Iterative precision spectrum analysis
First Claim
1. A method comprising:
- generating a long quasi-random staggered pulse sequence code containing quasi-random bi-polar phase changes; and
allocating a substantial portion of the pulse sequence code, when there is no transmission, to sine and cosine reception samples.
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Abstract
Simultaneous improvement in resolution, frequency range, dynamic ranges, as well as signal-to-noise ratio of spectrum analysis is possible by the huge increase in speed and capacity of digital data processing. In coherent pulse sounding (especially in monostatic Radar and Sonar), precise determination of the frequency, amplitude, and phase of wanted signals and unwanted interferers in the frequency domain and their elimination in the time domain data set leads to substantial improvement in the dynamic range of the analysis. Thus, a new apparatus and method of unevenly spaced transmitter pulses becomes feasible to increase the number of samples in a time period limited by the coherency requirements of the data set. The invented apparatus and method overcomes the inherent limitation in dynamic range of the spectral amplitudes due to cross-talk and sparse sampling. Non-linear spectrum analysis can improve signal-to noise further. Pre-cleaning of spread-spectrum data is another application of this method.
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Citations
4 Claims
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1. A method comprising:
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generating a long quasi-random staggered pulse sequence code containing quasi-random bi-polar phase changes; and
allocating a substantial portion of the pulse sequence code, when there is no transmission, to sine and cosine reception samples.
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2. A method comprising:
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translating time samples from active equally-spaced or staggered pulse soundings or from passive reception to raw spectrum data;
pre-cleaning the raw spectrum data by identifying the largest coherent interference;
removing sine and cosine functions corresponding to the accurate magnitude and phase of this coherent interference from corresponding time-domain data; and
repeating this process until all interference is below a specified level.
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3. The method as claimed in 1 further including:
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sequentially applying an individual phase code for each delay range;
determining the exact frequency of the largest Doppler amplitude of any delay range;
storing this information and subtracting its values from the time sequence; and
repeating the process until a sufficient amount of information is stored.
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4. The method as claimed in 2 further including:
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translating time samples by non-linear spectrum analysis in averaging the products of the first, third, and fifth power of the time sequence data with the respective power of the sine and cosine functions;
changing the exact frequency and phase of the trigonometric function in small steps to find the largest signal;
recording and eliminating the exact frequency, magnitude and phase of the signal in the time domain; and
repeating the process until a sufficient amount of useful data is generated and stored.
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Specification