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.

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.

Systems, apparatuses, and methods for implementing low-power flip-flops with balanced clock-to-Q delay are described. A flip-flop includes a primary latch, an upper secondary latch, and a lower secondary latch. The primary latch transmits a data value from an input port to a first node when transparent. The upper secondary latch pulls up a second node when transparent and when the first node is equal to a first value. The second node is a prebuffered data output of the flip-flop. The lower secondary latch pulls down the second node when transparent and when the first node is equal to a second value different from the first value. To ensure the flip-flop has a balanced clock-to-Q delay, a first set of clock signals coupled to transistor gates of the primary latch are delayed with respect to a second set of clock signals coupled to transistor gates of the upper secondary latch.

Systems, apparatuses, and methods for implementing low-power flip-flops with balanced clock-to-Q delay are described. A flip-flop includes a primary latch, an upper secondary latch, and a lower secondary latch. The primary latch transmits a data value from an input port to a first node when transparent. The upper secondary latch pulls up a second node when transparent and when the first node is equal to a first value. The second node is a prebuffered data output of the flip-flop. The lower secondary latch pulls down the second node when transparent and when the first node is equal to a second value different from the first value. To ensure the flip-flop has a balanced clock-to-Q delay, a first set of clock signals coupled to transistor gates of the primary latch are delayed with respect to a second set of clock signals coupled to transistor gates of the upper secondary latch.

A PFM control circuit includes a switching circuit, a slope-decision circuit, a flip-flop, a first and a second comparison circuits. The first comparison circuit outputs a first signal according to an output voltage of a power conversion circuit. The switching circuit outputs a switching signal according to an output current of the power conversion circuit. The slope-decision circuit outputs a slope modulation voltage, and determines a slope modulation voltage with a first or a second slope according to the switching signal. The second comparison circuit outputs the second signal according to the slope modulation voltage. The flip-flop outputs a control signal to the power conversion circuit according to the first and the second signals. When the slope modulation voltage has the first or the second slope, the control signal has a first or a second frequency accordingly. The first frequency is higher than the second frequency.

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 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.

Various embodiments of the present technology may comprise methods and system for a resettable flip flop. The flip flop may receive a clock signal along a first circuit path and a reset signal along a second circuit path. The first circuit path provides a first high voltage value and a first low voltage value, and the second circuit path provides a second high voltage value that is greater than the first high voltage value and a second low voltage value that is less than the first low voltage value.

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 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.