JP2001517128A - Method and apparatus for arbitrating and removing harmonics to obtain the best evaluation of blood component values - Google Patents

Abstract

  (57) [Summary] A method for measuring blood component values using a single data set includes the steps of: (a) providing a plurality of possible blood component values, each having an associated confidence level based on at least one quality metric; The values are determined using a plurality of blood component value calculators, each using one signal data, and (b) determining a plurality of values for the confidence level to measure the blood components. Arbitration between the possible component values of

Description

DETAILED DESCRIPTION OF THE INVENTION Method and apparatus for arbitrating and removing harmonics to obtain the best evaluation of blood component values The present invention relates to a method for measuring physiological parameters, especially for measuring reliability. The present invention relates to a method and apparatus for processing data. In particular, it relates to a method and an apparatus for arbitrating and removing harmonics in order to obtain the best evaluation of blood component values. Pulse oximeters typically measure and display various blood flow characteristics, including hemoglobin oxygen concentration and pulse rate in arterial blood. The oximeter allows light to pass through tissues that are perfused with blood, such as fingers and ears, and photoelectrically detects the light absorption of the tissues. The amount of light absorbed is then used to calculate the amount of blood component (eg, oxyhemoglobin) to be measured. A technique for calculating blood oxygen saturation levels is disclosed in International Patent Application No. IB96 /, filed as a patent application entitled Method and Apparatus for Adaptively Averaging Data Signals, referenced P2l977A. . Information regarding these features of the invention disclosed in this application is hereby incorporated by reference. The disclosed technique relates to assigning different weights to different measurements, wherein the weighted measurements are averaged to obtain a filtered measurement. Kalman filtering techniques have been used to calculate blood oximetry. Kalman filtering allows the parameters to be fitted with least squares when the parameters change over time. Another technique for calculating the blood oxygen saturation level of hemoglobin (a harmonic filter is used to reduce noise effects) is similar to the present application entitled "Method and Apparatus for Harmonically Filtering Data". Filed International Application IB / (ref. P21977D). Information regarding these features of the invention disclosed in that application is incorporated by reference into the specification of this application. A technique for determining pulse rate is disclosed in International Application IB96 / (reference number P21988B), filed in the same application as this application, entitled "Method and Apparatus for Measuring Pulse Rate and Saturation." Information regarding these features of the invention disclosed in that application is incorporated by reference into the specification of this application. The technique disclosed in that application relates to the use of a comb filter to separate signal energy corresponding to the fundamental and related frequencies. The present invention relates to techniques for evaluating signals related to physiological parameters, in particular blood oxygen saturation and pulse rate, and determining whether and how they are displayed. The signal can be derived using techniques of the type disclosed in the specifications of the above three applications. The technique of the present invention involves arbitrating between possible values of the parameter in question according to a confidence level associated with each value based on a quality metric. Accordingly, in one aspect, the invention relates to a method of measuring a blood component value using data comprising a single data set (eg, oxyhemoglobin in blood), comprising: Using blood component values, each having an associated confidence level based on at least one quality metric, using a plurality of blood component value calculators, each using one data set. And (b) arbitrating between a plurality of possible blood component values with respect to a confidence level to determine a measurement of the blood component value. In another aspect, the present invention provides an apparatus for measuring a blood component using a single data set applying the above method. In yet another aspect, the invention provides a method of determining a patient's pulse rate using data comprising a single data set corresponding to electromagnetic energy transmitted through a patient's tissue, the method comprising: The pulse rate, which has an associated confidence level based on at least one quality metric, by using a plurality of pulse rate estimators, the estimator using one data set. Using and determining; and (b) arbitrating between the plurality of possible pulse rates in relation to the confidence level to determine the patient's pulse rate. In yet another aspect, the present invention is to provide an apparatus for determining a patient's pulse rate using a single data set by applying the above method. Preferably, the arbitration step comprises: (a) comparing the confidence level of each value with the confidence level of the other values; and (b) (optionally) measuring at least the initial amount of a blood component or pulse rate, Selecting one of a plurality of possible values having a higher confidence level than all other confidence levels. Preferably, the arbitration step is to provide a measure of the blood component or the patient's pulse rate if none of the confidence levels (if any) are greater than the initial amount and greater than all other confidence levels. Includes linear storage between possible values. When the method measures blood component values, it is preferred that the quality metric is selected from the group consisting of possible blood component value ages and possible blood component value changes. Preferably, in a second aspect of the invention, the pulse rate estimator determines its corresponding possible pulse rate by the following steps. (a) defining a cam filter to remove signal energy from the data corresponding to the fundamental frequency and its harmonics; (b) identifying noise corresponding to the fundamental frequency at the output of the cam filter to minimize noise energy. (C) generating a possible pulse rate corresponding to a particular frequency. Preferably, the step of determining harmonics comprises: (a) calculating a squared noise on the data; (b) calculating a second derivative of the squared noise with respect to the fundamental frequency; and (c) Includes performing a Newton-Raphson search to determine specific harmonics. The determination of the pulse rate by the pulse rate estimator includes: (a) evaluating the power spectrum corresponding to the data to determine which of a plurality of peaks in the power spectrum corresponds to the fundamental frequency; and (b) Confirming that a particular harmonic corresponds to a fundamental frequency based on the evaluation step. When this method determines a patient's pulse rate, the quality metrics include pulse signal shape, signal-to-noise ratio, correlation of at least one wavelength of electromagnetic energy, potential arrhythmias, and It is desirable to select from the group consisting of the correlation between data corresponding to one wavelength. The pulse rate estimator in the second method aspect of the present invention determines its corresponding possible heart rate by: (a) Compare the data to the desired waveform template, (b) identify the square of the waveform feature indicating the waveform period, and (c) average several consecutive waveform periods to determine the average waveform period. And (d) determine the corresponding possible heart rate from the average waveform period. The method includes identifying pulse data that has been disturbed by motion and removing the data. The quality metric may be selected from the group consisting of signs of motion and the percentage of pulse periods that are disturbed by the motion, measured over a time interval. In another aspect, the invention provides a method for determining a patient's pulse rate using data corresponding to at least one wavelength of electromagnetic energy transmitted through a patient's tissue, the method comprising: Tracking the fundamental frequency and filtering the data using a cam filter having a first pulse rate with an associated first confidence level based on at least one quality metric; b) comparing the data with a desired waveform template to form a second pulse rate having an associated second confidence level based on the at least one quality metric; and (c) determining a patient pulse rate. In addition, arbitration between the first and second pulse rates in relation to the first and second confidence levels. Preferably, the tracking step comprises: (a) defining a cam filter to remove signal energy from data corresponding to the fundamental frequency and its harmonics; and (b) reducing noise energy at the output of the cam filter. Including determining a particular harmonic corresponding to the fundamental frequency to be minimized. The method may include filtering the first pulse rate to determine the filtered first pulse rate, for example, by a filtering technique such as Kalman filtering. Preferably, the step of determining the harmonics comprises: (a) calculating the squared noise of the data; (b) calculating the second derivative of the squared noise with respect to the fundamental frequency; and (c). Performing a Newton-Raphson search to determine the fundamental frequency. The tracking step consists of (a) evaluating the power spectrum corresponding to the data to determine which of the peaks in the power spectrum correspond to the fundamental frequency, and (b) identifying specific harmonics in the evaluation step. Verifying that it corresponds to the base frequency based on the method. This may include filtering the first pulse rate to determine the filtered first pulse rate by filtering, for example, Kalman filtering. Preferably, the comparing step of the method comprises: (a) identifying a square of a waveform feature indicative of a waveform period; and (b) averaging a plurality of consecutive waveform periods to determine an average waveform period. And (c) determining a second pulse rate from the average waveform period. Preferably, the arbitration method of the method comprises: (a) comparing the first and second confidence levels; and (b) reducing the patient's pulse rate by at least the first amount. Selecting a first and second level of confidence that is greater than the others of the level. The arbitration step is to form the patient's pulse rate if both the first and second confidence levels are greater than the first amount and greater than the others by the first and second confidence levels. Linearly interpolating between the first and second pulse rates. Preferably, the at least one quality metric corresponding to the first confidence level is selected from the group consisting of a pulse signal shape, a signal-to-noise ratio, a correlation of at least one wavelength of electromagnetic energy, and a possibility of arrhythmia. Preferably, the electromagnetic picture energy has two wavelengths, and the at least one quality metric corresponding to the first confidence level includes a correlation between the data corresponding to the two wavelengths. Preferably, the at least one quality metric corresponding to the second confidence level is selected from a motion indication and a percentage of motion-disturbed pulse periods detected over a time interval. Preferably, the method comprises, before the processing steps: (a) taking the logarithm of a signal representing at least one waveform of electromagnetic energy, and thus generating a first signal; (b) the first signal , And (c) normalizing the second signal, thereby generating data, the tracking step taking the derivative of the data. Including. The present invention relates to reducing noise effects when measuring physiological parameters. Means for reducing noise effects include: means for generating a plurality of measurements derived from at least one wavelength of electromagnetic energy transmitted through living tissue; means for providing a signal indicative of at least one wavelength of electromagnetic energy; Means for comparing the measured value with at least one characteristic of the expected measured value; assigning a plurality of variable weights to each selected measured value based on the comparing step, whereby for each wavelength Means for generating a plurality of differently weighted measurements (where the variable weights are, to some extent, given in response to the closeness between each selected measurement and the corresponding previous measurement) , Variable weights consist of different non-zero numbers), and are weighted differently to obtain filtered measurements for use in assessing physiological parameters. Means for averaging the plurality of measured values, and means for calibrating the system to measure a physiological parameter in response to a signal indicative of at least one wavelength of electromagnetic energy. The present invention also provides a monitor for measuring a physiological parameter (this monitor is used in conjunction with a sensor having emission means for emitting at least one wavelength of electromagnetic energy), a sensor for detecting electromagnetic energy and displaying it. Sensor means for generating a first signal, means for detachably connecting the sensor to the oximeter, means for communicating signals between the sensor and the oximeter, and a second signal indicating at least one wavelength of electromagnetic energy The monitor comprising: means for generating a plurality of measurements derived from the first signal; means for comparing the selected measurements with at least one characteristic of the expected measurements; A variable weight is assigned to each selected measurement based on the comparison step, thereby generating multiple weighted measurements. Means (where the variable weights are applied to some extent in response to the closeness between each selected measurement and the corresponding previous measurement, and the variable weights consist of different non-zero numbers); Means for averaging a number of differently weighted measurements to obtain filtered measurements for use in assessing the physiological parameters, and to determine physiological parameters in response to the second signal. Means for calibrating the monitor to determine The preferred method of processing and displaying blood oxygen saturation and pulse rate for use in hospital rooms is discussed below. With the metrics available from the algorithm for measuring oxygen saturation, the saturation and the calculated pulse value can be evaluated, and therefore, when the current evaluation is not sufficiently reliable, which saturation and Determine which pulse rate of the number is reliable and how long the previously selected saturation or pulse rate is retained. The present invention is applicable to oxygen saturation values calculated using (with or without cardiac gate averaging) the Kalman filtering technique disclosed in the above-mentioned International Application IB96 / (P21977A). The metric that can be calculated from these algorithms is the age: this is twice the effective average period. Deviation: Standard Deviation of Saturation Evaluation at Saturation Point The present invention is applicable to pulse values calculated using the cam filter disclosed in the above-mentioned international application. The metrics that can be calculated from these algorithms are: Relevance: Harmonic strength within the pulse, eg, heuristic metric based on pulse shape S / N: Possibility of signal-to-noise arrhythmia: s / n averaged over time Uncorrelated function decorrelation: √ (1-cross correlation (IR, red) ² ) where the cross correlation spans an appropriate number of sample points. Motion flag: Set when motion is detected. Movement rate: The rate of motion turbulence detected in the last 10 seconds. The confidence interval for the pulse rate measured using the applicable cam filter is related to the validity metric and the arrhythmia likelihood metric. This space is divided into several regions, where one or both metrics are determinants of how the applicable filter tracks the correct pulse rate. Age and deviation metrics can be used to determine saturation. A general algorithm for calculating the age of the output of an IIR filter with the following equation can be described by the following steps (where Filtered and Raw age are known and Flltered (n) is the value of sample number n) Flltered (n + 1) = (1 + W) * Flltered (n) -W * Raw 1) Increase the age of Filtered by the amount of time that has passed since the last computation. 2) Age of Flltered (n + 1) = (1 + W) * Age of Filtered (n) + Age of W * Raw Some of the incoming oximeter signals, independent of the confidence metric, for the parameters in question (eg oximetry and pulse rate) to determine what should appear on the provided display The evaluation of the characteristics of Possible states are: Disconnection: Disconnection when sensor is unplugged: Pulse loss when sensor is not in good contact with patient: Loss of pulse: No pulse when sensor is above patient: No sensor quality: Sensor quality Pulse is present when the oximeter signal arrives from a signal other than the human pulse due to a decrease in the amount of interference and the amount of interference is large: uncertainty when the oximeter signal arrives from the human pulse: disconnected or no pulse The waiting period before declaring the possible actions in response to the manifestation of these various states is to update the display, keep the current value, or clear the display, eg, to blank, dash, or zero . The criteria for the various states are evaluated in the lower order. Pulse Loss: The% IR adjustment was below the threshold in seconds intervals or the criteria for no pulse was met and the previous condition was pulse loss. Non-pulse: High decorrelation, high percentage of energy above 5 Hz, or low percentage IR adjustment. This criterion was true continuously for 10 seconds. If this criterion is true for less than 10 seconds, an uncertain state is declared. Pulse present: state is not one of the above states. The criteria for various display actions are UPDATE when the state is pulsed, HOLD when the state is uncertain or non-contact, and CLEAR when the state is disconnected, pulse loss or non-pulse. The best saturation is displayed when 1) the signal state is UPDATE, and 2) the best saturation is sufficiently up-to-date. Saturation is maintained when 1) the conditions for displaying the best saturation are not met, 2) the displayed saturation is not sufficiently current, and 3) the signal state operation is not CLEAR. The saturation is blank when 1) the condition for displaying the best saturation is not satisfied and 2) the condition for maintaining the saturation is not satisfied. The best heart rate is displayed when 1) the best calculated heart rate is reliable and 2) the signal status action is UPDATE. The heart rate is retained when 1) the conditions for displaying the current heart rate are not met, 2) the displayed heart rate is sufficiently recent, and 3) the signal state action is not CLEAR. The heart rate is blanked when 1) the condition for displaying the current heart rate is not satisfied, and 2) the condition for maintaining the heart rate is not satisfied.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] April 14, 1999 (1999.4.1.14) [Correction contents]                                The scope of the claims 1. A method of measuring a characteristic value of one blood component, (a) obtaining at least one measurement related to the value of the characteristic of the blood component; (b) multiple possible values of a characteristic of a blood component, each of which has at least one quality value; The possible value, having an associated confidence level based on the metric, is Calculating using multiple blood component value calculation techniques applied to measurements from And (c) In order to determine accurate measurements of the characteristics of blood components, the blood Arbitrating between component feature values, A method that includes 2. The method of claim 1, wherein the arbitration step is (a) comparing the confidence level for each of the calculated blood component values; (b) all other confidence levels, at least by the first amount, as measured values of blood components; Selecting one of a plurality of possible blood component values having a confidence level higher than When, A method that includes 3. The method of claim 1, wherein the arbitration step comprises: Any of the confidence levels is greater than the first amount, greater than all others. If possible, average several possible blood component values to form a blood component measurement. Method, including converting 4. The method according to claim 1, wherein at least one quality metric is available. Selected from the group consisting of age of blood component values and possible changes in blood component values That way. 5. The method according to claim 1, wherein the blood component is oxygenated hemoglobin in arterial blood. Including, including methods. 6. A device for measuring a characteristic value of one blood component, (a) means for obtaining at least one measurement related to the value of the characteristic of the blood component (b) multiple possible values of a characteristic of a blood component, each of which has at least one quality value; The possible value, having an associated confidence level based on the metric, is Means to calculate using multiple blood component value calculation techniques applied to measurements from And (c) In order to determine accurate measurements of the characteristics of blood components, the blood Means for mediating between component feature values, Equipment including. 7. The patient's pulse rate is a set of data corresponding to the energy transmitted through the patient's tissue. A method of determining using a set, (a) Use the energy transmitted through the patient's tissue to reduce the amount of energy associated with the patient's pulse rate. Steps to get at least one measurement (b) a plurality of possible values of the patient's pulse rate, each with at least one quality parameter; Apply possible values to the measurements that have an associated confidence level based on the trick Calculating using a plurality of pulse rate calculation techniques, and (c) To determine the patient's pulse rate, the number of possible pulse rates should be Arbitration process, A method that includes 8． The method of claim 7, wherein the arbitrating step comprises: (a) comparing the confidence level for each possible pulse value, and (b) all other confidence levels, at least by the first amount, for the patient's pulse rate; Selecting one of a plurality of possible pulse rates having a greater confidence level, , Including the method. 9． 8. The method of claim 7, wherein the arbitration step is performed at any of the confidence levels. If an amount greater than one is greater than all other confidence levels, the patient's pulse Including averaging between multiple possible pulse rates to form a pulse value, Roller method. Ten. 8. The method according to claim 7, wherein one pulse rate calculation technique is compatible with the pulse rate calculation technique. Pulse value (a) To remove data components corresponding to the fundamental frequency and its harmonics, The process of defining the filter, (b) The fundamental frequency that minimizes noise energy at the output of the cam filter Determining a particular frequency corresponding to the number; and (c) generating a possible pulse rate corresponding to a particular harmonic; Method determined by 11． 11. The method according to claim 10, wherein the calculating step comprises: (a) calculating a squared noise for the data; (b) calculating a second derivative of the squared noise with respect to the fundamental frequency; (c) To determine a specific harmonic, Newton- Steps to perform Raphson survey, , Including the method. 12． A method according to claim 10, wherein (a) Determine which of the peaks in the power spectrum corresponds to the fundamental frequency Evaluating the power spectrum corresponding to the data to determine (b) A process to confirm that a specific harmonic corresponds to the fundamental frequency based on the evaluation process Including, including, method. 13. 11. The method of claim 10, wherein the at least one quality metric is a pulse. Selected from the group consisting of signal shape, signal-to-noise ratio, and arrhythmia potential That way. 14. The method according to claim 10, wherein the electromagnetic energy has two wavelengths, At least one quality metric includes the correlation between the data corresponding to the two wavelengths , Where way. 15． 8. The method according to claim 7, wherein one pulse rate calculation technique has a corresponding pulse rate calculation technique. Good heart rate, (a) comparing the data with a desired waveform template; (b) a step of identifying a square as a characteristic of a waveform indicating a waveform period, (c) averaging a plurality of consecutive waveform periods to determine an average waveform period; and (d) determining the corresponding possible pulse rate from the average waveform period; Calculated by 16． 16. The method of claim 15, wherein the at least one quality metric is a motion metric. Symptoms and percentage of pulse duration measured by motion, measured over time intervals Method selected from the group consisting of: 17． Corresponds to at least one wavelength of electromagnetic energy transmitted through the patient's tissue Using the data to determine a patient's pulse rate, (a) Track the fundamental frequency using an adaptive cam filter and filter the data. Filter, so that relevant information is based on at least one quality metric. Generating a first pulse rate having a first confidence level, (b) comparing the data with the desired waveform template and at least one quality metric Forming a second pulse rate with an associated second confidence level based on the ,and (c) relating to the first and second confidence levels to determine the patient's pulse rate; First and second Arbitration between two pulse rates, Methods including 18． 18. The method according to claim 17, wherein the tracking step comprises: (a) To remove the data components corresponding to the fundamental frequency and its harmonics, Defining the filter; and (b) The fundamental frequency that minimizes noise energy at the output of the cam filter Determining a specific frequency corresponding to the number, , Including the method. 19. 19. The method according to claim 18, wherein the determining step comprises: (a) calculating a squared noise on the data, and (b) calculating the second derivative of the noise squared with respect to the fundamental frequency; and (c) performing a Newton-Raphson study to determine the fundamental frequency; , Including the method. 20. 11. The method according to claim 10, wherein the tracking step comprises: (a) Determine which of the peaks in the power spectrum corresponds to the fundamental frequency To determine Evaluating a power spectrum corresponding to the data; and (b) A process to confirm that a specific harmonic corresponds to the fundamental frequency based on the evaluation process About , Including the method. twenty one. 18. The method according to claim 17, wherein the tracking step is a first filtered step. The method wherein the step includes a step of Kalman filtering the pulse rate. twenty two. 18. The method according to claim 17, wherein the comparing step comprises: (a) identifying a square of a waveform feature indicating a waveform period; (b) averaging a number of consecutive waveform periods to determine an average waveform period ,and (c) determining a second pulse rate from the average waveform period , Including the method. twenty three. 18. The method of claim 17, wherein the arbitration method comprises: (a) comparing the first and second confidence levels; and (b) the first and second confidence levels of the patient's pulse rate by at least the first amount; Le others Selecting one of the first and second confidence levels greater than, , Including the method. twenty four. 18. The method according to claim 17, wherein the arbitration step comprises a first and a second confidence level. Of any of the first and second confidence levels by an amount greater than the first Greater than the first and second pulse rates to form the patient's pulse rate Where the method includes averaging. twenty five. 18. The method according to claim 17, wherein at least one of the first confidence levels corresponds to the first confidence level. The two quality metrics are pulse signal shape, signal-to-noise ratio, and low electromagnetic energy. Selected from the group consisting of at least one wavelength correlation and arrhythmia potential That way. 26. 18. The method according to claim 17, wherein the electromagnetic energy has two wavelengths, At least one quality metric corresponding to one confidence level corresponds to two wavelengths Method, including the correlation between the data to be processed. 27. 18. The method according to claim 17, wherein at least one of the second confidence levels corresponds to the second confidence level. The two quality metrics are motion signs and motion detected over time intervals. Consisting of a fraction of the turbulent pulse duration A method selected from a group. 28. 18. The method according to claim 17, wherein before the comparing step, (a) Take the logarithm of the signal determined by the magnitude of the wavelength of electromagnetic energy, and Generating a first signal by (b) subjecting the first signal to bandpass filtering, thereby generating a second signal Process, and (c) standardizing the second signal, thereby generating data; Including   The tracking process takes the derivative of the data.

Claims (1)

[Claims] 1. A method of measuring blood component values using data from a single data set So, (a) a plurality of possible blood component values, each of which has at least one quality metric; Blood component values that have an associated confidence level based on the Calculators, each of which uses one data set The step of determining using a luculator, and (b) To determine the measurement of blood component values, a number of possible blood Arbitration between component values, A method that includes 2. The method of claim 1, wherein the arbitration step is (a) Determine the confidence level for each possible blood component value and the confidence level for the other blood component values. Comparing with the file, and (b) all other confidence levels, at least for the initial amount, for the measurement of blood components Selecting one of a plurality of possible blood component values having a higher confidence level, A method that includes 3. The method of claim 1, wherein the arbitration step is performed with any confidence level equal to or less than the first amount. Above, generate a blood component measurement if not greater than all other confidence levels A linear interpolation between a plurality of possible blood components to perform the method. 4. The method according to claim 1, wherein at least one quality metric is available. Selected from the group consisting of age of blood component values and possible changes in blood component values That way. 5. The method according to claim 1, wherein the blood component is oxygenated hemoglobin in arterial blood. Including, including methods. 6. An apparatus for measuring blood components using one data set, (a) a plurality of possible blood component values, each of which has at least one quality metric; Blood component values that have an associated confidence level based on the Calculators, each of which uses one data set Means for making decisions using a calculator, and (b) In order to determine the measurement of the blood component value, several possible Means for mediating between liquid component values, Equipment including. 7. Include one data set corresponding to the electromagnetic energy transmitted through the patient's tissue. Determining the pulse rate of the patient using the data (a) multiple possible pulse rates, based on at least one quality metric; The pulse rate, which has a continuous confidence level, is determined by multiple pulse rate estimators. Using an estimator that uses one dataset Process, and (b) multiple possible pulse rates in relation to the confidence level to determine the patient's pulse rate; Arbitration between , Including the method. 8. The method of claim 7, wherein the arbitration step comprises: (a) The confidence level for each possible pulse rate should be Comparing with the file, and (b) all other confidence levels, at least by the first amount, for the patient's pulse rate; Selecting one of a plurality of possible pulse rates having a greater confidence level, , Including the method. 9. The method of claim 7, wherein the arbitration step is performed at any of the confidence levels. The patient's pulse rate if it is greater than all others by more than Including interpolating linearly between multiple possible pulse rates to achieve the method of. Ten. 8. The method according to claim 7, wherein one pulse rate estimator has a corresponding pulse rate estimator. The possible pulse rate (a) removing signal energy from the data corresponding to the fundamental frequency and its harmonics The process of defining the cam filter (b) The fundamental frequency that minimizes noise energy at the output of the cam filter Specific harmonic corresponding to the number The step of determining (c) generating a possible pulse rate corresponding to a particular harmonic; Method determined by 11． 11. The method according to claim 10, wherein the determining step comprises: (a) calculating a squared noise for the data; (b) calculating a second derivative of the squared noise with respect to the fundamental frequency; (c) performing a Newton-Raphson study to determine specific harmonics; , Including the method. 12． The method of claim 10, further comprising: (a) Determine which of the peaks in the power spectrum corresponds to the fundamental frequency Evaluating the power spectrum corresponding to the data to determine (b) A process to confirm that a specific harmonic corresponds to the fundamental frequency based on the evaluation process About , Including the method. 13. 11. The method of claim 10, wherein the at least one quality metric is a pulse. Signal shape, signal-to-noise ratio, correlation of at least one wavelength of electromagnetic energy, And a method selected from the group consisting of arrhythmias and potential arrhythmias. 14. 11. The method according to claim 10, wherein the electromagnetic energy is When there are two wavelengths, at least one quality metric corresponds to two wavelengths Selected from the group consisting of the correlations between the data. 15． 8. The method according to claim 7, wherein the pulse rate estimator comprises: The corresponding possible heart rate, (a) comparing the data with a desired waveform template, (b) a step of identifying a square as a characteristic of a waveform indicating a waveform period, (c) averaging a plurality of consecutive waveform periods to determine an average waveform period; and (d) determining a corresponding possible heart rate from the average waveform period; Method, as determined by 16． 16. The method of claim 15, wherein the at least one quality metric is a motion metric. Symptoms and percentage of pulse duration measured by motion, measured over time intervals Method selected from the group consisting of: 17． Corresponds to at least one wavelength of electromagnetic energy transmitted through the patient's tissue Using the data to determine a patient's pulse rate, (a) Track the fundamental frequency using an adaptive cam filter and filter the data. Filter, so that relevant information is based on at least one quality metric. Generating a first pulse rate having a first confidence level, (b) comparing the data with the desired waveform template and at least one quality metric Forming a second pulse rate with an associated second confidence level based on the ,and (c) relating to the first and second confidence levels to determine the patient's pulse rate; Adjusting between the first and second pulse rates; Methods including 18． 18. The method according to claim 17, wherein the tracking step comprises: (a) removing signal energy from the data corresponding to the fundamental frequency and its harmonics Defining a cam filter to (b) The fundamental frequency that minimizes noise energy at the output of the cam filter Determining a specific harmonic corresponding to the number, , Including the method. 19. 19. The method according to claim 18, wherein the determining step comprises: (a) removing signal energy from the data corresponding to the fundamental frequency and its harmonics The process of defining the cam filter to (b) The fundamental frequency that minimizes noise energy at the output of the cam filter Determining a specific harmonic corresponding to the number, , Including the method. 20. 11. The method according to claim 10, wherein the tracking step comprises: (a) Determine which of the peaks in the power spectrum corresponds to the fundamental frequency Evaluating the power spectrum corresponding to the data to determine (b) A process to confirm that a specific harmonic corresponds to the fundamental frequency based on the evaluation process About , Including the method. twenty one. 18. The method according to claim 17, wherein the tracking step comprises: Kalman filtering to determine the first pulse rate filtered The method, including the step of: twenty two. 18. The method according to claim 17, wherein the comparing step comprises: (a) identifying a square of a waveform feature indicating a waveform period; (b) averaging a plurality of consecutive waveform periods to determine an average waveform period ,and (c) determining a second pulse rate from the average waveform period , Including the method. twenty three. 18. The method of claim 17, wherein the arbitration method comprises: (a) comparing the first and second confidence levels; and (b) increase the patient's heart rate by at least the first amount, at the first and second confidence levels; Selecting first and second confidence levels greater than others; , Including the method. twenty four. 18. The method according to claim 17, wherein the arbitrating step is performed in the For both the first and second confidence levels, the first and second And if the second confidence level is greater than the others, to form the patient's pulse rate , Linearly interpolating between the first and second pulse rates. twenty five. 18. The method according to claim 17, wherein at least one of the first confidence levels corresponds to the first confidence level. The two quality metrics are pulse signal shape, signal-to-noise ratio, and low electromagnetic energy. Selected from the group consisting of at least one wavelength correlation and arrhythmia potential That way. 26. 18. The method according to claim 17, wherein the electromagnetic energy has two wavelengths, At least one quality metric corresponding to one confidence level corresponds to two wavelengths Method, including the correlation between the data to be processed. 27. 18. The method according to claim 17, wherein at least one corresponds to a second confidence level. The quality metric of movement is the sign of movement and the movement detected over a time interval. The method wherein the pulse is selected from the group consisting of a fraction of the pulse duration. 28. 18. The method according to claim 17, wherein before the processing step, (a) taking the logarithm of the signal representing at least one waveform of electromagnetic energy, Generating the first signal by (b) subjecting the first signal to bandpass filtering, Generating a second signal; (c) standardizing the second signal, thereby generating data; Including   The tracking process takes the derivative of the data.