A flip-flop circuit includes a first master latch circuit transmitting an inverted signal of an input signal received from an external device to a first node and transmitting an inverted signal of a signal of the first node to a second node, according to a first control signal having a first logic level or a second control signal having a second logic level, a first slave latch circuit transmitting an inverted signal of a signal of the second node to a third node according to the first control signal having the second logic level or the second control signal having the first logic level, a first output inverter generating a first output signal by inverting a signal of the third node, and a first control signal generation circuit generating the first control signal and the second control signal based on a clock signal and the signal of the first node.

A circuit is provided. The circuit includes a first master stage, a second master stage, a first slave stage, a first slave stage, and a second slave stage. The first master stage includes a data input line. The second master stage includes an inverse data input line. The first slave stage is coupled to an output of the first master stage. The second slave stage is coupled to an output of the second master stage. The first slave stage generates an output signal during a rising edge of a clock cycle. The second slave stage generates an inverted output signal during the rising edge of the clock cycle. The output signal and the inverted output signal are available concurrently.

A flip-flop circuit includes a clock generator configured to generate first and second clock signals having different phases relative to each other, and a master-slave latch circuit including master and slave latches. The master latch includes a scan path configured to output a scan path signal in response to a scan enable signal and a scan input signal, and a data path configured to output a first latch signal in response to a data signal and the scan path signal. A feedback path is provided, which includes a tri-state inverter responsive to the first and second clock signals. The tri-state inverter has an input terminal connected to an output terminal of the data path and an output terminal connected to a node of the scan path.

A flip-flop includes an input switching circuit configured to output an intermediate signal based on an input signal and at least one of a phase of a clock signal or a phase of an inverted clock signal, the phase of the inverted clock signal being opposite to the phase of the clock signal, and block application of a driving voltage to at least one circuit element of the input switching circuit in response to receiving a reset signal representing a reset operation of the flip-flop, and a latch circuit configured to generate an output signal based on the intermediate signal according to the at least one of the phase of the clock signal or the phase of the inverted clock signal.

An integrated circuit includes a flip-flop configured to operate in synchronization with a clock signal. The flip-flop includes a multiplexer configured to output an inverted signal of a scan input signal to a first node based on a scan enable signal, or the multiplexer configured to output an inverted signal of a data input signal or a signal having a first level to a first node based on a reset input signal, a master latch configured to latch the signal output through the first node, and to output the latched signal, and a slave latch configured to latch an output signal of the master latch and to output the latched output signal of the master latch.

A flip-flop having first and second shared transistors. The flip-flop including a tri-state inverter and a master latch configured to receive an output of the tri-state inverter. The flip-flop also having a slave latch coupled to the master latch, the slave latch including a slave tri-state inverter. The flip-flop further having an output inverter coupled to receive one of an output of the slave latch and an output of the master latch and configured to generate a flip-flop output. The first shared transistor configured to receive a clock signal and having a drain terminal coupled a first transistor in the tri-state inverter and a second transistor in the slave tri-state inverter. The second shared transistor configured to receive an inverted clock signal and having a drain terminal coupled a third transistor in the tri-state inverter and a fourth transistor in the slave tri-state inverter.

A flip flop includes a master latch and a slave latch. The master latch includes a delay circuit configured to receive a clock signal and generate a first internal signal, and is configured to generate an internal output signal by latching a data signal based on the first internal signal. The slave latch is configured to generate a final signal by latching the internal output signal. The delay circuit is further configured to generate the first internal signal by delaying the clock signal by a delay time when the clock signal has a first logic level and generate the first internal signal based on the data signal when the clock signal has a second logic level.

A circuit includes first and second power nodes having differing first and second voltage levels, and a reference node having a reference voltage level. A master latch outputs a first data bit based on a received data bit; a slave latch includes a first inverter that outputs a second data bit based on the first data bit and a second inverter that outputs an output data bit based on a selected one of the first data bit or a third data bit; a level shifter outputs the third data bit based on a fourth data bit; and a retention latch outputs the fourth data bit based on the second data bit. The first and second inverters and the level shifter are coupled between the first power node and the reference node, and the retention latch includes a plurality of transistors coupled between the second power node and the reference node.

A flip-flop circuit configured to latch an input signal to an output signal is disclosed. The circuit includes a first latch circuit; and a second latch circuit coupled to the first latch circuit. In some embodiments, in response to a clock signal, the first and second latch circuits are complementarily activated so as to latch the input signal to the output signal, and the first and second latch circuits each comprises at most two transistors configured to receive the clock signal.

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.