A semiconductor device includes: a first latch circuit that includes a first inverting circuit, a second inverting circuit, a third inverting circuit, and a fourth inverting circuit; a first first-type well region; a second first-type well region; and a second-type well region. In a plan view, a distance between a drain of a first-type MOS transistor in the first inverting circuit and a drain of a first-type MOS transistor in the third inverting circuit is longer than a distance between the drain of the first-type MOS transistor in the first inverting circuit and a drain of a first-type MOS transistor in the fourth inverting circuit.

A semiconductor device according to an aspect of the present disclosure includes: a plurality of line layers; a first line; and a second line that is not connected to the first line and is redundantly provided to transfer a signal having a level same as a level of a signal transferred through the first line. The first line and the second line are included in different layers out of the plurality of line layers, and a distance between the first line and the second line is longer than an interlayer distance between line layers next to each other out of the plurality of line layers.

A semiconductor device includes: a first line; a second line that is not connected to the first line and is provided to transfer a signal having a level same as a level of a signal transferred through the first line; and another line different from the first line and the second line. In a line layer, a distance between the first line and the second line is longer than a distance between the first line and the other line, and is longer than a distance between the second line and the other line.

A flip-flop circuit comprises a pass gate, a feedback inverter, and an interleaved filter. The pass gate comprises a clock input and an inverting clock input. The feedback inverter includes a feedback input coupled to both the clock input and the inverting clock input of the pass gate. The interleaved filter comprises a delay circuit including a delay output, a C-gate element, and a blocking inverter. The C-gate element includes a C-gate input and a C-gate output. The C-gate input is coupled to the delay output of the delay circuit and the pass gate, and the C-gate output is coupled to the feedback input of the feedback inverter. The blocking inverter includes a blocking input and a blocking output. The blocking input is coupled to the delay output of the delay circuit, and the blocking output is coupled to the feedback input of the feedback inverter.

The disclosure relates to a latch including a first inverter with a first pair of field effect transistors (FETs) configured with a first channel width to length ratio (W/L), and a second inverter with a second pair of FETs configured with a second W/L different than the first W/L. Another latch includes first and second inverters; a first negative feedback circuit including first and second FETs coupled between first and second voltage rails, the input of the first inverter coupled between the first and second FETs, and the first and second FETs including gates coupled to an output of the first inverter; and a second negative feedback circuit including third and fourth FETs coupled between the first and second voltage rails, the input of the second inverter coupled between the third and fourth FETs, and the third and fourth FETs including gates coupled to an output of the second inverter.

A pre-discharging based flip-flop having a negative setup time can include a flip-flop with an inverted output QN. The flip-flop includes a master section and a slave section. The master section latches a data input or a scan input signal based on a scan enable signal, and the slave section retains a previous value of the inverted output QN when a clock signal is at a low logic level. The master section retains a previously latched value of the data input or the scan input signal and the slave section fetches the latched value of the master section and provides a new inverted output QN when the clock signal is at a high logic level. Further, the master section includes sub-sections that are operated using a negative clock signal. An output of the master section is discharged to zero for a half of a phase of the clock cycle.

The present disclosure includes storage circuits, such latches. In one embodiment, a circuit includes a plurality of latches, each latch including a first N-type transistor formed in a first P-type material, a first P-type transistor formed in a first N-type material, a second N-type transistor formed in a second P-type material, and a second P-type transistor formed in a second N-type material. The first and second N-type transistors are formed in different P-wells and the first and second P-type transistors are formed in different N-wells. In other storage circuits, charge extraction transistors are coupled to data storage nodes and are biased in a nonconductive state. These techniques make the data storage circuits more resilient, for example, to an ionizing particle striking the circuit and generating charge carriers that would otherwise change the state of the storage node.

A semiconductor device includes a standard cell, which includes first to fourth active areas that are extended in a first direction, first to fourth gate lines that are extended in a second direction perpendicular to the first direction over the first to fourth active areas and are disposed parallel to each other, a first cutting layer that is disposed between the first active area and the second active area and separates the second and third gate lines, a second cutting layer that is disposed between the third active area and the fourth active area and separates the second and third gate lines, a first gate contact that is formed on the second gate line separated by the first cutting layer and the second cutting layer, and a second gate contact that is formed on the third gate line separated by the first cutting layer and the second cutting layer.

A True Single-Phase Clock (TSPC) NAND-based reset flip-flop includes a reset functionality to perform a reset operation. The flip-flop with the reset functionality includes a master section and a slave section. The reset functionality is achieved using two transistors in the master section. The master section and the slave section operate using the TSPC. The master section and the slave section may include a plurality of NAND circuits and a NAND and NOR circuit for performing the reset operation. The master section outputs a plurality of internal signals on receiving a data input, a scan enable signal, a scan input signal, a reset control signal, and a clock signal. The slave section generates an output on receiving the plurality of internal signals received from the master section.

A flip-flop includes a first master latch in a first row, a second master latch in a second row, a first slave latch in the first row, and a second slave latch in the second row. The first master latch and the second master latch are adjacently disposed in the second direction, and the first slave latch and the second slave latch are adjacently disposed in the second direction.