A single flux quantum (SFQ) circuit can include a combinational logic network, which can include a set of SFQ logic cells. The SFQ circuit can also include an SFQ sequencing circuit, which can be used to generate delayed versions of clock pulses to clock the set of SFQ logic cells.

A circuit for use in a processor includes a first processing channel having a first logic unit, a second processing channel having a second logic unit, and multiplexing circuitry. The multiplexing circuitry includes an input multiplexer arranged to switch between a first state in which an input of the first logic unit is coupled to an input line of the first processing channel, and a respective second state in which the input of the first logic unit is instead coupled to an input line of the second processing channel; and an output multiplexer arranged to switch between a first state in which an output line of the second processing channel is coupled to an output of the second logic unit, and a second state in which the output line of the second processing channel is instead coupled to an output of the first logic unit.

Provided is a semiconductor device including a sequential circuit including a first transistor and a capacitor. The first transistor includes a semiconductor layer including indium, zinc, and oxygen to form a channel formation region. A node electrically connected to a source or a drain of the first transistor and a capacitor becomes a floating state when the first transistor turns off, so that a potential of the node can be maintained for a long period. A power-gating control circuit may be provided to control supply of power supply potential to the sequential circuit. The potential of the node still can be maintained while supply of the power supply potential is stopped.

A circuit for use in a processor includes a first processing channel having a first logic unit, a second processing channel having a second logic unit, and multiplexing circuitry. The multiplexing circuitry includes an input multiplexer arranged to switch between a first state in which an input of the first logic unit is coupled to an input line of the first processing channel, and a respective second state in which the input of the first logic unit is instead coupled to an input line of the second processing channel; and an output multiplexer arranged to switch between a first state in which an output line of the second processing channel is coupled to an output of the second logic unit, and a second state in which the output line of the second processing channel is instead coupled to an output of the first logic unit.

A low power sequential circuit (e.g., latch) uses a non-linear polar capacitor to retain charge with fewer transistors than traditional CMOS sequential circuits. The sequential circuit includes a 3-input majority gate having first, second, and third inputs, and a first output. The sequential circuit includes a driver coupled to the first output, wherein the driver is to generate a second output. The sequential circuit further includes an exclusive-OR (XOR) gate to receive a clock and the second output, wherein the XOR gate is to generate a third output which couples to the second input, where the first input is to receive a data, and wherein the third input is to receive the second output.

A semiconductor device includes a plurality of functional blocks, each being configured to provide at least one predetermined function. The functional blocks at least include a first functional block and a second functional block. The first functional block and the second functional block are coupled in serial with a predetermined current flowing therethrough.

A semiconductor device includes a first area including a logic circuit, a second area including a functional circuit, a first power line, a second power line that supplies a power to the logic circuit and the functional circuit, and a first power switch circuit connected to the first power line and the second power line, wherein the first power switch circuit includes a first transistor larger than a transistor provided in the logic circuit and being connected to the first power line and the second power line, an end cap provided in an area next to the functional circuit, and a second transistor provided between the end cap and an area including the first transistor, the second transistor being of a same size as the transistor provided in the logic circuit and being connected to the first power line and the second power line.

A semiconductor device includes a first area including a logic circuit, a second area including a functional circuit, a first power line, a second power line that supplies a power to the logic circuit and the functional circuit, and a first power switch circuit connected to the first power line and the second power line, wherein the first power switch circuit includes a first transistor larger than a transistor provided in the logic circuit and being connected to the first power line and the second power line, an end cap provided in an area next to the functional circuit, and a second transistor provided between the end cap and an area including the first transistor, the second transistor being of a same size as the transistor provided in the logic circuit and being connected to the first power line and the second power line.

A retention circuit provided in a logic circuit enables power gating. The retention circuit includes a first terminal, a node, a capacitor, and first to third transistors. The first transistor controls electrical connection between the first terminal and an input terminal of the logic circuit. The second transistor controls electrical connection between an output terminal of the logic circuit and the node. The third transistor controls electrical connection between the node and the input terminal of the logic circuit. A gate of the first transistor is electrically connected to a gate of the second transistor. In a data retention period, the node becomes electrically floating. The voltage of the node is held by the capacitor.

A circuit for use in a processor includes a first processing channel having a first logic unit, a second processing channel having a second logic unit, and multiplexing circuitry. The multiplexing circuitry includes an input multiplexer arranged to switch between a first state in which an input of the first logic unit is coupled to an input line of the first processing channel, and a respective second state in which the input of the first logic unit is instead coupled to an input line of the second processing channel; and an output multiplexer arranged to switch between a first state in which an output line of the second processing channel is coupled to an output of the second logic unit, and a second state in which the output line of the second processing channel is instead coupled to an output of the first logic unit.