Abstract: A method and apparatus for analog to digital conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that errors produced by nonuniform sampling are frequency-shaped to a region (i.e., shifted to higher frequencies) where they can be removed by conventional filtering techniques. In one embodiment, digital data is interpolated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the digital data to be output by the converter and then decimated by a fixed ratio. In another embodiment, the digital data is interpolated by a fixed ratio and then decimated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the digital data to be output by the converter. The frequency selection signal is modulated using an n-th order m-bit sigma-delta modulator.

Abstract: A method and apparatus for digital-to-digital conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that noise produced by NONUNIFORM sampling are frequency-shaped to a region (i.e., shifted to higher frequencies where it can be removed by conventional filtering techniques. In one embodiment, the digital data is interpolated (16) by fixed ratio and then decimated (21) under control of a first sigma-delta modulated frequency selection signal (26) that represents, on average, the data rate of the incoming digital data stream. Thereafter, the digital data is interpolated (30) under control of a second sigma-delta modulated frequency selection signal (46) that represents, on average, the data rate of the digital data to be output by the converter and then decimated (40) by a fixed ratio.

Abstract: A method and apparatus for digital to analog conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that errors produced by nonuniform sampling are frequency-shaped to a region (i.e., shifted to higher frequencies) where they can be removed by conventional filtering techniques In one embodiment, the digital data is interpolated by a fixed ratio and then decimated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the incoming digital data stream. In another embodiment, the digital data is interpolated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the incoming digital data stream and then decimated by a fixed ratio. The frequency signal selection number is modulated using an n-th order m-bit sigma-delta modulator.

Abstract: A method and apparatus for analog-to-digital conversion using sigma-delta modulation of the temporal spacing between digital samples are provided. The method and apparatus include sigma-delta modulation of the time-base such that errors produced by non-uniform sampling are frequency-shaped to a high frequency region where they are reduced by conventional digital filtering techniques. In one embodiment, a sigma-delta ADC receives an analog input signal and converts the analog input signal to digital samples at an oversampling rate. A decimator, coupled to the sigma-delta ADC, receives the digital samples and decimates the digital samples to produce the digital samples at a preselected output sample rate, less than the oversampling rate. An ADC sample rate control circuit, coupled to the ADC, receives a frequency select signal representing the preselected output sample rate, and produces a noise-shaped clock signal for controlling operation of the ADC at the oversampling rate.

Abstract: A method and apparatus for phase locking to an input signal and outputting a sigma-delta modulated control signal. The method and apparatus of the present invention provide a sigma-delta modulated control signal which can be utilized by any one of a decimator for decimating a digital data at a first data rate to a digital data at a second data rate and an interpolator for interpolating a digital data at a first data rate to a digital data at a second data rate. The decimator and the interpolator can be utilized in any one of an analog-to-digital converter, a digital-to-analog converter and a digital-to-digital converter. In one embodiment, a period of the input signal is determined and fed to a phase-locked loop which includes a sigma-delta modulator for providing the sigma-delta modulated control signal. The phase-locked loop also includes a phase detector for determining a phase and a frequency-difference between the input signal and a conversion signal generated by the phase-locked loop.

Abstract: A method and apparatus for analog-to-digital conversion using sigma-delta modulation of the temporal spacing between digital samples are provided. The method and apparatus include sigma-delta modulation of the time-base such that errors produced by non-uniform sampling are frequency-shaped to a high frequency region where they are reduced by conventional digital filtering techniques. In one embodiment, a sigma-delta ADC receives an analog input signal and converts the analog input signal to digital samples at an oversampling rate. A decimator, coupled to the sigma-delta ADC, receives the digital samples and decimates the digital samples to produce the digital samples at a preselected output sample rate, less than the oversampling rate. An ADC sample rate control circuit, coupled to the ADC, receives a frequency select signal representing the preselected output sample rate, and produces a noise-shaped clock signal for controlling operation of the ADC at the oversampling rate.

Abstract: A method and apparatus for digital-to-analog conversion using sigma-delta modulation of the temporal spacing between digital samples are provided. The method and apparatus include sigma-delta modulation of the time-base such that errors produced by non-uniform sampling are frequency-shaped to a high frequency region where they are reduced by conventional filtering techniques. In one embodiment, an oversampling modulator receives digital input samples and, responsive to a noise-shaped clock signal, modulates the digital input samples to produce modulated samples at an oversampling rate. The oversampling rate preferably is equal to an oversampling ratio times a preselected input sample rate. A DAC, coupled to the modulator, converts the modulated samples to an analog signal.

Abstract: A method and apparatus for phase locking to an input signal and outputting a sigma-delta modulated control signal. The method and apparatus of the present invention provide a sigma-delta modulated control signal which can be utilized by any one of a decimator for decimating a digital data at a first data rate to a digital data at a second data rate and an interpolator for interpolating a digital data at a first data rate to a digital data at a second data rate. The decimator and the interpolator can be utilized in any one of an analog-to-digital converter, a digital-to-analog converter and a digital-to-digital converter. In one embodiment, a period of the input signal is determined and fed to a phase-locked loop which includes a sigma-delta modulator for providing the sigma-delta modulated control signal. The phase-locked loop also includes a phase detector for determining a phase and a frequency-difference between the input signal and a conversion signal generated by the phase-locked loop.

Abstract: A method and apparatus for phase locking to an input signal and outputting a sigma-delta modulated control signal. The method and apparatus of the present invention provide a sigma-delta modulated control signal which can be utilized by any one of a decimator for decimating a digital data at a first data to a digital data at a second data rate and an interpolator for interpolating a digital data at a first data rate to a digital data at a second data rate. The decimator and the interpolater can be utilized in any one of an analog-to-digital converter, a digital-to analog converter and a digital-to digital converter. In one embodiment, a period of the input signal is determined and fed to a phase-locked loop which includes a sigma-delta modulator for providing the sigma-delta modulated control signal. The phase-locked loop also includes a phase detector for determining a phase and a frequency-difference between the input signal and a conversion signal generated by the phase-locked loop.

Abstract: A method and apparatus for phase locking to an input signal and outputting a sigma-delta modulated control signal. The method and apparatus of the present invention provide a sigma-delta modulated control signal which can be utilized by any one of a decimator for decimating a digital data at a first data rate to a digital data at a second data rate and an interpolator for interpolating a digital data at a first data rate to a digital data at a second data rate. The decimator and the interpolator can be utilized in any one of an analog-to-digital converter, a digital-to-analog converter and a digital-to-digital converter. In one embodiment, a period of the input signal is determined and fed to a phase-locked loop which includes a sigma-delta modulator for providing the sigma-delta modulated control signal. The phase-locked loop also includes a phase detector for determining a phase and a frequency-difference between the input signal and a conversion signal generated by the phase-locked loop.

Abstract: A method and apparatus for digital-to-analog conversion using sigma-delta modulation of the temporal spacing between digital samples are provided. The method and apparatus include sigma-delta modulation of the time-base such that errors produced by non-uniform sampling are frequency-shaped to a high frequency region where they are reduced by conventional filtering techniques. In one embodiment, an oversampling modulator receives digital input samples and, responsive to a noise-shaped clock signal, modulates the digital input samples to produce modulated samples at an oversampling rate. The oversampling rate preferably is equal to an oversampling ratio times a preselected input sample rate. A DAC, coupled to the modulator, converts the modulated samples to an analog signal.

Abstract: A method and apparatus for digital-to-digital conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that noise produced by non-uniform sampling are frequency-shaped to a region (i.e., shifted to higher frequencies) where it can be removed by conventional filtering techniques. In one embodiment, the digital data is interpolated by fixed ratio and then decimated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the incoming digital data stream. Thereafter, the digital data is interpolated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the digital data to be output by the converter and then decimated by a fixed ratio. The first and second frequency signal selection numbers are modulated using n-th order m-bit sigma-delta modulators.

Abstract: A method and apparatus for digital to analog conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that errors produced by non-uniform sampling are frequency-shaped to a region (i.e., shifted to higher frequencies) where they can be removed by conventional filtering techniques. In one embodiment, the digital data is interpolated by a fixed ratio and then decimated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the incoming digital data stream. The frequency signal selection number is modulated using an n-th order m-bit sigma-delta modulator. Data thus emerges from the interpolation/decimation process at the clock rate of the n-th order m-bit sigma-delta modulator.

Abstract: A method and apparatus for analog to digital conversion using sigma-delta modulation of the temporal spacing between digital samples. The method and apparatus of the present invention provides for sigma-delta modulation of the time base such that errors produced by non-uniform sampling are frequency-shaped to a region (i.e., shifted to higher frequencies) where they can be removed by conventional filtering techniques. In one embodiment, digital data is interpolated under control of a sigma-delta modulated frequency selection signal that represents, on average, the data rate of the digital data to be output by the converter and then decimated by a fixed ratio. The frequency selection signal is modulated using an n-th order m-bit sigma-delta modulator. Data thus emerges from the interpolation/decimation process at the sample rate selected by the n-th order m-bit sigma-delta modulator.