Described herein is an apparatus for the recovery of asynchronous data into a fixed clock domain. A phase-locked loop (PLL) of the known art is replaced by a modified quadrature resolver, and the output from the resolver re-creates the selected frequency component of the input asynchronous data. The zero-crossings of this re-created data clock are used to sample the input data stream. One advantage of this technique is that it operates as a state machine on a single clock, and no analog components such as phase detectors or VCOs are needed. In another embodiment, the samples from the input data stream are changed from pulses to Gaussians, allowing for conversion of the sample rate from one clock domain to another.

Described herein is an apparatus for the recovery of asynchronous data into a fixed clock domain. A phase-locked loop (PLL) of the known art is replaced by a modified quadrature resolver, and the output from the resolver re-creates the selected frequency component of the input asynchronous data. The zero-crossings of this re-created data clock are used to sample the input data stream. One advantage of this technique is that it operates as a state machine on a single clock, and no analog components such as phase detectors or VCOs are needed. In another embodiment, the samples from the input data stream are changed from pulses to Gaussians, allowing for conversion of the sample rate from one clock domain to another.

Described herein is an apparatus for the recovery of asynchronous data into a fixed clock domain. A phase-locked loop (PLL) of the known art is replaced by a modified quadrature resolver, and the output from the resolver re-creates the selected frequency component of the input asynchronous data. The zero-crossings of this re-created data clock are used to sample the input data stream. One advantage of this technique is that it operates as a state machine on a single clock, and no analog components such as phase detectors or VCOs are needed. In another embodiment, the samples from the input data stream are changed from pulses to Gaussians, allowing for conversion of the sample rate from one clock domain to another.

Described herein is an apparatus for the recovery of asynchronous data into a fixed clock domain. A phase-locked loop (PLL) of the known art is replaced by a modified quadrature resolver, and the output from the resolver re-creates the selected frequency component of the input asynchronous data. The zero-crossings of this re-created data clock are used to sample the input data stream. One advantage of this technique is that it operates as a state machine on a single clock, and no analog components such as phase detectors or VCOs are needed. In another embodiment, the samples from the input data stream are changed from pulses to Gaussians, allowing for conversion of the sample rate from one clock domain to another.

Embodiments provide a device that includes a first circuit having a first input to receive a first sine wave signal and a second input to receive a second sine wave signal in quadrature with respect to each other and a current mode logic gate having a first input coupled to a first output of the first circuit and a second input coupled to a second output of the first circuit. The first circuit configured to deliver a first square wave signal and a second square wave signal. The current mode logic gate is configured to deliver a third square wave signal at a first level and a fourth square wave signal at a second level when the first and second square wave signals are simultaneously at their first levels and the first square wave signal is ahead of the second square wave signal.

Embodiments provide a device that includes a first circuit having a first input to receive a first sine wave signal and a second input to receive a second sine wave signal in quadrature with respect to each other and a current mode logic gate having a first input coupled to a first output of the first circuit and a second input coupled to a second output of the first circuit. The first circuit configured to deliver a first square wave signal and a second square wave signal. The current mode logic gate is configured to deliver a third square wave signal at a first level and a fourth square wave signal at a second level when the first and second square wave signals are simultaneously at their first levels and the first square wave signal is ahead of the second square wave signal.