitry generates, based on the first and second input signals, a first internal signal that transitions between one of the supply voltages of the first voltage domain and one of the supply voltages of the second voltage domain. Output circuitry within the combinational logic circuit generates an output signal that transitions between the upper and lower supply voltages of the first voltage domain in response to transition of the first internal signal.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

A device includes a memristive element; and a write circuit to write the memristive element into a memristive state of a plurality of memristive states by a write operation, wherein the memristive state has a characteristic flux and/or a characteristic charge; wherein the characteristic flux corresponds to a characteristic voltage drop over the memristive element applied for a saturation time and wherein the characteristic charge corresponds to a characteristic current through the memristive element applied for a saturation time; wherein the write operation includes: causing a write voltage drop over the memristive element that is greater than the characteristic voltage drop associated with the memristive state or causing a write current through the memristive element that is higher than the characteristic write current associated with the memristive state, each for a total write time that is shorter than the saturation time.

According to various aspects, a method is provided including: setting a memristive element into a memristive state of a plurality of memristive states, determining one or more static state parameter values of the memristive element associated with the memristive state, wherein determining the one or more static state parameter values includes: determining a current/voltage characteristic of the memristive element, and fitting the current/voltage characteristic based on a physical model to determine the one or more static state parameter values, wherein the physical model is based on static state parameters for which the static state parameter values are determined.

Linearity of a PAM-4 voltage-mode driver is improved using current compensation. The driver receives a first input data signal having a first logic level and a second input data signal having a second logic level. In an additive current mode, when the first logic level matches the second logic level, the driver uses switch circuitry to form an auxiliary current path through which supplementary current (I_Supplementary) flows from a voltage regulator. In a primary current mode, when the first logic level does not match the second logic level, the driver uses the switch circuitry to break the auxiliary current path, thereby preventing the supplementary current (I_Supplementary) from flowing from the voltage regulator.

A serial, half-duplex start/stop event detection circuit comprises a stop detection flip-flop clocked by a serial data input that takes a serial clock input as an input and generates a stop signal output indicative of a stop event. A start detection flip-flop, clocked by an inverted copy of the serial data input, takes the serial clock input as an input and generates a start signal output indicative of a start event. A first buffer flip-flop, clocked by an inverted copy of the serial clock input, takes the start signal output as an input and generates a first delayed start signal output. Similarly, a second buffer flip-flop, clocked by the serial clock input, takes the first delayed start signal output as an input and generates a second delayed start signal output. The second delayed start signal output resets at least one of said stop detection, start detection or first buffer flip-flops.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.

Asynchronous circuit elements are described. Asynchronous circuit elements include a consensus element (c-element), completion tree, and validity tree. The c-element is implemented using adjustable threshold based multi-input capacitive circuitries. The completion tree comprises a plurality of c-elements organized in a tree formation. The validity tree comprises OR gates followed by c-elements. The multi-input capacitive circuitries include capacitive structures that may comprise linear dielectric, paraelectric dielectric, or ferroelectric dielectric. The capacitors can be planar or non-planar. The capacitors may be stacked vertically to reduce footprint of the various asynchronous circuitries.