Clock generation circuits including a single and multi-phase clock circuits are disclosed. A clock generation circuit is coupled to receive a first pulse on a first input and a second pulse on a second input. The first pulse may be generated responsive to a rising edge of an input clock signal, while the second pulse may be generated responsive to a falling edge of the input clock signal. Responsive to the first pulse, an output node of the clock generation circuit may be pulled high. Responsive to the second pulse, the output node may be pulled low. During those points in which neither pulse is asserted, a state element in the clock generation circuit may hold the output node to its most recent value. Using delay elements and multiple instances of the clock generation circuit and pulse generation circuits, a multi-phase clock generation circuit may be constructed.

Clock generation circuits including a single and multi-phase clock circuits are disclosed. A clock generation circuit is coupled to receive a first pulse on a first input and a second pulse on a second input. The first pulse may be generated responsive to a rising edge of an input clock signal, while the second pulse may be generated responsive to a falling edge of the input clock signal. Responsive to the first pulse, an output node of the clock generation circuit may be pulled high. Responsive to the second pulse, the output node may be pulled low. During those points in which neither pulse is asserted, a state element in the clock generation circuit may hold the output node to its most recent value. Using delay elements and multiple instances of the clock generation circuit and pulse generation circuits, a multi-phase clock generation circuit may be constructed.

An integrated circuit includes a clock tree network that distributes a clock signal to a plurality of clocked components of the integrated circuit. The clock tree network includes clock lines, each of which includes a clock tree delay element that provides a modified clock signal that is provided to an individual one the clocked components. Among the plurality of clocked components, one or more of the clocked components provides a data signal to another one or more of the clocked components. The one or more clocked components are configured having a transmission duration for the data signal that is longer relative to a transmission duration of the modified clock signal of the receiving clocked component.

A low-power phase interpolator circuit has a phase generator that receives an input clock signal and uses the input clock signal to generate multiple intermediate clock signals with different phase shifts; a phase rotator circuit that outputs phase-adjusted clock signals, each phase-adjusted clock signal having a phase that lies within a range bounded by phases of two of the intermediate clock signals; a frequency doubler circuit that receives a plurality of the phase-adjusted clock signals and outputs two frequency-doubled clock signals having a 180 phase difference; and a quadrature clock generation circuit that receives the two frequency-doubled clock signals and provides four output signals that include in-phase and quadrature versions of the two frequency-doubled clock signals.