A digital clock multiplier (DCM) circuit including: a plurality of power amplifier (PA) rows, wherein each PA row comprises a plurality of cascade switched capacitor power amplifiers (SCPA) unit cells configured to: receive a phase shift of a driving clock phase; and one or more processors configured to: disable of one or more of the plurality of cascade SCPA unit cells based on a frequency of the phase shift; generate an output signal for each of the cascade SCPA unit cells; and combine the output signal for each of the cascade SCPA unit cells to generate an PA row output signal.

A digital clock multiplier (DCM) circuit including: a plurality of power amplifier (PA) rows, wherein each PA row comprises a plurality of cascade switched capacitor power amplifiers (SCPA) unit cells configured to: receive a phase shift of a driving clock phase; and one or more processors configured to: disable of one or more of the plurality of cascade SCPA unit cells based on a frequency of the phase shift; generate an output signal for each of the cascade SCPA unit cells; and combine the output signal for each of the cascade SCPA unit cells to generate an PA row output signal.

Disclosed herein is a low-cost, high-performance, and energy-efficient near-sensor convolution engine based on pulsed unary processing. The disclosed engine removes the necessity of using costly analog-to-digital converters. Synthesis results show that the proposed pulse-based design significantly improves the hardware cost and energy consumption compared to the conventional fixed-point binary and also to the stochastic computing-based designs.

Disclosed herein is a low-cost, high-performance, and energy-efficient near-sensor convolution engine based on pulsed unary processing. The disclosed engine removes the necessity of using costly analog-to-digital converters. Synthesis results show that the proposed pulse-based design significantly improves the hardware cost and energy consumption compared to the conventional fixed-point binary and also to the stochastic computing-based designs.