[미국특허]
System and method for measuring battery current
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61N-001/36
A61N-001/378
A61N-001/37
출원번호
US-0829825
(2001-04-10)
발명자
/ 주소
Stessman, Nicholas J.
출원인 / 주소
Cardiac Pacemakers, Inc.
대리인 / 주소
Schwegman, Lundberg, Woessner & Kluth, P.A.
인용정보
피인용 횟수 :
68인용 특허 :
9
초록▼
Systems, devices and methods are provided for measuring battery current. According to one aspect, a medical device is provided that comprises a battery, a pulse generator, and a current measuring device. The pulse generator draws a pulse generator current from the power source, and the current measu
Systems, devices and methods are provided for measuring battery current. According to one aspect, a medical device is provided that comprises a battery, a pulse generator, and a current measuring device. The pulse generator draws a pulse generator current from the power source, and the current measuring device determines the pulse generator current or tracks charge depletion from the battery. The current measuring device comprises an oscillator and a counter. The oscillator produces an oscillating output with a frequency of oscillation dependent on the pulse generator current, and the counter provides an oscillation count for the oscillating output. The current measuring device is capable of being calibrated while continuously determining the pulse generator current. In one embodiment, the current measuring device includes at least two current sources, each including an operational amplifier that has an autozeroing feature.
대표청구항▼
Systems, devices and methods are provided for measuring battery current. According to one aspect, a medical device is provided that comprises a battery, a pulse generator, and a current measuring device. The pulse generator draws a pulse generator current from the power source, and the current measu
Systems, devices and methods are provided for measuring battery current. According to one aspect, a medical device is provided that comprises a battery, a pulse generator, and a current measuring device. The pulse generator draws a pulse generator current from the power source, and the current measuring device determines the pulse generator current or tracks charge depletion from the battery. The current measuring device comprises an oscillator and a counter. The oscillator produces an oscillating output with a frequency of oscillation dependent on the pulse generator current, and the counter provides an oscillation count for the oscillating output. The current measuring device is capable of being calibrated while continuously determining the pulse generator current. In one embodiment, the current measuring device includes at least two current sources, each including an operational amplifier that has an autozeroing feature. The image data is updated on a periodic basis. inescence phases at different frequencies for cancellation of the instrumental frequency response. 12. A simultaneous photothermal radiometric and luminescence method for imaging of a tooth surface and detection of the tooth defects intraorally, comprising the steps of: scanning a tooth surface intraorally by irradiating the tooth surface with a light source at fixed frequency wherein a photothermal radiometric signals and luminescence signal is responsively emitted from said tooth; detecting said emitted photothermal radiometric signals and said luminescence signals; demodulating said emitted photothermal radiometric signals into photothermal phase and amplitude signals and said luminescence signals into luminescence phase and amplitude signals using a lock-in amplifier and normalizing said demodulated photothermal phase and amplitude signals and normalizing said demodulated luminescence phase and amplitude signals to cancel light source fluctuations and lock-in amplifier dependencies; and comparing said normalized photothermal phase and normalized amplitude signals to photothermal phase and amplitude signals of a reference sample and comparing said normalized luminescence phase and normalized amplitude signals to luminescence phase and amplitude signals of a reference sample to determine differences between said portion of said tooth and said reference sample thereby identifying defects in said tooth. 13. The method according to claim 12 wherein upon detecting a defective portion of a tooth such as cracks and fissures in the tooth, carious lesions or decayed portions including treatment of said tooth by; the preparation of the tooth surface for bonding the material by etching using one of a laser or acid, and curing or initiation of curing of a light cured or dual cured composite resin to restore the defect or carious lesion or to seal the fissure or defect in question. 14. A device for photothermal radiometric and luminescence for inspection of teeth, comprising the steps of: a light source for irradiating a portion of a surface of a tooth with an effective wavelength wherein photothermal radiometric signals and luminescence signals are responsively emitted from said portion of the tooth; detection means for detecting said emitted photothermal signals and said luminescence signals; demodulating means for demodulating said emitted photothermal signals into photothermal phase and amplitude components and said luminescence signals into luminescence phase and amplitude signals; and processing means for comparing said photothermal phase and amplitude signals to photothermal phase and amplitude signals of a reference sample and comparing said luminescence phase and amplitude signals to luminescence phase and amplitude signals of a reference sample to determine differences between said portion of said tooth and said reference sample and correlating said differences with defects in said tooth. 15. The device according to claim 14 wherein said light source is a laser emitting in the near-ultraviolet, visible, or near-infrared spectral ranges. 16. The device according to claim 14 wherein said demodulation means is a lock-in amplifier. 17. The device according to claim 14 including a laser for preparation of a defective tooth portion and curing of dental resins. median of two or more earlier heart rate values, the heart beat candidate is accepted as a heart beat detection, if the momentary heart rate value calculated on the basis of the heart beat candidate is, when compared with the median value, within threshold values of the median value, and updating as the heart rate value the momentary heart rate value calculated on the basis of the accepted heart beat detection. 2. A method as claimed in claim 1 wherein the EKG signal is analyzed in the rationality analysis using an approximately three-second time window, and the median value of the heart rate is calculated on the basis of the accepted heart beat detections in the time window. 3. A method as claimed in claim 1, wherein the EKG signal is analyzed in the rationality analysis using a time window, and if there are more than one heart beat candidate in the time window, the heart beat candidate is selected as the heart beat detection, the heart rate value calculated from which is closest to the valid heart rate value. 4. A method as claimed in claim 1, wherein the EKG signal is analyzed in the rationality analysis using a time window, and if there are more than one heart beat candidate in the time window, the heart beat candidate is selected as the heart beat detection, the heart rate value calculated from which is closest to the median value of the heart rate. 5. A method as claimed in claim 1, wherein the EKG signal is analyzed in the rationality analysis using a time window, and the median value of the heart rate is calculated on the basis of the accepted heart beat detections in the time window, and approximately ten beats a minute is used as the threshold value of the median. 6. A method as claimed in claim 1, wherein an EKG signal is measured from a person's hands in an exercise apparatus having handles, in which a measuring electrode is located in both handles of the exercise apparatus for setting against the skin of the person's hand for the purpose of measuring the EKG signal. 7. A method as claimed in claim 1, wherein a signal is measured from a person's skin at a minimum of two measuring points, and an analog EKG signal is formed by means of the potential difference of said signals, the EKG signal is converted into digital format to be a sample signal containing samples, the sample signal is read one sample at a time until a first sample can be located from the sample signal, which exceeds a threshold value set to a first maximum value of the EKG signal and contains a local maximum, and until a second sample can be located from the sample signal, which is lower than a minimum value of the EKG signal and contains a local minimum, and until a third sample can be located from the sample signal, which exceeds a threshold value set to a second maximum value of the EKG signal and contains a second local maximum, the part of the sample signal formed by the first, second and third sample is accepted as the heart beat candidate. 8. A method as claimed in claim 7, wherein a threshold value is used for the first maximum value, which is approximately 50% of the average R peak amplitude of the earlier accepted heart beat detections of the person. 9. A method as claimed in claim 7, wherein the average noise level is calculated during the measurement of the EKG signal, and a threshold value is used for the first maximum value, which is approximately 150% with respect to the average of noise. 10. A method as claimed in claim 7, wherein the same threshold value is used for the minimum value and the second maximum value as for the first maximum value. 11. A method as claimed in claim 7, wherein the time difference between the first sample and the second sample is calculated, and a part of the sample signal is accepted as a heart beat only if the time difference is within the limits defined by the threshold values set for the time difference. 12. An arrangement for detecting a heart beat and calculating heart rate on the basis o f the detected heart beats, comprising: at least one measuring electrode for measuring a signal from the skin of one hand of a person, and at least one measuring electrode for measuring a signal from the skin of the other hand, an amplifier connected to said measuring electrodes for amplifying the potential difference of the signals measured by the measuring electrodes for the purpose of forming an EKG signal, an analog-to-digital converter for receiving the signal from the amplifier and for converting the signal into digital format to be a sample signal containing samples, and a computer which is arranged: to read the digital signal and to detect from the sample signal a heart beat candidate, to perform a rationality analysis for the heart beat detection, in which the computer is arranged: to calculate a time difference between the heart beat candidate and the heart beat detection preceding it, and to calculate on the basis of the time difference, a momentary heart rate value, to compare the calculated momentary heart rate value with a median value of the heart rate, which is a median of two or more earlier calculated heart rate values, to accept the heart beat candidate as a heart beat detection, if the momentary heart rate value calculated on the basis of the heart beat candidate is, when compared with the median value, within threshold values of the median value, and to update as the heart rate value the momentary heart rate value calculated on the basis of the accepted heart beat detection, the arrangement further comprising display means connected to the computer and displaying the calculated heart rate value on the basis of the accepted heart beat detections. 13. An arrangement as claimed in claim 12, wherein the computer is arranged to analyze the EKG signal in the rationality analysis using an approximately two-second time window, and to calculate the median value of the heart rate on the basis of the accepted heart beat detections in the time window. 14. An arrangement as claimed in claim 12, wherein the computer is arranged to analyze the EKG signal in the rationality analysis using a time window, and if there are more than one heart beat candidate in the time window, to select as the heart beat detection the heart beat candidate, the heart rate value calculated from which is closest to the valid heart rate value. 15. An arrangement as claimed in claim 12, wherein the computer is arranged to analyze the EKG signal in the rationality analysis using a time window, and if there are more than one heart beat candidate in the time window, to select as the heart beat detection the heart beat candidate, the heart rate value calculated from which is closest to the median of the heart rate. 16. An arrangement as claimed in claim 12, wherein the computer is arranged to analyze the EKG signal in the rationality analysis using a time window, and to calculate the median value of the heart rate on the basis of the accepted heart beat detections in the time window, and to use approximately ten beats a minute as the threshold value of the median. 17. An arrangement as claimed in claim 12, wherein the arrangement is an exercise apparatus comprising handles for supporting the hands during exercise, and measuring electrodes are placed in the handles of the exercise apparatus so that both handles have at least one measuring electrode for setting against the skin of the person's hand for the purpose of measuring the EKG signal. 18. An arrangement as claimed in claim 12, wherein the computer is arranged to read the sample signal one sample at a time until a first sample can be located from the sample signal, which exceeds a threshold value set to a first maximum value of the EKG signal and contains a local maximum, and until a second sample can be located from the sample signal, which is lower than a minimum value of the EKG signal and contains a local minimum, and until a third sample can be located from the sample signal, which exceeds a threshold value set to a second maximum value of the EKG signal and contains a second local maximum, and to accept the part of the sample signal formed by the first, second and third sample as the heart beat candidate. 19. An arrangement as claimed in claim 18, wherein the computer is arranged to use for the first maximum value a threshold value which is approximately 50% of the average R peak amplitude of the earlier accepted heart beat detections of the person. 20. An arrangement as claimed in claim 18, wherein the computer is arranged to calculate the average noise level during the measurement of the EKG signal, and to use for the first maximum value a threshold value which is approximately 150% with respect to the average of noise. 21. An arrangement as claimed in claim 18, wherein the computer is arranged to use the same threshold value for the minimum value and the second maximum value as for the first maximum value. 22. An arrangement as claimed in claim 18, wherein the computer is arranged to calculate the time difference between the first sample and the second sample, and to accept a part of the sample signal as a heart beat detection only if the time difference is within the limits defined by the threshold values set for the time difference.
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