A computer-implemented method includes an act of configuring hardware to cause at least a part of the hardware to operate as a double data rate (DDR) memory controller, and to produce a capture clock to time a read data path, where a timing of the capture clock is based on a first clock signal of a first clock, delay the first clock signal to produce a delayed first clock signal, adjust the delay such that at least one clock edge of the delayed first clock signal is placed nearer to at least one clock edge of at least one data strobe (DQS), or at least one signal dependent on a DQS timing, and produce a modified timing of the capture clock based on the delay of the first clock signal.

A computer-implemented method includes an act of configuring hardware to cause at least a part of the hardware to operate as a double data rate (DDR) memory controller, and to produce a capture clock to time a read data path, where a timing of the capture clock is based on a first clock signal of a first clock, delay the first clock signal to produce a delayed first clock signal, adjust the delay such that at least one clock edge of the delayed first clock signal is placed nearer to at least one clock edge of at least one data strobe (DQS), or at least one signal dependent on a DQS timing, and produce a modified timing of the capture clock based on the delay of the first clock signal.

In some embodiments, clock input buffer circuitry and divider circuitry use a combination of externally-suppled voltages and internally-generated voltages to provide the various clock signals used by a semiconductor device. For example, a clock input buffer is configured to provide second complementary clock signals responsive to received first complementary clock signals using cross-coupled buffer circuitry coupled to a supply voltage and to drive the first complementary clock signals using driver circuitry coupled to an internal voltage. In another example, a divider circuitry may provide divided clock signals based on the second complementary clock signals via a divider coupled to the internal voltage and to drive the divided clock signals using driver circuitry coupled to the supply voltage. A magnitude of the supply voltage may be less than a magnitude of the internal voltage.

In some embodiments, clock input buffer circuitry and divider circuitry use a combination of externally-suppled voltages and internally-generated voltages to provide the various clock signals used by a semiconductor device. For example, a clock input buffer is configured to provide second complementary clock signals responsive to received first complementary clock signals using cross-coupled buffer circuitry coupled to a supply voltage and to drive the first complementary clock signals using driver circuitry coupled to an internal voltage. In another example, a divider circuitry may provide divided clock signals based on the second complementary clock signals via a divider coupled to the internal voltage and to drive the divided clock signals using driver circuitry coupled to the supply voltage. A magnitude of the supply voltage may be less than a magnitude of the internal voltage.

Embodiments of the present disclosure provide systems and methods for realizing phase synchronization updates based on an input system reference signal SYSREF without the need to synchronously distribute the SYSREF signal on a high-speed domain. In particular, phase synchronization mechanisms of the present disclosure are based on keeping a first phase accumulator in the device clock domain and using a second phase accumulator in the final digital clock domain to asynchronously transmit phase updates to the final digital clock domain. Arrival of a new SYSREF pulse may be detected based on the counter value of the first phase accumulator, which value is asynchronously transferred and scaled to the second phase accumulator downstream. In this manner, even though the SYSREF signal itself is not synchronously transferred to the second phase accumulator, the phase updates from the SYSREF signal may be transferred downstream so that the final phase may be generated deterministically.

A system-on-chip includes: a dynamic power monitor configured to generate a power detection signal by calculating an amount of power consumed by a functional circuit in real time; a frequency controller configured to detect an idle period and a running period of the functional circuit in response to the power detection signal, and generate a clock control signal based on the power detection signal; and a clock controller configured to change a frequency of a clock signal provided to the functional circuit, based on the clock control signal. The running period includes: a first running period in which the frequency of the clock signal has a first value based on the clock control signal; and a second running period in which the frequency of the clock signal has a second value that is greater than the first value based on the clock control signal.

A system-on-chip includes: a dynamic power monitor configured to generate a power detection signal by calculating an amount of power consumed by a functional circuit in real time; a frequency controller configured to detect an idle period and a running period of the functional circuit in response to the power detection signal, and generate a clock control signal based on the power detection signal; and a clock controller configured to change a frequency of a clock signal provided to the functional circuit, based on the clock control signal. The running period includes: a first running period in which the frequency of the clock signal has a first value based on the clock control signal; and a second running period in which the frequency of the clock signal has a second value that is greater than the first value based on the clock control signal.

The present disclosure relates to clock circuits, computing chips, hash boards and data processing devices. A clock circuit comprises M stages of clock drive circuits that are connected in series, M being an integer that is no less than 2, wherein N inverters connected in series are arranged between an input port and an output port of each stage of the M stages of clock drive circuits, N being an odd number that is no less than 3. The clock circuit may provide clock signals with excellent performance.

The present disclosure relates to clock circuits, computing chips, hash boards and data processing devices. A clock circuit comprises M stages of clock drive circuits that are connected in series, M being an integer that is no less than 2, wherein N inverters connected in series are arranged between an input port and an output port of each stage of the M stages of clock drive circuits, N being an odd number that is no less than 3. The clock circuit may provide clock signals with excellent performance.

In an embodiment a method includes generating a low-frequency clock signal having a first frequency, in a standby mode and in a run mode of the CPU, generating a high-frequency clock signal having a second frequency higher than the first frequency, in the run mode, updating a value of the reference time base at each period of the low-frequency clock signal in the standby mode, and accessing the counter register with the high-frequency clock signal in the run mode.