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 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.

A flip-flop circuit includes first and second latches. The first latch comprises a first inverting logic element and a second inverting logic element. The first inverting logic element has a first logic threshold voltage. The second inverting logic element is connected in antiparallel to the first inverting logic element and has a second logic threshold voltage. The first and second logic threshold voltages are set with respect to one half of a power supply voltage. The second latch comprises a third inverting logic element and a fourth inverting logic element. The third inverting logic element is connected to the first latch and has a third logic threshold voltage. The fourth inverting logic element is connected in antiparallel to the third inverting logic element and has a fourth logic threshold voltage. The third and fourth logic threshold voltages are set with respect to one half of the power supply voltage.

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.

A semiconductor device and a method of operating a semiconductor device are provided. The semiconductor device includes a first latching circuit and a second latching circuit coupled to the first latching circuit. The second latching circuit includes a first feedback circuit and a first transmission circuit, the first feedback circuit configured to receive a first clock signal of a first phase and a second clock signal of a second phase, and the first transmission circuit configured to receive the second clock signal and a third clock signal of a third phase. The first feedback circuit is configured to be turned off by the first clock signal and the second clock signal before the first transmission circuit is turned on by the second clock signal and the third clock signal.

Disclosed is a semiconductor integrated circuit comprising a master chip including a first buffer circuit coupled to a first power line that is supplied with a first voltage and a first supply circuit that supplies a second voltage, having a lower voltage level than the first voltage, to a first through line in response to a control signal, and a slave chip, coupled to the first through line, including a second buffer circuit coupled to a second power line supplied with the second voltage and a second supply circuit that supplies the second voltage to a second through line in response to the control signal, which indicates whether the master chip and the slave chip are stacked.

A semiconductor standard cell of a flip-flop circuit includes semiconductor fins extending substantially parallel to each other along a first direction, electrically conductive wirings disposed on a first level and extending substantially parallel to each other along the first direction, and gate electrode layers extending substantially parallel to a second direction substantially perpendicular to the first direction and formed on a second level different from the first level. The flip-flop circuit includes transistors made of the semiconductor fins and the gate electrode layers, receives a data input signal, stores the data input signal, and outputs a data output signal indicative of the stored data in response to a clock signal, the clock signal is the only clock signal received by the semiconductor standard cell, and the data input signal, the clock signal, and the data output signal are transmitted among the transistors through at least the electrically conductive wirings.

An integrated circuit includes a first time delay circuit, a second time delay circuit, and a master-slave flip-flop having a gated input circuit and a transmission gate. The first time delay circuit has a first input configured to receive a first clock signal and having a first output configured to generate a second clock signal. The second time delay circuit has a second input configured to receive the second clock signal and having a second output configured to generate a third clock signal. The transmission gate is configured to receive the first clock signal and the second clock signal to control a transmission state of the transmission gate. The gated input circuit is configured to have an input transmission state controlled by the third clock signal at the second output of the second time delay circuit.

A clocked storage element comprises a first latch having an input data node, a clock input node and a first latch output data node, and a second latch having an input connected to the first latch output data node, a clock input node and a second latch output data node. The first and second latches can have a clocked pull-up current path consisting of two p-channel transistors between their respective output data nodes and the VDD supply line, and a clocked pull-down current path consisting of two n-channel transistors between their respective output data nodes and the VSS supply line.

A data retention circuit is provided in the invention. The data retention circuit includes a master latch circuit, a slave latch circuit, and a control circuit. The control circuit is coupled to the master latch circuit and the slave latch circuit and receives a clock signal from a clock circuit and a power management signal from a power management unit (PMU). In a normal operation mode, the control circuit transmits the clock signal to the master latch circuit and the slave latch circuit. In sleep mode, power to the master latch circuit is switched off and the control circuit transmits the power management signal to the slave latch circuit.