Method of detecting system function by measuring frequency response
First Claim
1. A method for detecting function of a unit under test by measuring frequency response the method comprising;
- the acts of;
setting measurement conditions comprising choosing a Root Mean Square (RMS) level of current, identifying a start frequency, and choosing a period of a lowest frequency,selecting a number of octave harmonic frequencies relative to the start frequency over which the function of the unit under test will be tested, wherein the number of octave harmonic frequencies is one or more;
assembling an excitation time record including a sum of sinusoids of the number of octave harmonic frequencies and a duration of the period of the lowest frequency;
conditioning the excitation time record to be compatible with the measurement conditions;
exciting the unit under test with the excitation time record and simultaneously capturing a resulting response time record with a data acquisition system having a sample frequency that is octave related and harmonically related to the frequencies within the sum of sinusoids and at least four times the highest frequency in the sum of sinusoids;
rectifying the response time record relative to a sine at each frequency of the octave harmonic frequencies with a first sine rectification sum m11, comprising;
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Abstract
Real-time battery impedance spectrum is acquired using a one-time record. Fast Summation Transformation (FST) is a parallel method of acquiring a real-time battery impedance spectrum using a one-time record that enables battery diagnostics. An excitation current to a battery is a sum of equal amplitude sine waves of frequencies that are octave harmonics spread over a range of interest. A sample frequency is also octave and harmonically related to all frequencies in the sum. The time profile of this signal has a duration that is a few periods of the lowest frequency. The voltage response of the battery, average deleted, is the impedance of the battery in the time domain. Since the excitation frequencies are known and octave and harmonically related, a simple algorithm, FST, processes the time record by rectifying relative to the sine and cosine of each frequency. Another algorithm yields real and imaginary components for each frequency.
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Citations
12 Claims
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1. A method for detecting function of a unit under test by measuring frequency response the method comprising;
- the acts of;
setting measurement conditions comprising choosing a Root Mean Square (RMS) level of current, identifying a start frequency, and choosing a period of a lowest frequency, selecting a number of octave harmonic frequencies relative to the start frequency over which the function of the unit under test will be tested, wherein the number of octave harmonic frequencies is one or more; assembling an excitation time record including a sum of sinusoids of the number of octave harmonic frequencies and a duration of the period of the lowest frequency; conditioning the excitation time record to be compatible with the measurement conditions; exciting the unit under test with the excitation time record and simultaneously capturing a resulting response time record with a data acquisition system having a sample frequency that is octave related and harmonically related to the frequencies within the sum of sinusoids and at least four times the highest frequency in the sum of sinusoids; rectifying the response time record relative to a sine at each frequency of the octave harmonic frequencies with a first sine rectification sum m11, comprising; - View Dependent Claims (2, 3, 4, 5, 6, 7)
- the acts of;
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8. A method of calibrating phase response of a captured time record for a unit under test by measuring frequency response of a reference standard the method comprising the acts of:
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setting measurement conditions comprising choosing a Root Mean Square (RMS) level of current, identifying a start frequency, and choosing a period of a lowest frequency; determining a theoretical frequency response for the reference standard; selecting a number of frequencies and a frequency spread over which the reference standard will be tested, wherein the frequency spread is by octaves; assembling a phase-shifted excitation time record including a sum of sinusoids of the number of frequencies with a pre-selected phase shift, wherein a duration of the excitation time record is greater than or equal to one period of a lowest of the number of frequencies; conditioning the phase-shifted excitation time record to be compatible with the measurement conditions; exciting the reference standard with the phase-shifted excitation time record and simultaneously capturing a response time record with a data acquisition system having an appropriate sample frequency; processing the response time record to obtain estimated magnitude and estimated phase at each of the number of frequencies to determine the frequency response; wherein, phase calibration is achieved through a selection of multiple known phase-shifts until enough points are obtained to determine phase calibration constants for each of the number of frequencies using a regression analysis. - View Dependent Claims (9, 10, 11, 12)
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Specification