Abstract: A high speed CMOS-implemented equalizer architecture as described herein utilizes a digitally controlled analog equalization scheme to equalize intersymbol interference present in an input signal. The equalizer structure includes an inductor high frequency gain boosting stage and a feed forward high frequency equalizer stage connected in series. The equalization performed by each of these gain boosting stages is controlled by one or more digital control signals. The combination of these stages results in the equalization of both amplitude and phase distortion. The equalizer architecture is suitable for use with communication systems that operate at 11.2 Gbps speeds.

Abstract: A high speed, high sensitivity post amplifier as described herein includes a digitally-controlled DC offset cancellation feature. The amplifier circuit is configured to provide DC offset voltage levels in response to a digital control signal, where the digital control signal is generated based upon a data error metric such as bit error rate. The AC signal path and the DC offset adjustment signal path in the amplifier circuit are separated to facilitate operation with normal power supply voltages, and to achieve low power operation.

Abstract: A high speed, high sensitivity post amplifier as described herein includes a digitally-controlled DC offset cancellation feature. The amplifier circuit is configured to provide DC offset voltage levels in response to a digital control signal, where the digital control signal is generated based upon a data error metric such as bit error rate. The AC signal path and the DC offset adjustment signal path in the amplifier circuit are separated to facilitate operation with normal power supply voltages, and to achieve low power operation.

Abstract: A method of reducing jitter in a phase locked loop (PLL) includes receiving a first reference signal, quadrupling a frequency of the first reference signal to produce a second reference signal, and providing the second reference signal to a frequency phase detector of the PLL. The method may also include equalizing the second reference signal prior to providing the second reference signal to the frequency phase detector. The method can be accomplished by a circuit, wherein quadrupling the frequency of the first reference signal is performed by two frequency doublers arranged in series. The step of equalizing can be performed by two equalizers, each one configured to equalize an output of a respective frequency doubler.

Abstract: Circuitry for a phase locked loop (PLL) includes a reference signal input and a frequency doubler. The output of the frequency doubler is a second reference signal having a frequency that is approximately twice that of the initial reference signal, and which is fed into the PLL. The frequency doubler includes a first delay circuit having an input coupled to the input of the frequency doubler; and an XOR circuit having a first input coupled to an output of the delay circuit and a second input coupled to the input of the frequency doubler. The frequency doubler can include one or more additional delay circuits in series after the first delay circuit, the output of which is provided to a multiplexer. The multiplexer includes a selection signal input for selecting an output from at least one of the delay circuits to be provided to the XOR circuit. The frequency doubler allows the PLL to have a smaller feedback divider ratio and a higher loop gain for reducing jitter.

Abstract: A low-jitter phase-locked loop (PLL) circuit includes a reference signal generator and a PLL. The reference signal generator is configured to quadruple a frequency of a first reference signal to produce a second reference signal. The PLL includes a filter coupled in series with a voltage controlled oscillator (VCO), and a frequency phase detector configured to generate a first error signal based on a frequency difference between the second reference signal and a first divided VCO output signal. The PLL further includes a phase detector configured to generate a second error signal based on a phase difference between the second reference signal and a second divided VCO output signal at each rising and falling transition of the second reference signal.

Abstract: Circuitry for a phase locked loop (PLL) includes a first frequency doubler; a first equalizer having an input coupled to an output of the first frequency doubler; a second frequency doubler having an input coupled to an output of the first equalizer; and a second equalizer having an input coupled to an output of the second frequency doubler and an output which is fed into the PLL. Each frequency doubler includes a first delay circuit having an input coupled to the input of the frequency doubler; and an XOR circuit having a first input coupled to an output of the delay circuit and a second input coupled to the input of the frequency doubler. The combination of the two frequency doublers in series quadruples the reference signal into the PLL, which allows the, PLL to have a smaller feedback divider ratio and a higher loop gain for reducing jitter. Advantageously, controls for the selection of the initial reference signal are provided.