Digital phase-locked loop and frequency measuring device
First Claim
1. A method for providing a sampling signal having a first frequency corresponding to a first period wherein said first frequency is maintained in substantially constant proportion to a second frequency of an input signal, said method comprising the steps of:
- (a) sampling said input signal at instants determined by said sampling signal to provide first and second pluralities of data signals associated with respective first and second cycles of said input signal, wherein each said data signal represents the magnitude of said input signal at the sampling instant;
(b) performing a discrete Fourier analysis on each of said first and second plurality of data signals to provide first and second phasor signals, wherein each said first and second phasor signal is indicative of respective first and second voltage phasors associated with the fundamental frequency of the discrete Fourier transform of said first and second cycles, respectively;
(c) generating a difference signal representing the angular displacement between said first and second voltage phasors and, therefore, representing the difference between said first and second frequencies; and
(d) modulating said first period in response to said difference signal such that said difference signal is minimized and, therefore, said first frequency is maintained in substantially constant proportion to said second frequency.
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Abstract
Method and apparatus are disclosed for providing a sampling signal having a frequency which is maintained in constant proportion to the frequency of an input signal. The input signal is sampled at instants determined by the sampling signal to provide a plurality of data signals associated with one cycle of the input signal. A signal processor is adapted to receive first and second pluralities of data signals associated with first and second cycles of the input signal and to perform two discrete Fourier analyses to provide two phasor signals representing two voltage phasors of respective fundamental frequencies of the discrete Fourier transforms. The phasor signals are used to generate a difference signal indicative of the angle between the two voltage phasors and, therefore, proportional to the difference between the sampling frequency and the input frequency. The difference signal is used to modulate the period of the sampling signal such that the frequency of the sampling signal is maintained in constant proportion to that of the input signal.
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Citations
13 Claims
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1. A method for providing a sampling signal having a first frequency corresponding to a first period wherein said first frequency is maintained in substantially constant proportion to a second frequency of an input signal, said method comprising the steps of:
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(a) sampling said input signal at instants determined by said sampling signal to provide first and second pluralities of data signals associated with respective first and second cycles of said input signal, wherein each said data signal represents the magnitude of said input signal at the sampling instant; (b) performing a discrete Fourier analysis on each of said first and second plurality of data signals to provide first and second phasor signals, wherein each said first and second phasor signal is indicative of respective first and second voltage phasors associated with the fundamental frequency of the discrete Fourier transform of said first and second cycles, respectively; (c) generating a difference signal representing the angular displacement between said first and second voltage phasors and, therefore, representing the difference between said first and second frequencies; and (d) modulating said first period in response to said difference signal such that said difference signal is minimized and, therefore, said first frequency is maintained in substantially constant proportion to said second frequency. - View Dependent Claims (2, 3, 4)
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5. A method for providing a sampling signal having a first frequency corresponding to a first period wherein said first frequency is maintained in substantially constant proportion to a second frequency of an input signal, said method comprising the steps of:
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(a) sampling a first cycle of said input signal at instants determined by said sampling signal and performing a discrete Fourier analysis to provide a first phasor signal indicative of a first voltage phasor associated with the fundamental frequency of the discrete Fourier transform of said first cycle; (b) sampling a second cycle of said input signal at instants determined by said sampling signal and performing a discrete Fourier analysis to provide a second phasor signal indicative of a second voltage phasor associated with the fundamental frequency of the discrete Fourier transform of said second cycle, wherein said first cycle precedes said second cycle by Q cycles; (c) determining whether the angle between said first and second voltage phasors is greater than a predetermined maximum angle and, if so, performing steps (d) and (e), and conversely, if the angle between said first and second voltage phasors is not greater that said predetermined angle, then performing steps (f)-(h); (d) generating a first difference signal representing the angular displacement between said first and second voltage phasors and, therefore, representing the difference between said first and second frequencies; (e) modulating said first period in response to said first difference signal such that said first difference signal is reduced and, therefore, the difference between said first and second frequencies is reduced, and repeating steps (a)-(c); (f) sampling a third cycle of said input signal at instants determined by said sampling signal and performing a discrete Fourier analysis to provide a third phasor signal indicative of a third voltage phasor associated with the fundamental frequency of the discrete Fourier transform of said third cycle, wherein said first cycle precedes said third cycle by M cycles, and wherein M is greater than Q; (g) generating a second difference signal representing the angular displacement between said first and third voltage phasors and, therefore, representing the difference between said first and second frequencies; and (h) modulating said first period in response to said second difference signal such that said second difference signal is minimized and, therefore, said first frequency is maintained in substantially constant proportion to said second frequency, and repeating steps (a)-(c). - View Dependent Claims (6, 7, 8)
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9. Apparatus for providing a sampling signal having a first frequency corresponding to a first period wherein said first frequency is maintained in substantially constant proportion to a second frequency of an input signal, said apparatus comprising:
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(a) means for sampling said input signal at instants determined by said sampling signal to provide first and second pluralities of data signals associated with respective first and second cycles of said input signal, wherein each said data signal represents the magnitude of said input signal at the sampling instant; (b) signal processing means for performing a discrete Fourier analysis on each of said first and second plurality of data signals to provide first and second phasor signals, wherein each said first and second phasor signal is indicative of respective first and second voltage phasors associated with the fundamental frequency of the discrete Fourier transform of said first and second cycles, respectively, said signal processing means being adapted to generate a difference signal representing the angular displacement between said first and second voltage phasors and, therefore, representing the difference between said first and second frequencies, said signal processing means being further adapted to provide said sampling signal and to modulate said first period in response to said difference signal such that said difference signal is minimized and, therefore, said first frequency is maintained in substantially constant proportion to said second frequency. - View Dependent Claims (10, 11, 12, 13)
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Specification