Design and operation of a processing device is configurable to optimize wake-up time and peak power cost during restoration of a machine state from non-volatile storage. The processing device includes a plurality of non-volatile logic element arrays configured to store a machine state represented by a plurality of volatile storage elements of the processing device. A stored machine state is read out from the plurality of non-volatile logic element arrays to the plurality of volatile storage elements. During manufacturing, a number of rows and a number of bits per row in non-volatile logic element arrays are based on a target wake up time and a peak power cost. In another approach, writing data to or reading data of the plurality of non-volatile arrays can be done in parallel, sequentially, or in any combination to optimize operation characteristics.

Design and operation of a processing device is configurable to optimize wake-up time and peak power cost during restoration of a machine state from non-volatile storage. The processing device includes a plurality of non-volatile logic element arrays configured to store a machine state represented by a plurality of volatile storage elements of the processing device. A stored machine state is read out from the plurality of non-volatile logic element arrays to the plurality of volatile storage elements. During manufacturing, a number of rows and a number of bits per row in non-volatile logic element arrays are based on a target wake up time and a peak power cost. In another approach, writing data to or reading data of the plurality of non-volatile arrays can be done in parallel, sequentially, or in any combination to optimize operation characteristics.

The present disclosure describes current steering phase control for current-mode logic (CML) circuits. In some aspects, a circuit for frequency division comprises a current sink connected to a ground rail. The circuit also includes first and second current-carrying branches of frequency-dividing circuitry operably connected to respective load resistors, which are connected to a power rail. A first switch element of the circuit is connected between the current sink and the first current-carrying branch and a second switch element of the circuit is connected between the current sink and the second current-carrying branch. The first and second switch elements may steer current sank by the current sink between the first and second current-carrying branches effective to alter a phase of a signal provided by the frequency division circuit.

The present disclosure describes current steering phase control for current-mode logic (CML) circuits. In some aspects, a circuit for frequency division comprises a current sink connected to a ground rail. The circuit also includes first and second current-carrying branches of frequency-dividing circuitry operably connected to respective load resistors, which are connected to a power rail. A first switch element of the circuit is connected between the current sink and the first current-carrying branch and a second switch element of the circuit is connected between the current sink and the second current-carrying branch. The first and second switch elements may steer current sank by the current sink between the first and second current-carrying branches effective to alter a phase of a signal provided by the frequency division circuit.

A flip-flop circuit may include a first latch and a second latch. The first latch, which may operate as a “master” latch, includes a first input terminal to receive a data signal, a second input terminal to receive a clock signal, and an output terminal. The second latch, which may operate as a “slave” latch, includes a first input terminal connected directly to the output terminal of the first latch, a second input terminal to receive the clock signal, and an output terminal to provide an output signal. The first latch and the second latch are to be clocked on the same phase of the clock signal, thereby eliminating the need to include clock inversion circuits that generate complementary clock signals.

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 multi-bit flip-flop (MBFF) includes a plurality of 1-bit flip-flops, each having an input data selection circuit that receives a data signal and a scan data signal. The MBFF also includes a local signal generation circuit that receives a global clock signal and a global scan enable signal, and in response, provides local control signals, wherein each of the local control signals is generated in response to both the global clock signal and the global scan enable signal. The local control signals are provided to the input data selection circuits, and exclusively control the input data selection circuits to route either the input data signal or the scan input data signal as a master data bit, reducing transistor requirements. Local clock signals may be generated by the local signal generation circuit in response to the global clock signal, and may exclusively control data transfer within the flip-flops, improving setup time.

A semiconductor device may include a master latch that stores an input data signal, using a local power supply voltage and a clock signal, and outputs the input data signal to a first output signal; a slave latch that stores the first output signal, using a global power supply voltage, the clock signal and a retention signal, and outputs a second output signal; a first logic gate that receives input of one signal and another signal of the retention signal, the clock signal and the reset signal, and outputs a first control signal generated by performing a first logical operation; and a second logic gate that receives input of the rest of the retention signal, the clock signal and the reset signal, and the first control signal, and performs a second logical operation to at least one of the master latch and the slave latch.

Provided is a semiconductor device including low power retention flip-flop. The semiconductor device includes a first line to which a global power supply voltage is applied, a second line to which a local power supply voltage is applied, the second line being separated from the first line, a first operating circuit connected to the second line to use the local power supply voltage, a first power gating circuit determining whether the local power supply voltage is applied to the first operating circuit and a first retention flip-flop connected to the first line and the second line, wherein the first retention flip-flop comprises a first circuit including a master latch, a second circuit including a slave latch, and a first tri-state inverter connected between the master latch and the slave latch.

A buffer includes an amplification circuit, an amplification current generation circuit, and a latch. The amplification circuit may change voltage levels of a first output node and a second output node based on a clock signal and a pair of input signals. The amplification current generation circuit may provide currents having different magnitudes to the first and second output nodes during a first operation period, and may provide currents having the same magnitude to the first and second output nodes during a second operation period. The latch circuit may latch the voltage levels of the first output node and the second output node based on the clock signal.