A system and method for efficiently generating clock signals are described. In various implementations, an integrated circuit includes multiple clock frequency dividers both at its I/O boundaries and across its die. A clock frequency divider utilizes a first clock divider and a second clock divider that receive input clock signals with an initial phase difference between them. The first clock divider and the second clock divider generate output clock signals that have frequencies that are a fraction of the frequencies of the received input clock signals. The second clock divider uses a combined multiplexer and flip-flop (combined mux-flop) circuit. The combined mux-flop circuit receives a reset signal that is asserted asynchronously with respect to an input clock signal received by the second clock divider. The second clock divider generates an output clock signal that has the initial phase difference with an output clock signal of the first clock divider.

Circuits, methods, and systems for generating data outputs based on sampled data inputs. One circuit includes a first latch including a first logic gate, a second logic gate, and a first keeper subcircuit. The circuit further includes a second latch including a third logic gate, a fourth logic gate, and a second keeper subcircuit. The first keeper subcircuit being electrically coupled via a first shared node of the first latch and the second latch, and the second keeper subcircuit being electrically coupled via a second shared node of the first latch and the second latch.

A flip flop circuit includes a first master portion, a second master portion, at least one determining portion and a slave portion. The first master portion is configured to operate at a first mode and to receive a first input and generate first master outputs. The second master portion is configured to operate at a second mode and to receive a second input and generate second master outputs. The at least one determining portion is configured to receive at least one enable signal, and has determining inputs and determining outputs. The determining inputs are connected to the first master outputs and the second master outputs. The determining portion is configured to determine the determining outputs being the first master outputs or the second master outputs according to the at least one enable signal. The slave portion is configured to receive the determining outputs and generate an output signal.

A flip flop circuit includes a first master portion, a second master portion, at least one determining portion and a slave portion. The first master portion is configured to operate at a first mode and to receive a first input and generate first master outputs. The second master portion is configured to operate at a second mode and to receive a second input and generate second master outputs. The at least one determining portion is configured to receive at least one enable signal, and has determining inputs and determining outputs. The determining inputs are connected to the first master outputs and the second master outputs. The determining portion is configured to determine the determining outputs being the first master outputs or the second master outputs according to the at least one enable signal. The slave portion is configured to receive the determining outputs and generate an output signal.

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 master latch circuit, including a first p-type transistor, a first n-type transistor, and a second n-type transistor connected in series; a first node connected to the first p-type transistor and the first n-type transistor, and a NAND circuit configured to receive a signal of the first node and a clock signal and output a result of a NAND operation to a second node, wherein a gate of the first p-type transistor is connected to the second node.

A master latch circuit, including a first p-type transistor, a first n-type transistor, and a second n-type transistor connected in series; a first node connected to the first p-type transistor and the first n-type transistor, and a NAND circuit configured to receive a signal of the first node and a clock signal and output a result of a NAND operation to a second node, wherein a gate of the first p-type transistor is connected to the second node.

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.

A latch and/or flip-flop with reduced dynamic capacitance for the clock node. Power associated with the clock node is reduced without timing impact. Merely two clock devices and merely the signal on the clock input pin toggles when the data does not change. As such, power is reduced. Further, the latch is interrupted-based with no contention or jamming issues. The latch can be configured as master and slave latches to form a flip-flop.