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.

An integrated circuit includes a first circuit, a second circuit, and an inverter. The first circuit receives a first input signal, an inverted clock signal, a first logic level of a first output node, and a logic level of a second output node to determine a second logic level of a first output node. The second circuit receives the first input signal, the clock signal, the first logic level, and the second logic level to determine a logic level of the second output node. The inverter receives a second input signal to output the inverted second input signal to the first circuit or the second circuit. A logic level of the first output node or a logic level of the second output node is output as an output signal when a logic level of the clock signal is a first logic level.

Devices for reducing power consumption and skew for transmission of signals in a clock distribution circuit are described. A global distribution circuit is configured to divide external clock signals to generate first divided multiphase clock signals and divide one of the first divided multiphase clock signals to generate a reference clock signal. A local distribution circuit is configured to generate second divided multiphase clock signals according to a portion of the first divided multiphase clock signals and the reference clock signal.

An apparatus includes a circuit having an inverter including a power supply, an input terminal and an output terminal, and a harvest terminal electrically coupled to the output terminal. The circuit electrically couples the output terminal and the power supply, such that (1) a harvested charge is transferred from an output voltage at the output terminal to the harvest terminal in response to a high-to-low transition at the circuit and (2) a low-to-high transition at the circuit is driven using at least the harvested charge at the harvest terminal in response to the high-to-low transition.

An electrical circuit includes a driver circuit, a receiver circuit, and a keeper circuit. The receiver circuit receives an input pulse from the driver circuit during a pre-charge phase. The receiver circuit generates an output pulse based on the input pulse during an evaluation phase. The keeper circuit maintains a charge of the output pulse until another evaluation phase, wherein the keeper circuit is adapted to the driver circuit by gating a first voltage supply of the driver circuit with a second voltage supply of the keeper circuit.

Various embodiments provide for data sampling with loop-unrolled decision feedback equalization. In particular, some embodiments provide for an unrolled first-tap Decision Feedback Equalizer (DFE) loop that comprises parallel data samplers that each include a tri-state output.

Various embodiments provide for data sampling with loop-unrolled decision feedback equalization. In particular, some embodiments provide for an unrolled first-tap Decision Feedback Equalizer (DFE) loop that comprises parallel data samplers that each include a tri-state output.

A synchronization circuit includes a precharge circuit and a signal driving circuit. The precharge circuit precharges an output node to a first logic level. The signal driving circuit detects, in synchronization with a second dock signal having a phase leading a first clock signal, a logic level of an input signal and drives, in synchronization with the first clock signal, the output node to a second logic level according to the logic level of the input signal.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.

Reduced-power dynamic data circuits with wide-band energy recovery are described herein. In one embodiment, a circuit system comprises at least one sub-circuit in which at least one of the sub-circuits includes a capacitive output node that is driven between low and high states in a random manner for a time period and an inductive circuit path coupled to the capacitive output node. The inductive circuit path includes a transistor switch and an inductor connected in series to discharge and recharge the output node to a bias supply. A pulse generator circuit generates a pulse width that corresponds to a timing for driving the output node.