Source: https://patents.google.com/patent/JP5060186B2/en
Timestamp: 2019-10-14 13:38:29
Document Index: 287638187

Matched Legal Cases: ['art 107', 'art 108', 'art 109', 'art 110', 'art 101', 'art 102', 'art 103', 'art 104', 'art 105', 'art 106', 'art 107', 'art 108', 'art 109', 'art 110', 'art 111']

JP5060186B2 - Pulse wave processing apparatus and method - Google Patents
Pulse wave processing apparatus and method Download PDF
JP5060186B2
JP5060186B2 JP2007177173A JP2007177173A JP5060186B2 JP 5060186 B2 JP5060186 B2 JP 5060186B2 JP 2007177173 A JP2007177173 A JP 2007177173A JP 2007177173 A JP2007177173 A JP 2007177173A JP 5060186 B2 JP5060186 B2 JP 5060186B2
JP2007177173A
JP2009011585A (en
2007-07-05 Application filed by 株式会社東芝 filed Critical 株式会社東芝
2009-01-22 Publication of JP2009011585A publication Critical patent/JP2009011585A/en
2012-10-31 Publication of JP5060186B2 publication Critical patent/JP5060186B2/en
The present invention relates to a pulse wave processing apparatus and method for processing a pulse wave signal as data.
One of the biological indices that significantly reflects the state of the subject is heart rate (such as heart rate and autonomic nerve activity by frequency analysis of heart rate intervals). In order to directly measure the heartbeat, it is common to measure the electrocardiogram. For electrocardiogram measurement, it is necessary to directly apply electrodes to, for example, several places on the chest. The burden on the subject is large in order to continuously use the electrode in daily life. Therefore, pulse waves on fingers, wrists, earlobes, and the like are used as biological indices corresponding to heartbeats more easily. However, when measuring a pulse wave, there is a problem that the influence of the waveform disturbance on the body movement (body movement) is greater than when measuring the electrocardiogram. Therefore, a technique for removing the influence of body movement from the waveform of a pulse wave has been proposed (see, for example, Patent Documents 1 to 5).
Japanese Patent No. 2816944 JP 2001-61795 A JP 2002-17694 A JP 2005-95653 A JP 2005-160640 A
However, in the techniques disclosed in Patent Documents 1 to 5, basically, the body motion component is removed from the pulse wave signal in the predetermined section or the characteristics of the pulse wave signal and the body motion signal, and the average pulse in the section is calculated. The number is calculated. Such technology is suitable for exercise applications and the like, but there is a problem that it is difficult to remove body motion components when the body motion signal is in the same frequency band as the pulse wave signal. Moreover, it cannot be used for the purpose of extracting an interval for each beat of the pulse wave and performing autonomic nerve analysis based on frequency analysis of the fluctuation component.
On the other hand, there is a method for determining whether or not to use a pulse wave at the time of occurrence of the body motion for analysis depending on the size of the body motion. In this method, it is possible to determine the non-use of the pulse wave for each beat, but if a body movement exceeding a predetermined magnitude occurs, it is determined that all the pulse waves are not used. Therefore, there is a possibility of missing data that can be measured as a pulse wave. In order to perform an accurate autonomic nerve analysis, it is desirable to use the data as much as possible when it can be measured correctly as a pulse wave.
The present invention has been made in view of the above, and provides a pulse wave processing apparatus and method capable of selecting a pulse wave signal used as data according to the magnitude of the influence of waveform disturbance due to body movement. For the purpose.
In order to solve the above-described problems and achieve the object, the present invention is a pulse wave processing device comprising: pulse wave signal data representing a subject's pulse wave; and body motion signal data representing a subject's body motion. Acquisition means for acquiring; correlation coefficient calculating means for calculating a correlation coefficient representing a degree of correlation between the pulse wave signal data and the body motion signal data; and the correlation coefficient of the pulse wave signal data is predetermined. And a pulse wave removing means for removing the pulse wave signal data exceeding the threshold value.
The present invention is also a pulse wave processing method executed by a pulse wave processing apparatus including an acquisition unit, a correlation coefficient calculation unit, and a pulse wave removal unit, wherein the pulse wave of the subject is acquired by the acquisition unit. Obtaining pulse wave signal data representing body motion signal data representing body motion of the subject;
Calculating a correlation coefficient representing a degree of correlation between the pulse wave signal data and the body motion signal data by the correlation coefficient calculating means; and the pulse wave signal out of the pulse wave signal data by the pulse wave removing means. Removing pulse wave signal data having a correlation coefficient equal to or greater than a predetermined threshold;
According to the present invention, in order to determine the influence of the body motion on the pulse wave signal using the correlation between the pulse wave signal and the body motion signal, while removing the pulse wave signal greatly affected by the body motion, It is possible to employ a pulse wave signal that has a small influence even when body movement occurs.
Exemplary embodiments of a pulse wave processing apparatus and method according to the present invention will be explained below in detail with reference to the accompanying drawings.
(1) Configuration FIG. 1 is a block diagram showing a configuration of a pulse wave processing device 100 according to the present embodiment. As shown in the figure, the pulse wave processing device 100 includes a pulse wave measuring unit 101, a body motion measuring unit 102, a pulse wave interval detecting unit 103, a correlation coefficient calculating unit 106, and a pulse wave waveform removing unit 107. A display unit 108, a communication unit 109, and a recording unit 110.
FIG. 2 is a diagram illustrating the appearance and wearing state of the pulse wave processing device 100. In this example, the pulse wave processing device 100 is attached to the wrist like a wristwatch, the pulse wave measuring unit 101 is wound around the finger, and the pulse wave is measured at the finger pad.
FIG. 3 is a diagram schematically showing the configuration of the pulse wave measuring unit 101. The pulse wave measurement unit 101 is equipped with a photoelectric pulse wave pulse wave sensor constituted by a combination of a light emitting diode (LED) 111 and a photodiode 112. The pulse wave measurement unit 101 irradiates the skin with light from the LED 111, detects a change in intensity of reflected light (or may be transmitted light) due to a change in blood flow, and captures this as a pulse wave. Thereby, the pulse wave measuring unit 101 measures the pulse wave and outputs a pulse wave signal representing the pulse wave. As the color of the LED 111, blue, green, red, near-infrared, etc., which have good absorption characteristics of blood hemoglobin, are used, and a photodiode 112 having a characteristic suitable for the wavelength band of the LED 111 to be used may be selected. . FIG. 4 is a diagram illustrating a pulse wave processing device 100 in which the pulse wave measuring unit 101 is provided on the lower surface. FIG. 5 is a diagram showing an example in which the pulse wave processing device 100 shown in FIG. 4 is attached to the wrist like a wristwatch. In this example, the pulse wave is measured at the wrist. The pulse wave measurement unit 101 in this case may be configured by a photoelectric pulse wave sensor that is a combination of the LED 111 and the photodiode 112 shown in FIG. 3, or a pressure sensor that captures changes in arterial pulsation by pressure. Also good. FIG. 6 is a diagram illustrating a pulse wave processing device 100 having a shape that can be worn on the ear. In this example, the pulse wave measuring unit 101 is attached to the earlobe to measure the pulse wave. The pulse wave measurement unit 101 in this case may be configured by a photoelectric pulse wave sensor that is a combination of the LED 111 and the photodiode 112 shown in FIG.
Returning to FIG. 1, the pulse wave interval detection unit 103 detects the pulse interval by sampling the pulse wave signal output by the pulse wave measurement unit 101. Specifically, the pulse wave interval detection unit 103 includes a filter such as an FIR filter, LPF (low pass filter), HPF (high pass filter), and the like for noise components other than pulse waves (noise, baseline fluctuations, etc.). After performing signal processing such as removal and steepening of the pulse wave waveform, the pulse interval is detected.
The body motion measuring unit 102 includes a triaxial acceleration sensor that detects acceleration in the triaxial directions of the X, Y, and Z axes, for example. By attaching this three-axis acceleration sensor to a predetermined part of the human body, the body movement measuring unit 102 measures the acceleration in the three-axis direction as a body movement and outputs this as a body movement signal. The acceleration in each axial direction corresponds to a component signal. As a method of detecting acceleration by the acceleration sensor, there are a piezoresistive type, a piezoelectric type, a capacitance type, and the like, but any method may be used.
Detailed configurations of the pulse wave measurement unit 101, the pulse wave interval detection unit 103, and the body motion measurement unit 102 are disclosed in, for example, Japanese Patent Application Laid-Open No. 2001-344352.
The correlation coefficient calculation unit 106 determines a pulse wave use range used for calculating the correlation coefficient based on the pulse wave interval detected by the pulse wave interval detection unit 103, and represents a pulse wave within the use range. The correlation coefficient is calculated in time series using the wave signal and the body motion signal representing the body motion measured by the body motion measuring unit 102 at substantially the same time as the time when the pulse wave in the use range is measured. .
The pulse wave interval detection unit 103 and the correlation coefficient calculation unit 106 are hardware that is an acquisition unit for the pulse wave signal output from the pulse wave measurement unit 101 and the body motion signal output from the body motion measurement unit 102. As an input port (not shown).
The pulse wave waveform removal unit 107 removes pulse wave interval data (pulse wave interval data) when the correlation coefficient calculated by the correlation coefficient calculation unit 106 is equal to or greater than the first threshold, and the correlation coefficient is The pulse wave interval data when lower than 1 threshold is adopted.
The display unit 108 is a liquid crystal display (LCD) that can display the pulse wave interval data adopted by the pulse wave waveform removing unit 107 among the pulse wave interval data (pulse wave interval data) detected by the pulse wave interval detector 103. Consists of. FIG. 7 is a diagram illustrating an example in which the display unit 108 is provided on the upper surface of the pulse wave processing apparatus 100.
The recording unit 110 is a storage area for storing various measurement data measured by the pulse wave processing apparatus 100. For example, a flash memory, an EEPROM, or the like is used. The measurement data is, for example, a pulse wave signal, a body motion signal, pulse wave interval data, or the like.
The communication unit 109 transfers measurement data to an external terminal by wireless (electromagnetic wave or optical) communication such as Bluetooth or infrared communication, or wired communication such as USB or RS-232C. The communication unit 109 may transfer the measurement data every time it is measured, or may collectively transfer the measurement data accumulated in the recording unit 110.
(2) Operation Next, the operation of the pulse wave processing device 100 in the embodiment of the present invention will be described. FIG. 8 is a flowchart showing the procedure of the pulse wave measurement process performed by the pulse wave processing apparatus 100. For example, a case where the pulse wave processing device 100 is worn on the wrist as shown in FIGS. 3 and 5 will be described. First, when the subject operates the power switch and the measurement start button (none of which are shown) of the pulse wave processing device 100 to instruct the start of pulse wave measurement (step S10), the pulse wave measurement unit 101 is predetermined. The pulse wave is measured at the sampling period (step S11). The sampling period is, for example, 50 ms. Then, the pulse wave interval detection unit 103 performs a pulse wave interval detection process using the pulse wave signal measured by the pulse wave measurement unit 101 (step S12).
FIG. 9 is a flowchart showing a procedure of pulse wave interval detection processing performed by the pulse wave interval detector 103. First, the pulse wave interval detection unit 103 appropriately performs digital filter processing using an FIR filter or the like according to the filter characteristics depending on the hardware configuration of the pulse wave measurement unit 101, and LPF (low pass filter) or HPF as necessary. Either or both of the filters (high-pass filter) are used to remove noise components other than the pulse wave (noise, baseline fluctuations, etc.) and sharpen the pulse wave waveform (step S30). Next, the pulse wave interval detection unit 103 updates the maximum value and the minimum value of the pulse wave waveform for a certain period of time (for example, 1.5 s) from the current sampling (step S31), and crosses the pulse wave waveform ( A second threshold value (for example, the midpoint between the maximum value and the minimum value) used for detecting the threshold value cross) is determined (step S32). The second threshold value may be set according to the measurement system because the waveform characteristics (shape, polarity, etc.) differ depending on the measurement system. Moreover, it becomes easy to follow the change of a pulse wave amplitude dynamically by performing such a process.
Next, the pulse wave interval detector 103 determines whether or not the set second threshold has been crossed (in a predetermined direction), and the first crossed sampling time is set as the pulse wave interval detection timing ( Step S33). Here, since the threshold crossing occurs between samplings, an error occurs between the sampling timing and the actual threshold crossing timing. Therefore, it is conceivable to perform an approximation process on the threshold cross to reduce the influence of the error. FIG. 10 is a diagram illustrating an approximation process for a threshold value cross. In the approximation process shown in the figure, it is assumed that the pulse wave waveform between samplings (between P0 and P1) is a straight line, and the threshold value cross Pc is estimated using the ratio of amplitudes before and after the second threshold value (Th). . In the figure,
T = T1 × (P0−Th) / (P0−P1)
It becomes. The threshold cross Pc is calculated using this T. The pulse wave interval is detected in this way, but there are cases where there is noise or the pulse wave signal cannot be measured correctly. For this reason, the pulse wave interval detection unit 103 determines whether or not the detected pulse wave interval is within a presumed pulse rate range (for example, a pulse rate of 40 bpm to 120 bpm, that is, a pulse wave interval of 0.5 s to 1.5 s). Is determined (step S34). Then, when the detected pulse wave interval is outside the range (step S34: NO), the pulse wave interval detection unit 103 does not detect the pulse wave interval, and the detected pulse wave interval is within the range. If it is within (step S34: YES), it is assumed that the pulse wave interval has been detected.
On the other hand, in step S13 of FIG. 8, the body movement measuring unit 102 measures the body movement of the subject. Here, since the body motion measuring unit 102 has a triaxial acceleration sensor, the body motion measuring unit 102 measures the acceleration in the triaxial direction and outputs this as a body motion signal. In the present embodiment, the magnitude of the influence on the pulse wave waveform given along with the posture and motion of the subject is measured by the acceleration in each axial direction. Then, the process proceeds to step S15.
In step S15, the correlation coefficient calculation unit 106 determines whether or not the pulse wave interval detection unit 103 has detected a pulse wave interval as a result of the above-described pulse wave interval detection processing, and when the determination result is affirmative, Proceeding to step S16, if the determination result is negative, the process returns to step S10.
In step S <b> 16, the correlation coefficient calculation unit 106 determines the use range of the pulse wave signal used for calculating the correlation coefficient. The use range is a range that sufficiently includes one pulse wave interval at that time point detected by the pulse wave interval detection unit 103 by performing the pulse wave interval detection process in step S12 described above. For example, it is about 1.5 times the pulse wave interval. FIG. 11 is a diagram exemplifying a use range of a pulse wave signal used for calculating a correlation coefficient. When the pulse wave interval detection unit 103 detects the pulse wave interval based on the second threshold (Th), the latest pulse wave interval (Tm) is detected from the latest detection trigger point (threshold cross) 130 each time a pulse is detected. ) 1.5 times (1.5 Tm), the range returned to the past is used as the range for calculating the correlation coefficient. Correlation coefficient calculation section 106 determines a new use range by adjusting the use range according to the above-described procedure every time a pulse wave interval is detected.
Next, in step S <b> 17, the correlation coefficient calculation unit 106 determines the priority order used for calculating the correlation coefficient with respect to the triaxial acceleration output from the body movement measurement unit 102 as the body movement signal. This processing is performed because the axial direction of the acceleration that affects the pulse wave waveform varies depending on the posture and movement of the subject. For example, the axial direction that affects the pulse wave waveform differs between the acceleration measured when the subject normally walks with his / her hand walking and the acceleration measured when walking while holding an object. The impact of the ground contact of the sole during walking is large, and the correlation with the acceleration change waveform in the direction of gravitational acceleration (the vertical direction on the ground) detected by the three-axis acceleration sensor is high. For this reason, the correlation coefficient calculation unit 106 compares the direct current components in the respective axial directions of the acceleration measured by the body motion measurement unit 102 having the three-axis acceleration sensor, and in order closer to ± 1 G which is the gravitational acceleration, Determine priority. For example, in FIG. 14, the acceleration in the Y-axis direction is the first priority, the acceleration in the Z-axis direction is the second priority, and the acceleration in the X-axis direction is the third priority. The correlation coefficient calculation unit 106 first measures the body wave measurement unit 102 at approximately the same time as the pulse wave signal in the use range determined in step S16 and the time when the pulse wave in the use range is measured. A correlation coefficient with the acceleration in the axial direction (here, the Y-axis direction) with the highest priority among the accelerations is calculated (step S18). As a method for calculating the correlation coefficient, for example, an FFT (Fast Fourier Transform) method, a convolution integral method (Convolution), or the like may be used.
Then, the correlation coefficient calculation unit 106 determines whether or not the calculated correlation coefficient is greater than or equal to a predetermined first threshold (step S19). If the determination result is affirmative, the pulse wave waveform removal unit 107 removes the pulse wave interval data detected in step S12 (step S22), and proceeds to steps S23 to S25. If the determination result in step S19 is negative, it is determined whether or not the next priority is third or lower (step S20). If the determination result is affirmative, the use range determined in step S16 is determined. The correlation coefficient between the pulse wave signal and the acceleration in the axial direction having the next highest priority among the accelerations measured by the body motion measuring unit 102 at substantially the same time as the time when the pulse wave in the use range is measured. Calculate (step S21). If the determination result in step S20 is negative, the pulse wave interval data detected in step S12 is not removed, and the process proceeds to steps S23 to S25.
Here, a description will be given with reference to an example of a pulse wave waveform shown in the figure. FIG. 12 is a diagram illustrating a pulse wave waveform at rest. FIG. 13 is a diagram illustrating the pulse waveform and the acceleration waveforms in the three-axis directions when walking with the file held in front of the chest. The vertical direction of the ground is the Y axis. FIG. 14 is a diagram showing correlation coefficients between the pulse wave waveform and the acceleration waveforms in the three-axis directions. Comparing the pulse waveform shown in FIG. 12 with the pulse waveform shown in FIG. 13, it can be seen that the waveforms are similar. For this reason, in the prior art, the pulse waveform shown in FIG. 13 may also be detected as representing the original pulse waveform of the subject. However, referring to the correlation coefficient shown in FIG. 14, it can be seen that the correlation between the pulse waveform and the acceleration waveform in the Y-axis direction in the vertical direction on the ground is maintained high. From this, it can be seen that the pulse waveform shown in FIG. 13 does not represent the waveform of the subject's original pulse wave, but is a waveform affected by the subject's body movement (in this case, walking). Referring to FIG. 14, in this example, if the first threshold is set to about “0.6” in advance, the pulse wave waveform that is greatly influenced by the body movement of the subject as a result of the determination in step S <b> 11 described above. Corresponding pulse wave interval data can be removed by the pulse wave waveform removing unit 107.
In this way, the original waveform of the pulse wave and the waveform that is greatly influenced by body movement are distinguished and used as pulse wave interval data corresponding to the former waveform. Then, the display unit 108 displays the adopted pulse wave interval data each time (step S23), the communication unit 109 transmits it to the external information terminal each time (step S24), and the recording unit 110 temporarily stores the data. (Step S25). Further, the pulse wave interval data stored and accumulated by the recording unit 110 may be collectively transferred to the external information terminal by the communication unit 109. When the measurement ends (step S26: YES), the process ends.
According to the configuration as described above, since it is determined whether the pulse wave signal is affected by the body movement using the correlation between the pulse wave signal and the body movement signal, the pulse wave signal is greatly influenced by the body movement. While removing the pulse wave signal that cannot correctly detect the wave interval, it is possible to employ the pulse wave signal that can correctly detect the pulse wave interval as much as possible. Then, by removing the pulse wave interval data that is greatly affected by the body motion and employing the correctly detected pulse wave interval data, it is possible to perform various biological analyzes with high accuracy. Further, since it is determined for each beat whether the pulse wave signal is affected by body movement, it is suitable for applications such as biological analysis using the pulse wave interval for each beat.
Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.
In the above-described embodiment, when a triaxial acceleration sensor is used as the body motion measurement unit 102, the correlation coefficient calculation unit 106 calculates the correlation coefficient for each axis direction of acceleration in step S17 of FIG. The priority order used for the calculation was determined, and the correlation coefficient was calculated using the axial acceleration up to the third priority order unless the determination result in step S19 was positive. However, steps S20 to S21 may not be performed, and a correlation coefficient for the acceleration in the axial direction with the first priority may be calculated. The number of relationships may be calculated.
Further, a body motion measuring unit 102 other than the triaxial acceleration sensor may be used. As a method of measuring body motion, it can capture body movements such as a method of detecting the movement of a metal sphere due to body movement at multiple points of contact and a method of detecting by attaching strain gauges to joints etc. What is necessary is just to use. The body motion measuring unit 102 may be configured using a plurality of various sensors. In such a configuration, the correlation coefficient calculating unit 106 determines priorities for a plurality of types of data detected by one sensor and data detected by a plurality of sensors, and in order of the data with the highest priority. You may make it use for calculation of a correlation coefficient.
In the above-described embodiment, the pulse wave processing device 100 may be configured to include the posture estimation unit. FIG. 15 is a block diagram illustrating the configuration of the pulse wave processing device 100 according to this variation. The posture estimation unit 104 shown in the figure inputs the body motion signal output from the body motion measurement unit 102 via an input port (not shown), and estimates the subject's posture using this body motion signal. . Specifically, for example, when the posture estimation unit 104 obtains an acceleration waveform as the body motion signal output from the body motion measurement unit 102, the posture estimation unit 104 estimates the posture of the subject based on the DC component obtained through the low-pass filter. The estimated posture is, for example, a supine position, a standing position, or a sitting position. Corresponding to the posture of the subject, the priority in the axial direction of the acceleration for which the correlation coefficient with the pulse wave interval data is to be calculated is determined in advance and stored in advance in the recording unit 110 or a memory (not shown).
FIG. 16 is a diagram illustrating a procedure of pulse wave measurement processing according to the present modification. In this modification, after step S13 described in the above-described embodiment, the posture estimation unit 104 estimates the posture of the subject in step S14. In step S17 ′, the correlation coefficient calculation unit 106 detects the body motion measurement unit 102 at substantially the same time as the pulse wave signal in the use range determined in step S16 and the pulse wave in the use range are measured. The correlation coefficient is calculated using the acceleration data in the axial direction with the first priority stored in the memory corresponding to the posture of the subject estimated by the posture estimation unit 104 among the accelerations measured by the above.
According to such a configuration, it is possible to more appropriately remove the pulse wave interval data according to the posture that greatly affects the pulse wave waveform.
Note that the posture data representing the posture estimated by the posture estimation unit 104 may be displayed on the display unit 108, transmitted to the external information terminal by the communication unit 109, or stored in the recording unit 110.
In this modification, the posture estimation unit 104 is provided separately from the correlation coefficient calculation unit 106, but the posture estimation unit 104 may be included in the correlation coefficient calculation unit 106.
In the above-described embodiment, the pulse wave processing device 100 may be configured to include the motion estimation unit. FIG. 17 is a block diagram illustrating the configuration of the pulse wave processing device 100 according to this variation. The motion estimation unit 105 shown in the figure estimates the motion of the subject using the body motion signal output from the body motion measurement unit 102. Specifically, for example, when the motion estimation unit 105 obtains an acceleration waveform as the body motion signal output from the body motion measurement unit 102, based on the frequency component and fluctuation pattern of the AC component obtained through the low-pass filter, Estimate the behavior. The estimated motion is, for example, walking (normal walking, walking with an object), stairs up / down, traveling, bicycle traveling, car ride, train ride, and the like. Corresponding to the movement of the subject, the priority in the axial direction of the acceleration for which the correlation coefficient with the pulse wave signal is to be calculated is determined in advance and stored in advance in the recording unit 110 or a memory (not shown).
The configuration of the motion estimation unit 105 is disclosed in, for example, Japanese Patent Application Laid-Open No. 2001-344352. In addition, when the body motion measurement unit 102 is worn on the wrist, the motion estimation unit 105 may be configured using the techniques described in the following documents.
Literature: Makoto Sato, Chie Morita, Miwako Doi: Behavior recognition using biometric data and acceleration data, Information Processing Society of Japan 65th National Conference 3T5B-2, pp239-242, (2003.3)
The procedure of the pulse wave measurement process according to this modification is substantially the same as that shown in FIG. In this modification, after step S13 described in the above-described embodiment, the motion estimation unit 105 estimates the motion of the subject in step S14. In step S17 ′, the correlation coefficient calculation unit 106 detects the body motion measurement unit 102 at substantially the same time as the pulse wave signal in the use range determined in step S16 and the pulse wave in the use range are measured. The correlation coefficient is calculated using the acceleration data in the axial direction with the first priority stored in the memory corresponding to the motion of the subject estimated by the motion estimation unit 105 among the accelerations measured by the above.
According to such a configuration, it is possible to more appropriately remove the pulse wave interval data in accordance with an operation that greatly affects the pulse wave waveform.
Note that the operation data representing the motion estimated by the motion estimation unit 105 may be displayed on the display unit 108, transmitted to the external information terminal from the communication unit 109, or stored in the recording unit 110.
In this modification, the motion estimation unit 105 is provided separately from the correlation coefficient calculation unit 106, but the motion estimation unit 105 may be included in the correlation coefficient calculation unit 106.
In the above-described embodiment, the pulse wave processing device 100 includes the pulse wave interval detection unit 103, and the pulse wave waveform removal unit 107 appropriately removes the pulse wave interval data based on the correlation coefficient. However, the pulse wave processing device 100 does not include the pulse wave interval detection unit 103, and the pulse wave waveform removal unit 107 appropriately removes the pulse wave signal itself output from the pulse wave measurement unit 101 based on the correlation coefficient, for example. You may do it.
In the above-described embodiment, the pulse wave processing device 100 is configured to include the display unit 108, the communication unit 109, and the recording unit 110 as output means. The structure provided with at least one may be sufficient. In the configuration in which the pulse wave processing device 100 includes the display unit 108 and the communication unit 109, the communication unit 109 may not immediately transfer the pulse wave interval data to the external information terminal.
In the above-described embodiment, the pulse wave processing device 100 includes conversion means for converting the pulse rate using the pulse wave interval data, and the pulse wave waveform of the pulse wave interval data detected by the pulse wave interval detection unit 103 is included. You may comprise so that the pulse rate which the said conversion means converted the pulse wave interval data which the removal part 107 employ | adopted may be output to at least one of the display part 108, the communication part 109, and the recording part 110. FIG.
In the above-described embodiment, the pulse wave processing device 100 includes the pulse wave measurement unit 101 and the body motion measurement unit 102, and is configured to also serve as the pulse wave measurement device. However, the pulse wave processing device 100 may be configured not to include these units and to acquire the pulse wave signal and the body motion signal using an external device. FIG. 18 is a block diagram illustrating the configuration of the pulse wave processing device 100 according to the present modification and the configuration of the pulse wave measuring device 120 that is an external device. The pulse wave measurement device 120 includes a pulse wave measurement unit 101 ′, a body motion measurement unit 102 ′, and a communication unit 121 configured by a network interface or the like. The configurations of the pulse wave measurement unit 101 ′ and the body motion measurement unit 102 ′ are substantially the same as the configurations of the pulse wave measurement unit 101 and the body motion measurement unit 102, respectively. The pulse wave measuring device 120 transmits the pulse wave signal output from the pulse wave measuring unit 101 ′ and the body motion signal output from the body motion measuring unit 106 ′ to the pulse wave processing device 100 via the communication unit 121. The pulse wave processing device 100 receives a pulse wave signal and a body motion signal from the pulse wave measuring device 120 via the communication unit 109. The pulse wave processing apparatus 100 detects a pulse wave interval using the received pulse wave signal, and calculates a correlation coefficient using the received pulse wave signal and body motion signal in the same manner as in the above-described embodiment. Then, based on the correlation coefficient, the pulse wave interval data corresponding to the pulse wave signal in which the influence of the body motion is acting is removed.
Further, in such a configuration, the pulse wave processing device 100 may be configured to further include at least one of the posture estimation unit 104 and the motion estimation unit 105 described in the second and third modifications.
It is a block diagram which shows the structure of the pulse wave processing apparatus 100 concerning embodiment of this invention. It is a figure which illustrates the appearance and wearing state of pulse wave processing device. 2 is a diagram schematically showing a configuration of a pulse wave measurement unit 101. FIG. It is a figure which illustrates the pulse wave processing apparatus 100 which provided the pulse wave measurement part 101 in the lower surface. FIG. 5 is a diagram showing an example in which the pulse wave processing device 100 shown in FIG. 4 is attached to a wrist like a wristwatch. It is a figure which illustrates pulse wave processing device 100 made into the shape which can be worn on an ear. FIG. 3 is a diagram showing an example in which a display unit is provided on the upper surface of the pulse wave processing apparatus. It is a flowchart which shows the procedure of the pulse wave measurement process which the pulse wave processing apparatus 100 performs. It is a flowchart which shows the procedure of a pulse-wave space | interval detection process. It is a figure which illustrates the approximation process with respect to threshold value crossing. It is a figure which illustrates the use range of the pulse wave signal used for calculation of a correlation coefficient. It is a figure which illustrates the pulse wave waveform at the time of rest. It is a figure which illustrates the pulse wave waveform at the time of walking while holding a file in front of a chest, and each acceleration waveform of a triaxial direction. It is a figure which shows each the correlation coefficient of a pulse wave waveform and each acceleration waveform of a triaxial direction. It is a block diagram which illustrates the composition of pulse wave processing device 100 concerning one modification. It is a figure which shows the procedure of a pulse wave measurement process. It is a block diagram which illustrates the composition of pulse wave processing device 100 concerning one modification. It is a block diagram which illustrates the composition of pulse wave processing device 100 concerning one modification, and the composition of pulse wave measuring device 120 which is an external device.
DESCRIPTION OF SYMBOLS 100 Pulse wave processing apparatus 101 Pulse wave measurement part 102 Body motion measurement part 103 Pulse wave interval detection part 104 Posture estimation part 105 Motion estimation part 106 Correlation coefficient calculation part 107 Pulse wave waveform removal part 108 Display part 109 Communication part 110 Recording part 111 LED
112 Photodiode 120 Pulse wave measuring device 121 Communication unit
An acquisition means for acquiring pulse wave signal data representing a subject's pulse wave and body motion signal data representing a subject's body movement;
Correlation coefficient calculating means for calculating a correlation coefficient representing the degree of correlation between the pulse wave signal data and the body motion signal data;
A pulse wave processing apparatus, comprising: pulse wave removing means for removing the pulse wave signal data in which the correlation coefficient is equal to or greater than a predetermined threshold from the pulse wave signal data.
Pulse wave interval detection means for detecting first pulse wave interval data for each beat using a pulse wave waveform represented by the pulse wave signal data;
The pulse wave removing means calculates third pulse wave interval data obtained by removing second pulse wave interval data representing a pulse wave interval when the correlation coefficient is equal to or greater than a predetermined threshold value from the first pulse wave interval data. The pulse wave processing device according to claim 1, wherein:
The pulse wave processing apparatus according to claim 1, wherein the correlation coefficient calculating unit calculates the correlation coefficient at a timing when the pulse wave interval for each beat is detected.
The correlation coefficient calculation means determines a use range of the pulse wave signal used for calculation of the correlation coefficient based on the first pulse wave interval data, and uses the pulse wave signal in the use range The pulse wave processing device according to claim 1, wherein the correlation coefficient is calculated.
The body motion signal data includes a plurality of signal data,
The correlation coefficient calculating means determines a priority for at least one of the signal data, and indicates a degree of correlation between the pulse data and the signal data having the highest priority. 5. The pulse wave processing device according to claim 1, wherein the number of relations is calculated.
Further comprising posture estimation means for estimating the posture of the subject based on the body motion signal;
The correlation coefficient calculating means determines the order of the signal data having a high degree of correlation with the estimated posture of the subject as the priority, and the signal data having the highest priority and the pulse wave signal data 5. The pulse wave processing device according to claim 1, wherein a correlation coefficient representing a degree of correlation is calculated.
The body motion signal includes a plurality of signal data,
Further comprising motion estimation means for estimating the motion of the subject based on the body motion signal;
The correlation coefficient calculating means determines the order of the signal data having a high degree of correlation with the estimated motion of the subject as the priority order, and the signal data having the highest priority order and the pulse wave signal data, 5. The pulse wave processing device according to claim 1, wherein a correlation coefficient representing a degree of correlation is calculated.
The pulse according to any one of claims 1 to 7, further comprising output means for outputting at least one of the pulse wave signal data and body motion signal data, or the third pulse wave interval data. Wave processing device.
The pulse wave processing device according to claim 8, further comprising output means for outputting posture data representing the estimated posture.
The pulse wave processing device according to claim 8 or 9, further comprising output means for outputting motion data representing the estimated motion.
It further comprises pulse wave measuring means for measuring the pulse wave of the subject and outputting pulse wave signal data representing the pulse wave,
The pulse wave processing device according to claim 1, wherein the acquisition unit acquires pulse wave signal data output from the pulse wave measurement unit.
Body movement measuring means for measuring the body movement of the subject and outputting body movement signal data representing the body movement;
The pulse wave processing device according to claim 1, wherein the acquisition unit acquires the body motion signal data output from the body motion measurement unit.
The body motion measuring means has a triaxial acceleration sensor, measures accelerations in three orthogonal directions, and outputs a signal including acceleration data in each axial direction as signal data as the body motion signal data. The pulse wave processing device according to claim 12.
A pulse wave processing method executed by a pulse wave processing apparatus including an acquisition unit, a correlation coefficient calculation unit, and a pulse wave removal unit,
Obtaining pulse wave signal data representing a subject's pulse wave and body motion signal data representing a subject's body movement by the obtaining means;
Calculating a correlation coefficient representing a degree of correlation between the pulse wave signal data and the body motion signal data by the correlation coefficient calculating means;
Removing the pulse wave signal data in which the correlation coefficient is equal to or greater than a predetermined threshold from the pulse wave signal data by the pulse wave removing unit;
A pulse wave processing method comprising:
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