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Kafe 바로가기국가/구분 | United States(US) Patent 등록 |
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국제특허분류(IPC7판) |
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출원번호 | US-0650861 (2007-01-08) |
등록번호 | US-7499740 (2009-03-03) |
발명자 / 주소 |
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출원인 / 주소 |
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인용정보 | 피인용 횟수 : 28 인용 특허 : 775 |
Low power techniques for sensing cardiac pulses in a signal from a sensor are provided. A pulse detection block senses the sensor signal and determines its signal-to-noise ratio. After comparing the signal-to-noise ratio to a threshold, the drive current of light emitting elements in the sensor is d
Low power techniques for sensing cardiac pulses in a signal from a sensor are provided. A pulse detection block senses the sensor signal and determines its signal-to-noise ratio. After comparing the signal-to-noise ratio to a threshold, the drive current of light emitting elements in the sensor is dynamically adjusted to reduce power consumption while maintaining the signal-to-noise ratio at an adequate level. The signal component of the sensor signal can be measured by identifying systolic transitions. The systolic transitions are detected using a maximum and minimum derivative averaging scheme. The moving minimum and the moving maximum are compared to the scaled sum of the moving minimum and moving maximum to identify the systolic transitions. Once the signal component has been identified, the signal component is compared to a noise component to calculate the signal-to-noise ratio.
What is claimed is: 1. A pulse oximeter system comprising: a drive interface that controls drive current of light emitting elements in a pulse oximeter sensor; and a feedback loop coupled around the pulse oximeter sensor and the drive interface that is capable of dynamically adjusting the drive cur
What is claimed is: 1. A pulse oximeter system comprising: a drive interface that controls drive current of light emitting elements in a pulse oximeter sensor; and a feedback loop coupled around the pulse oximeter sensor and the drive interface that is capable of dynamically adjusting the drive current of the light emitting elements based at least in part upon results of a comparison between a signal-to-noise ratio of a pulse oximeter signal and a threshold, wherein the feedback loop is capable of detecting systolic transitions based at least in part upon a multi-step averaging scheme, wherein the pulse oximeter signal is generated by a photodetector in the pulse oximeter sensor. 2. The pulse oximeter system as defined in claim 1 wherein the feedback loop causes the drive current of the light emitting elements to decrease if the signal-to-noise ratio of the pulse oximeter signal is greater than a maximum threshold, and the feedback loop causes the drive current of the light emitting elements to increase if the signal-to-noise ratio of the pulse oximeter signal is less than a minimum threshold. 3. The pulse oximeter system as defined in claim 1 wherein the feedback loop further comprises: a pulse detection block that is capable of calculating the signal-to-noise ratio of the pulse oximeter signal; and a comparator that is capable of performing the comparison of the signal-to-noise ratio of the pulse oximeter signal to the threshold. 4. A method for reducing power consumption in a pulse oximeter sensor, the method comprising: providing drive current to light emitting elements in the pulse oximeter sensor; and dynamically determining a signal-to-noise ratio of a pulse oximeter signal generated by a photodetector in the pulse oximeter sensor, wherein determining the signal-to-noise ratio comprises measuring and storing the noise at each of a plurality of gain stages; and dynamically adjusting the drive current of the light emitting elements based at least in part upon results of a comparison between the signal-to-noise ratio of the pulse oximeter signal and a threshold. 5. The method as defined in claim 4 wherein dynamically adjusting the drive current of the light emitting elements further comprises: increasing the drive current provided to the light emitting elements if the signal-to-noise ratio of the pulse oximeter signal is less than a minimum threshold; and decreasing the drive current provided to the light emitting elements if the signal-to-noise ratio of the pulse oximeter signal is greater than a maximum threshold. 6. A system coupled to a sensor, the system comprising: a transimpedance amplifier capable of receiving a current signal from the sensor and converting the current signal to a voltage signal based at least in part upon a transimpedance gain; an analog-to-digital converter capable of converting the voltage signal into a digital signal; and a feedback loop capable of providing a feedback signal indicating a magnitude of the voltage signal from the transimpedance amplifier when light emitting elements in the sensor are on or off, wherein the transimpedance gain is capable of being adjusted in response to the feedback signal to reduce the environmental DC bias on the voltage signal. 7. The system as defined in claim 6 wherein the sensor is a pulse oximeter sensor containing a photodetector. 8. The system as defined in claim 6 further comprising: a pulse detector that is capable of calculating the signal-to-noise ratio of the signal from the sensor; a comparator that is capable of comparing the signal-to-noise ratio to a threshold; and a drive interface that is capable of controlling drive current of the light emitting elements. 9. A method for controlling drive current of light emitting elements in a pulse oximeter sensor, comprising: using a pulse oximeter: measuring a noise component of a pulse oximeter signal; identifying a systolic period of the pulse oximeter signal; performing first pulse qualification tests to qualify a systolic period for pulse rate measurement; performing second pulse qualification tests to qualify the systolic period for oxygen saturation calculations, if the systolic period is qualified for pulse rate measurement; determining a strength of the systolic period if the systolic period is qualified for oxygen saturation calculations; identifying a signal-to-noise ratio by comparing the strength of the systolic period to the noise component; and controlling the drive current based at least in part upon a comparison of the signal-to-noise ratio to a threshold. 10. The method of claim 9, comprising measuring the noise component before determining the strength of the systolic period and storing the measured noise component in memory for comparison with the strength of the systolic period. 11. The method of claim 9, comprising measuring the noise in the pulse oximeter signal at various gain values. 12. The method of claim 9, wherein the threshold comprises a maximum signal-to-noise ratio value of 128:1. 13. The method of claim 9, wherein the threshold comprises a minimum signal-to-noise ratio value of 8:1. 14. The method of claim 9, comprising calculating a series of moving averages based at least in part upon a derivative of the pulse oximeter signal to identify the systolic period. 15. The method of claim 14, comprising identifying a moving minimum and moving maximum of a last moving average of the series of moving averages to identify the systolic period. 16. The method of claim 9, comprising calculating a moving average of a derivative of the pulse oximeter signal to generate a first output, calculating a moving average of the first output to generate a second output, calculating a moving average of the second output to generate a third output, and identifying a moving minimum and a moving maximum of the third output to identify the systolic period. 17. The method of claim 16, comprising comparing the moving minimum and the moving maximum to a scaled sum of the moving minimum and the moving maximum to determine the systolic period. 18. A monitor for controlling drive current of light emitting elements in a pulse oximeter sensor, comprising: an identification module capable of identifying a systolic period of a pulse oximeter signal; a qualification module capable of performing multiple stages of pulse qualification tests to qualify the systolic period for oxygen saturation calculations; a strength determination module capable of determining a strength of the systolic period if the systolic period is qualified for oxygen saturation calculations; a ratio module capable of identifying a signal-to-noise ratio by comparing the strength of the systolic period to a measured value of a noise component of the pulse oximeter signal stored in a memory; and a controller capable of controlling the drive current based at least in part upon a comparison of the signal-to-noise ratio to a threshold. 19. The monitor of claim 18, comprising a measurement module capable of measuring the noise component. 20. The monitor of claim 19, wherein the measurement module is capable of measuring the noise component at various gain values. 21. The monitor of claim 18, wherein the threshold comprises a maximum signal-to-noise ratio value of 128:1. 22. The monitor of claim 18, wherein the threshold comprises a minimum signal-to-noise ratio value of 8:1. 23. The monitor of claim 18, comprising a calculation module capable of calculating a series of moving averages based at least in part upon a derivative of the pulse oximeter signal to identify the systolic period. 24. The monitor of claim 23, wherein the calculation module is capable of identifying a moving minimum and moving maximum of a last moving average of the series of moving averages to identify the systolic period. 25. The monitor of claim 18, comprising a calculation module capable of calculating a moving average of a derivative of the pulse oximeter signal to generate a first output, calculating a moving average of the first output to generate a second output, calculating a moving average of the second output to generate a third output, and identifying a moving minimum and a moving maximum of the third output to identify the systolic period. 26. The monitor of claim 25, comprising a comparison module capable of comparing the moving minimum and the moving maximum to a scaled sum of the moving minimum and the moving maximum to determine the systolic period. 27. A tangible computer-readable medium, comprising: code capable of identifying a systolic period of a pulse oximeter signal, wherein identifying a systolic period comprises calculating a moving average; code capable of performing pulse qualification tests to qualify the systolic period for oxygen saturation calculations; code capable of determining a strength of the systolic period if the systolic period is qualified for oxygen saturation calculations; code capable of identifying a signal-to-noise ratio by comparing the strength of the systolic period to a measured value of a noise component of the pulse oximeter signal; and code capable of controlling the drive current based at least in part upon a comparison of the signal-to-noise ratio to a threshold. 28. The tangible computer-readable medium of claim 27, comprising code capable of measuring the noise component of the pulse oximeter signal. 29. The tangible computer-readable medium of claim 27, comprising code capable of calculating a moving average of a derivative of the pulse oximeter signal to generate a first output, calculating a moving average of the first output to generate a second output, calculating a moving average of the second output to generate a third output, and identifying a moving minimum and a moving maximum of the third output to identify the systolic period.
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