Method for recording skin galvanic reactions and device for realizing the same

US 6,167,299 A
Filed: 04/23/1999
Issued: 12/26/2000
Est. Priority Date: 05/28/1996
Status: Expired due to Fees

First Claim

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1. A method of galvanic skin reactions monitoring comprising the operations:

fastening of two electrodes on the body of a subject,application of electric voltage to the said electrodes,monitoring time variations of electric current flowing between said electrodes,registering electric current pulses in the frequency band of an electrodermal activity phasic component, andanalysis of the shape of each of said pulses, wherein;

(a) the signal is registered as the time derivative of the logarithm of electric current numerical value,(b) the trend value is defined, said trend value being caused by signal variations in the frequency band of electrodermal activity tonic component, and adjustment of the first derivative value is performed by subtracting the value of the trend from the said first derivative value,(c) the second derivative in time of said numerical value of the logarithm of the electric current is registered,(d) the pulse onset of said signal is determined as the moment of said second derivative exceeding a threshold value, and(e) conformity of the pulse shape to the preset criteria is determined,said pulse being classified as a phasic component pulse provided existence of this conformity and as an artifact otherwise.

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Abstract

In the field of medicine and medical engineering, in particular to methods and devices for diagnostics of the status of an alive organism basing on skin electrical conductivity, a method and device for monitoring galvanic skin reactions is usable in experimental and clinical medicine, as well as in psychophysiology, pedagogics and sports medicine. The device enables to eliminate interference caused by artifacts of a subject'"'"'s movements as well as interference brought about by non-biological causes (various electrical noises and equipment drift). The method is featured by the fact that the shape of each pulse of the sequence of pulses is being analyzed in the phasic component frequency band. For this purpose monitored are the first and the second derivatives in time of the logarithm of skin electric conductivity. The value of the trend brought about by the tonic component is determined, and the value of the first derivative is adjusted through subtraction of the trend value from it. Further, the time of the onset of the first derivative pulse is determined as the moment of the second derivative exceeding a threshold value, and then the shape of said pulse is analyzed. The analysis of the pulse shape could be carried out either by hardware or by software method. Should the parameters of this shape meet certain preset criteria, the analyzed pulse is classified as a pulse of the phasic component, otherwise it is put down to artifacts. Two devices for galvanic skin reaction monitoring are described.

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14 Claims

1. A method of galvanic skin reactions monitoring comprising the operations:
- fastening of two electrodes on the body of a subject,application of electric voltage to the said electrodes,monitoring time variations of electric current flowing between said electrodes,registering electric current pulses in the frequency band of an electrodermal activity phasic component, andanalysis of the shape of each of said pulses, wherein;
  
  (a) the signal is registered as the time derivative of the logarithm of electric current numerical value,(b) the trend value is defined, said trend value being caused by signal variations in the frequency band of electrodermal activity tonic component, and adjustment of the first derivative value is performed by subtracting the value of the trend from the said first derivative value,(c) the second derivative in time of said numerical value of the logarithm of the electric current is registered,(d) the pulse onset of said signal is determined as the moment of said second derivative exceeding a threshold value, and(e) conformity of the pulse shape to the preset criteria is determined,said pulse being classified as a phasic component pulse provided existence of this conformity and as an artifact otherwise.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. A method according to claim 1, wherein the trend value (b) is determined as an average value of the first derivative over an interval of time, basically, 30 to 120 seconds.
  - 3. A method according to claim 2, wherein the time of arrival of said first derivative pulse is determined as the moment of the second derivative (c) exceeding the threshold value by at least by 0.2%.
  - 4. A method according to claim 1, wherein the trend value (b) is determined as an average value of the first derivative over an interval of time of 1-2 seconds, provided that values of the first and the second derivative during this interval of time are less than preset threshold values.
  - 5. A method according to claim 4, wherein the time of arrival of said first derivative pulse is determined as the moment of the second derivative (c) exceeding the threshold value by at least by 0.2%.
  - 6. A method according to claim 1, wherein the time of arrival of said first derivative pulse is determined as the moment of the second derivative (c) exceeding the threshold value by at least by 0.2%.
  - 7. A method according to claim 1, wherein in determining the pulse shape, registered are the maximum (f_MAX) and the minimum (f_MIN) values of the first derivative minus the trend value (b), their ratio (r), the interval of time (t_x) between the minimum and the maximum of the first derivative, the moments of achievement by the first derivative of the maximum and the minimum values being determined as the moments of change of sign of the second derivative (c).
  - 8. A method according to claim 7, wherein said preset criteria (e) of the analyzed pulse belonging to phasic component of EDA are determined as the following inequalities:
    - space="preserve" listing-type="equation">0.5<
      
      f.sub.MAX <
      
      10
      space="preserve" listing-type="equation">-2<
      
      f.sub.MIN <
      
      -0.1
      space="preserve" listing-type="equation">1.8<
      
      t.sub.x <
      
      7
      space="preserve" listing-type="equation">1.5<
      
      r<
      
      10.

9. A device for monitoring of galvanic skin reactions comprising:
- (a) an input unit connected to a plurality of electrodes and including a means of fastening said electrodes to a subject'"'"'s skin,(b) means for suppression of pulse interference,(c) means for signal discrimination in the frequency band of an electrodermal activity phasic component,(d) means for phasic component pulses detection, and(e) a monitoring unit having at least one input,wherein the improvement consists in the assembly comprising the means for signal discrimination in the frequency band of electrodermal activity phasic component (c), and the means for phasic component pulses detection (d) being embodied as the assembly comprising;
  
  (f) a unit for conversion of the logarithm of the input signal into the first and the second time derivatives, and(g) a pulse shape analysis unit,wherein the said means for suppression of pulse interference (b), the unit (f) for conversion of the logarithm of the input signal into the first and the second derivatives, and the pulse shape analysis unit (g) are connected serially to the input unit (a), the output of the pulse shape analysis unit (g) being connected to the input of the monitoring unit (e).
- View Dependent Claims (10, 11, 12, 13)
- - 10. A device according to claim 9, wherein the assembly of the means for suppression of pulse interference (b), the means for signal discrimination in the frequency band of electrodermal activity phasic component (c), and the means for said component pulses detection (d) is embodied as the assembly comprising:
    - (f) a unit for conversion of the logarithm of the input signal into the first and the second time derivatives,(g) a pulse shape analysis unit, and(i) a low pass filter,wherein said lowpass filter (i), the unit (f) for conversion of the logarithm of the input signal into the first and the second time derivatives, and the pulse shape analysis unit (g) are connected serially to the input unit (a), the output of the pulse shape analysis unit (g) being connected to the input of the monitoring unit (e).
  - 11. A device according to claim 9, wherein the input unit (a) is a stabilized source of electric voltage and a resistor connected serially to the electrodes, a logarithmic amplifier with a differential input stage, said resistor shunting the inputs of the said logarithmic amplifier.
  - 12. A device according to claim 9, where in the unit for conversion of the logarithm of the input signal into the first and the second time derivatives (f) is embodied as a first differentiator (j) and a second differentiator (k) and a second lowpass filter (l), the output of the first differentiator (j) being connected to inputs of the second differentiator (k) and of the second lowpass filter (l), the outputs of which are the outputs of the unit (f) for conversion of the logarithm of the input signal into the first and the second time derivatives.
  - 13. A device according to claim 9, wherein the unit for pulse shape analysis (g) further comprises:
    - (m) means for determining of the maximum variation rate of the signal at leading and trailing edges of the pulse being analyzed,(n) means for determining of its shape asymmetry,(o) means for determining of the pulse width, and(p) means for comparison of said values with the preset limits for generation of a signal indicating belonging of the pulse being analyzed to electrodermal activity phasic component.

14. A device for monitoring of galvanic skin reactions comprising:
- (a) an input unit with electrodes connected to it and with a means of their fastenings to a subject'"'"'s skin,(b) means for suppression of pulse interference,(c) means for signal discrimination in the frequency band of electrodermal activity phasic component,(d) means for phasic component pulses detection, and(e) a monitoring unit,wherein the improvement consists in the input unit (a) being a stabilized source of dc electric voltage and a resistor connected serially to the electrodes, an amplifier with a differential input stage, said resistor shunting the inputs of the said amplifier, and the output of said amplifier being connected to the input of an analog-to-digital converter (q) the digital output of which is the output of the unit (a);
  
  with this, the means (b), (c), (d), (e) are implemented as a program executed by a computer (r), the digital input of which is connected to the output of the input unit (a).

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Current Assignee
Zakrytoe Aktsionernoe Obschestvo "Neurocom"
Original Assignee
Zakrytoe Aktsionernoe Obschestvo "Neurocom"
Inventors
Shakhnarovich, Vjacheslav Markovich, Galchenkov, Leonid Arkad'evich, Dementienko, Valery Vasiljevich, Koreneva, Lidyja Georgievna, Markov, Andrey Genrikhovich
Primary Examiner(s)
Kamm, William E.

Application Number

US09/194,352
Time in Patent Office

613 Days
Field of Search

600/346, 600/547
US Class Current

600/547
CPC Class Codes

A61B 5/0533   Measuring galvanic skin res...

A61B 5/16   Devices for psychotechnics ...

A61B 5/7207   of noise induced by motion ...

A61B 5/7239   using differentiation inclu...

A61N 1/06   for high-frequency therapy

Method for recording skin galvanic reactions and device for realizing the same

First Claim

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Abstract

49 Citations

14 Claims

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Method for recording skin galvanic reactions and device for realizing the same

First Claim

1 Assignment

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Accused Products

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Abstract

49 Citations

14 Claims

Specification

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Solutions

Use Cases

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