Method and apparatus for displaying multi-frequency bio-impedance
First Claim
1. A method for detecting the complex impedance of biological tissue at a sinusoidal frequency comprising the steps of:
- selecting a sinusoidal frequency value;
selecting a first sampling rate no less than 400% of said sinusoidal frequency;
selecting a second sampling rate no less than first said sampling rate;
generating a series of excitation pulses at said first sampling rate to form an excitation signal comprising a component at said sinusoidal frequency having a predetermined magnitude;
spanning said biological tissue with at least one pair of electrically conductive terminals;
applying said excitation signal across said at least one pair of terminals to said biological tissue;
detecting a response signal comprising the response of said biological tissue to said applied excitation signal;
sampling said excitation signal at said second sampling rate to form a series of excitation samples;
sampling said response signal at said second sampling rate in synchronism with said excitational sampling step to form a series of response samples;
delaying said excitation samples by a delay time substantially equal to one-fourth cycle of said sinusoidal frequency to form a series of delayed excitation samples;
multiplying each said excitation sample by the simultaneous said response sample to form a first impedance sample;
multiplying each said delayed excitation sample by the simultaneous said response sample to form a second impedance sample;
averaging said first and second impedance samples over time to form first and second mean impedance signals, respectively; and
providing an output comprising said first and second means impedance signals representative of the complex impedance of said biological tissue.
1 Assignment
0 Petitions
Accused Products
Abstract
A method and apparatus for displaying complex impedance and related physical characteristics of an object at a plurality of sinusoidal frequencies over a wide frequency range. Excitation signal waveforms are stored in digital form. Digital sampling and processing circuitry provide high noise immunity and accurate measurement at all impedance phase angles. The technique is particularly well-suited to the measurement of complex impedances in living biological tissue because the digital implementation results in highly accurate measurement values over a plurality of selectable frequencies within a wide sinusoidal frequency region. A novel adaptation of digital cross-correlation and convolution techniques is used to simultaneously display real and imaginary electrical impedance of living biological tissue at several selectable sinusoidal frequencies.
-
Citations
22 Claims
-
1. A method for detecting the complex impedance of biological tissue at a sinusoidal frequency comprising the steps of:
-
selecting a sinusoidal frequency value; selecting a first sampling rate no less than 400% of said sinusoidal frequency; selecting a second sampling rate no less than first said sampling rate; generating a series of excitation pulses at said first sampling rate to form an excitation signal comprising a component at said sinusoidal frequency having a predetermined magnitude; spanning said biological tissue with at least one pair of electrically conductive terminals; applying said excitation signal across said at least one pair of terminals to said biological tissue; detecting a response signal comprising the response of said biological tissue to said applied excitation signal; sampling said excitation signal at said second sampling rate to form a series of excitation samples; sampling said response signal at said second sampling rate in synchronism with said excitational sampling step to form a series of response samples; delaying said excitation samples by a delay time substantially equal to one-fourth cycle of said sinusoidal frequency to form a series of delayed excitation samples; multiplying each said excitation sample by the simultaneous said response sample to form a first impedance sample; multiplying each said delayed excitation sample by the simultaneous said response sample to form a second impedance sample; averaging said first and second impedance samples over time to form first and second mean impedance signals, respectively; and providing an output comprising said first and second means impedance signals representative of the complex impedance of said biological tissue. - View Dependent Claims (2, 3)
-
-
4. A method for determining the complex impedance of biological tissue over a range of sinusoidal frequencies comprising the steps of:
-
selecting a first sampling of no less than 400% of the maximum said sinusoidal frequency; selecting a second sampling rate no less than said first sampling rate; generating a series of excitation pulses at said first sampling rate to form an excitation signal; spanning said biological tissue with at least one pair of terminals; applying said excitation signal to said at least one pair of terminals across said biological tissue; detecting a response signal comprising the response of said biological tissue to said applied excitation signal; sampling said excitation signal and said response signal in synchronism at said second sampling rate to form a series of synchronous excitation samples and response samples, respectively; computing the complex cross-correlation of said series of excitation samples and said series of response samples over a predetermined time delay region; computing the real and imaginary components of the Fourier transform of said complex cross-correlation over said range of sinusoidal frequencies to form first and second impedance signals, respectively; computing the square of the magnitude of the Fourier transform of said excitation signal over said range of sinusoidal frequencies to form a calibration signal; displaying the ratios of said first and second impedance signals to said calibration signal to represent said complex impedance of said biological tissue over said range of sinusoidal frequency. - View Dependent Claims (5)
-
-
6. An apparatus for measuring and displaying the complex impedance of biological tissue comprising:
-
at least one pair of terminals disposed in electrical communication with said biological tissue; frequency selection means for selecting at least one sinusoidal frequency; signal generating means for creating an excitation signal across said at least one pair of terminals, said excitation signal having a sinusoidal component at said selected sinusoidal frequency; response detection means for detecting a response signal arising in said biological tissue across said at least one pair of terminals in response to application of said excitation signal; quadrature delay means for delaying said excitation signal by a predetermined time period to create a delayed excitation signal; first multiplier means for multiplying said excitation signal and response signal to form a first impedance signal; second multiplier means for multiplying said delayed excitation signal and response signal to form a second impedance signal; fist averaging means for averaging said first impedance signal over time to form a first mean impedance signal; second averaging means for averaging said second impedance signal over time to form a second mean impedance signal; and display means for displaying said first and second mean impedance signals to represent said complex impedance of said biological tissue at said selected sinusoidal frequency. - View Dependent Claims (7, 8, 9, 10, 11, 12, 13, 14, 15)
-
-
16. An apparatus for measuring and displaying at least one equivalent circuit component arising from a theoretical model of biological tissue comprising:
-
at least one pair of terminals for spanning said biological tissue; frequency selection means for selecting at least one sinusoidal frequency; signal generating means for creating an excitation signal comprising a sinusoidal component at said selected sinusoidal frequency for conduction across said at least one pair of terminals; response detection means electrically connected to said at least one pair of terminals for detecting a response signal arising in said biological tissue in response to application of said excitation signal; quadrature delay means for delaying said excitation signal by a predetermined time period to create a delayed excitation signal; first multiplier means for multiplying said excitation signal and response signal to form a first impedance signal; second multiplier means for multiplying said delayed excitation signal and response signal to form a second impedance signal; first averaging means for averaging said first impedance signal over time to form a first mean impedance signal; second averaging means for averaging said second impedance signal over time to form a second mean impedance signal; first memory means for storing said first and second mean impedance signals to represent said biological signal impedance at said selected sinusoidal frequency; processing means for obtaining a plurality of said first and second mean impedance signals representing said biological tissue impedance at a plurality of selected sinusoidal frequencies; network analyzer means for inverting said plurality of biological tissue impedances to a plurality of equivalent circuit element values; and display means for displaying said plurality of biological tissue equivalent circuit values.
-
-
17. An apparatus for assessing the composition of biological tissue comprising:
-
a wave generator for generating a signal at at least one sinusoidal frequency; a signal generator responsive to said wave generator for generating an excitation signal at said at least one sinusoidal frequency; at least one pair of terminals for spanning said biological tissue and applying said excitation signal thereof; a detector for detecting a response signal arising in said biological tissue in response to application of said excitation signal; delay means for delaying said excitation signal by a predetermined time period to create a delayed excitation signal; first multiplier means for multiplying said excitation signal and response signal to form a fist impedance signal; second multiplier means for multiplying said delayed excitation signal and response signal to form a second impedance signal; first averaging means for averaging said first impedance signal over time to generate a first mean bio-impedance signal; second averaging means for averaging said second impedance signal over time to generate a second mean bio-impedance signal; and an output means for providing said first and second mean impedance signals which represent a complex bio-impedance of said biological tissue at said at least one sinusoidal frequency, wherein said complex bio-impedance is representative of composition of said biological tissue. - View Dependent Claims (18, 19, 20, 21, 22)
-
Specification