Techniques and apparatus for reducing low frequency power supply spurs in clock signals in a clock distribution network. One example circuit for clock distribution generally includes a plurality of logic inverters coupled in series and configured to drive a clock signal and a current-starved inverter coupled in parallel (or in series) with a logic inverter in the plurality of logic inverters.

A multiplexer includes a first inverter for receiving and inverting first data, a second inverter for receiving and inverting second data, and a first driver connected to an output of the first inverter and to an output of the second inverter. The first driver is configured to output the first data or the second data as output data.

The present invention provides a processor including a core circuit, a plurality of clock signal generation circuits, a multiplexer and a detection circuit is disclosed. The core circuit is supplied by a supply voltage. The plurality of clock signal generation circuits are configured to generate a plurality of clock signals with different frequencies, respectively, wherein a number of the plurality of clock signals is equal to or greater than three. The multiplexer is configured to receive the plurality of clock signals, and to select one of the plurality of clock signals to serve as an output clock signal according to a control signal, wherein the core circuit uses the output clock signal to serve as an operating clock. The detection circuit is configured to detect a level of the supply voltage received by the core circuit in a real-time manner, to generate the control signal.

A method, implemented in a serializer for quarter rate serialization, is disclosed. The method includes receiving a plurality of in-phase and quarter-phase clock signals defining a quarter phase clock. The method includes receiving a quarter rate data input and sequentially outputting data in accordance with the quarter phase clock. The method includes receiving at least one data input from amongst the quarter rate input and outputting a first logical output in accordance with the in-phase clock signal and the quarter-phase clock signal. The method includes receiving said at least one data input and outputting a second logical output in accordance a complementary in-phase clock signal and a complementary quarter-phase clock signal. The method includes outputting, an output associated with the branch.

A device for synchronous serial data transmission over a differential data channel and a differential clock channel includes an interface controller having a clock generator, data controller, clock transmitter block and data receiver block. The clock generator generates a transmit clock signal which, during a data transmission cycle, includes a clock pulse train having a period. The clock generator is suitably configured such that, for data transmission cycles in a dynamic operating state in which a maximum occurring differential voltage of a differential clock signal is lower than a maximum differential voltage of the clock transmitter block, the clock generator sets a duration of a first clock phase of a first clock period of the clock pulse train to be longer than a first clock phase of following clock periods and shorter than a time duration required to reach the maximum differential voltage.

Systems and methods for interface block. The interface block includes input/output modules distributed along the interface block and a mid-stack module interspersed within the input/output modules. The input/output modules include at least one data module and at least one command module. At least one of the input/output modules is shared by an adjacent pair of channels. Each of the input/output modules is configured to interface with a memory device via a silicon interposer or equivalent. The mid-stack module is in communication with the input/output modules via programmable logic circuitry. The mid-stack module may include independent clock quadrants. Each clock quadrant is configured to operate at different phases where each phase is aligned to a respective core clock.

An embodiment of the present invention relates to a low-power broadband asynchronous BPSK demodulation method and a configuration of a circuit thereof. In connection with a configuration of a BPSK demodulation circuit, there may be provided a low-power wideband asynchronous binary phase shift keying demodulation circuit comprising: a sideband separation and lower sideband signal delay unit; a data demodulation unit; and a data clock restoration unit.

Various embodiments of the present technology may provide methods and apparatus for reordering signals that are generated by a sensor. The apparatus may receive the generated signals in the form of a plurality of X-bit input signals and generate a plurality of output signals according to an exemplary reordering scheme. The apparatus may perform the exemplary reordering scheme based on one or more states of a state machine.

A clock gating cell (CGC) is provided. The clock gating cell includes two latches that can be configured as a flip-flop to use positive/negative edges of a first clock signal to store a value of an input terminal, and the clock gating cell also includes a selector used for the flip-flop to select from values of different input terminals for storing. In addition, in a non-scan testing mode, the clock gating cell can forcefully close an unused latch through an independent signal, and in a scan shift duration and a scan capture duration of a scan testing mode, the clock gating cell can further forcefully output the first clock signal as the gating clock signal according to two independent signals.

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.