A control arrangement is disclosed for providing a plurality of phase-coherent oscillating signals. It comprises a reference clock signal arrangement for providing a high-frequency reference clock signal and a plurality of modules each comprising a plurality of channels for providing the plurality of phase-coherent oscillating signals.

Learning-based power modeling of a processor core includes generating, using computer hardware, pipeline snapshot data specifying a plurality of snapshots for a pipeline of a processor core. Each snapshot specifies a state of the pipeline for a clock cycle in executing a computer program over a plurality of clock cycles. A plurality of estimates of power consumption for the processor core in executing the computer program for the plurality of clock cycles are determined, using an instruction-based power model executed by the computer hardware, a based on the pipeline snapshot data. The plurality of estimates of power consumption are calculated using the instruction-based power model based on the plurality of snapshots over the plurality of clock cycles.

Learning-based power modeling of a processor core includes generating, using computer hardware, pipeline snapshot data specifying a plurality of snapshots for a pipeline of a processor core. Each snapshot specifies a state of the pipeline for a clock cycle in executing a computer program over a plurality of clock cycles. A plurality of estimates of power consumption for the processor core in executing the computer program for the plurality of clock cycles are determined, using an instruction-based power model executed by the computer hardware, a based on the pipeline snapshot data. The plurality of estimates of power consumption are calculated using the instruction-based power model based on the plurality of snapshots over the plurality of clock cycles.

Dynamic power control embodiments concern a data processing pipeline. First and second pipeline stages respectively receive first and second clock signals. The first and second pipeline stages are configured to perform first and second operations respectively triggered by first timing edges of the first clock signal and second timing edges of the second clock signal. A clock controller is configured to generate the first and second clock signals. The clock controller is capable of operating in a first mode in which, during a first data processing cycle of the data processing pipeline, a first of the first timing edges is in-phase with a first of the second timing edges. The clock controller is also capable of operating in a second mode in which, during a second data processing cycle of the data processing pipeline, a second of the first timing edges is out of phase with a second of the second timing edges.

A memory controller component includes transmit circuitry and adjusting circuitry. The transmit circuitry transmits a clock signal and write data to a DRAM, the write data to be sampled by the DRAM using a timing signal. The adjusting circuitry adjusts transmit timing of the write data and of the timing signal such that an edge transition of the timing signal is aligned with an edge transition of the clock signal at the DRAM.

A memory controller component includes transmit circuitry and adjusting circuitry. The transmit circuitry transmits a clock signal and write data to a DRAM, the write data to be sampled by the DRAM using a timing signal. The adjusting circuitry adjusts transmit timing of the write data and of the timing signal such that an edge transition of the timing signal is aligned with an edge transition of the clock signal at the DRAM.

Synthetizing a hardware description language code into a netlist comprising loads and a multi-clock buffer (MBUF). The MBUF receives a global clocking signal and generates a first and a second related clocking signals. The loads are grouped into a first and a second groups receiving the first and the second clocking signals respectively. A first/second clock modifying leaf are placed between a common node and the first/group groups respectively, wherein the common node is positioned closer in proximity to the first/second groups in comparison to a clock source generating the global clocking signal. The first/second clock modifying leaves receive a least divided clocking signal from the MBUF and generate the first/second clocking signals respectively. The least divided clocking signal is routed from the MBUF to the first/second clock modifying leaves. The first/second clocking signals are routed from the first/second clock modifying leaves to the first/second group respectively.

Synthetizing a hardware description language code into a netlist comprising loads and a multi-clock buffer (MBUF). The MBUF receives a global clocking signal and generates a first and a second related clocking signals. The loads are grouped into a first and a second groups receiving the first and the second clocking signals respectively. A first/second clock modifying leaf are placed between a common node and the first/group groups respectively, wherein the common node is positioned closer in proximity to the first/second groups in comparison to a clock source generating the global clocking signal. The first/second clock modifying leaves receive a least divided clocking signal from the MBUF and generate the first/second clocking signals respectively. The least divided clocking signal is routed from the MBUF to the first/second clock modifying leaves. The first/second clocking signals are routed from the first/second clock modifying leaves to the first/second group respectively.

Apparatus and methods for multiphase clock generation are provided herein. In certain embodiments, a multiphase clock generator includes a first clock buffer that generates a first output clock signal based on a first input clock signal, a second clock buffer that generates a second output clock signal based on a second input clock signal, and a first clock interpolation circuit that generates a third output clock signal based on interpolating the first input clock signal and the second input clock signal. The first clock interpolation circuit generates the third output clock signal based on multiplying the first input clock signal by a first adjustable current to generate a first multiplied current, multiplying the second input clock signal by a second adjustable current to generate a second multiplied current, combining the first multiplied current and the second multiplied current to generate a combined current, and integrating the combined current.

Apparatus and methods for multiphase clock generation are provided herein. In certain embodiments, a multiphase clock generator includes a first clock buffer that generates a first output clock signal based on a first input clock signal, a second clock buffer that generates a second output clock signal based on a second input clock signal, and a first clock interpolation circuit that generates a third output clock signal based on interpolating the first input clock signal and the second input clock signal. The first clock interpolation circuit generates the third output clock signal based on multiplying the first input clock signal by a first adjustable current to generate a first multiplied current, multiplying the second input clock signal by a second adjustable current to generate a second multiplied current, combining the first multiplied current and the second multiplied current to generate a combined current, and integrating the combined current.