JP2002282224A - Biological information measurement device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a simple-structured device for measuring the heartbeat and respiration of a bathing person while taking a bath. SOLUTION: The biological information measurement device 1 comprises a water pressure measurement means 2 for measuring the water pressure in a bathtub by converting the water pressure into electric information, and an operation means 3 for extracting the frequency component corresponding to the heartbeat of the bathing person based on the temporal variation of the electric information and deducing the heartbeat from the frequency component corresponding to the heartbeat of the bathing person as the bathing person's biological information.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for measuring biological information such as heart rate and respiration in a bathtub.

[0002]

2. Description of the Related Art Devices for monitoring the heartbeat and breathing of a bather taking a bath have been proposed. For example, Patent 2
In the “bathing apparatus using a heart function measurement bathtub” described in Japanese Patent No. 594217 (hereinafter, referred to as a first conventional example), a bathtub electrocardiograph is used to measure an electrocardiogram and a heart rate of a bather.
Measuring bather breathing using a water level sensor is described. In addition, “Water surface fluctuation measurement apparatus and method” described in JP-A-2000-3000528 (hereinafter, referred to as “
In the second conventional example, the water surface of a bathtub irradiated with a laser beam is photographed by a video camera and image-processed to detect the fluctuation frequency of the water surface, and the respiration rate and heart rate of the bather are detected from the fluctuation frequency. Calculating a number is described.

[0003]

However, in the first prior art, separate measuring devices are required for heart rate measurement and respiration measurement, and the configuration of the device is complicated to measure both at the same time. There is a problem. Further, in order to analyze the measured heartbeat and respiration in relation to each other, a further additional signal processing device is required, which further complicates the overall device configuration.

Further, in the second conventional example, it is necessary to use a combination of a plurality of measuring instruments in the same manner as in the first conventional example. Further, the second conventional example has a high processing capability for processing an image photographed by a video device. There is also a problem that an image processing device is required.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a device capable of measuring the heart rate and breathing of a bather with a simple device configuration.

[0006]

A first characteristic configuration of a biological information measuring apparatus according to the present invention for solving the above-mentioned problems is as follows.
Water pressure measuring means for converting the water pressure in the bathtub into an electric signal for measurement as described in claim 1 of the Claims section, and a frequency corresponding to the heartbeat of the bather from a temporal change of the electric signal. Computing means for extracting a component and deriving heart rate information from the frequency component corresponding to the heart rate as biological information of the bather. Here, the heart rate information is
Information such as the heartbeat interval and the heart rate per unit time.

[0007] A second characteristic configuration of the biological information measuring device according to the present invention for solving the above-described problem is, in addition to the first characteristic configuration, as described in claim 2 of the claims. The arithmetic means further extracts a frequency component corresponding to a bather's breath from the temporal change of the electric signal, and derives breathing information as the bather's biological information from the frequency component extracted by the arithmetic means. Is to do. Here, the respiration information is information such as a respiration interval and a respiration rate per unit time.

[0008] A third characteristic configuration of the biological information measuring device according to the present invention for solving the above-mentioned problem is the first or second characteristic configuration as described in claim 3 of the claims. In addition to the above, there is provided a determining means for determining a physical condition of the bather based on the derived biological information.

A fourth characteristic configuration of the biological information measuring device according to the present invention for solving the above-mentioned problem is, in addition to the third characteristic configuration, as described in claim 4 of the claims. And a warning means for issuing a warning based on the determination result by the determination means.

[0010] A fifth characteristic configuration of the biological information measuring device according to the present invention for solving the above-mentioned problems is as described in claim 5 of the claims. In addition to the characteristic configuration described above, the water pressure measuring means is a water level sensor for hot water supply control provided in a predetermined location of the bathtub in advance.

The operation and effect will be described below. According to the first characteristic configuration of the biological information measuring device according to the present invention, the water pressure measuring means converts the water pressure in the bathtub into an electric signal to measure the water pressure, and the arithmetic means detects the bathing from the temporal change of the electric signal. A frequency component corresponding to the heartbeat of the user is extracted, and heartbeat information can be derived from the frequency component corresponding to the heartbeat as the biological information of the bather. Therefore, since the heart rate information such as the timing of the heart rate can be measured by the water pressure measuring means without using a special device such as a bathtub electrocardiographic measuring device, a simple configuration of the biological information measuring device is provided. be able to.

According to a second characteristic configuration of the biological information measuring apparatus according to the present invention, the calculating means extracts a frequency component corresponding to a bather's breath from a temporal change of the electric signal, and extracts the extracted frequency component. Respiration information can be derived from the frequency component as the above-mentioned bather's biological information. Therefore, without using a special device such as a bathtub electrocardiographic measuring device, a laser device, and a video camera, which were conventionally used to measure heartbeat information and respiratory information such as the timing of heartbeat and the timing of breathing, The heartbeat timing and the respiration timing can be measured simultaneously by a simple device configuration using the water pressure measurement means.

According to the third characteristic configuration of the biological information measuring device according to the present invention, the determination means determines the physical condition of the bather based on the derived biological information, so that the bather can relax. It is possible to determine whether or not the bather is physically tired or not. For example, by examining the numerical values of the respiration rate and the heart rate, it is possible to determine whether or not a physical load is applied to the bather. In addition, if the peak on the high frequency side seen in the power spectrum due to the time-varying frequency component of the heartbeat interval is large, the subject (bathing person) can be determined to be relaxed. It can be determined that it has not been done.

According to the fourth characteristic configuration of the biological information measuring device according to the present invention, a warning is issued based on the determination result by the determining means, thereby preventing a bather from falling into a dangerous state, or It can notify the outside that there is a dangerous state. For example, if the breathing interval or heartbeat interval changes suddenly, it is determined that the bather has modulated his / her physical condition, and an alarm is issued, whereby the bather's abnormality is quickly communicated to cohabitants and the like. You. In addition, when the heart rate is measured but the respiration is not measured, it is possible to determine that the bather is submerged, the breathing is stopped, and only the heart is moving. The alarm can be issued according to.

According to the fifth characteristic configuration of the biological information measuring device according to the present invention, since the water level sensor for controlling hot water supply is provided in a normal bathtub in advance, it is necessary to realize the function of the water pressure measuring means. There is no need to provide a new water level sensor.
Therefore, there is an advantage that the biological information measuring device can be configured using an existing device.

[0016]

FIG. 1 is a schematic view of a biological information measuring apparatus 1 according to the present invention. The biological information measuring device 1 extracts and extracts a water level sensor (water pressure measuring means) 2 for measuring a fluctuation of a water level of a bathtub by a fluctuation of an electric signal due to a water pressure, and a frequency component corresponding to heartbeat and respiration from the electric signal. A calculating means 3 for deriving characteristics of heartbeat and respiration as biological information from frequency components.

The calculating means 3 and the judging means 4 as described above.
Can be realized by using a microcomputer built in the bathroom remote control that is installed in the bathroom and adjusts the amount of hot water and the temperature of the hot water.However, another computer is newly installed and the above-mentioned computer is installed in the computer. Functions may be realized.

Further, the water level sensor 2 can be realized by a pressure sensor generally provided in the middle of a hot water supply pipe of a bathtub for controlling hot water supply. As described above, by using the existing device, the cost and labor for configuring the biological information measuring device 1 can be reduced.

FIG. 2 shows that breathing is performed once every two seconds (0.5 H
z) shows the measurement results of the fluctuation frequency of the water surface of the bathtub measured when the measurement was performed. This fluctuation frequency is the fluctuation frequency of the electric signal strength output from the water level sensor 2 that outputs the fluctuation of the water level as the electric signal strength. A peak having a small frequency and a peak having a large frequency are measured, and the small peak (frequency: about 0.5 Hz) is obtained by detecting the water level fluctuation caused by the breathing of the bather as described above, and the large peak (frequency: : About 1.5 Hz) is a detection of a water level fluctuation caused by a heartbeat of a bather. Therefore, the respiratory rate and heart rate per unit time (hereinafter simply referred to as respiratory rate and heart rate) can be derived from the respective peak frequencies corresponding to respiration and heart rate. In this case, the fluctuation of the water level was measured when breathing was performed once every 2 seconds, but even if breathing was performed normally without being conscious, peaks corresponding to breathing and heartbeat also appeared. Respiratory rate and heart rate can be derived.

Next, a method for obtaining the degree of fatigue and the degree of relaxation from the heart rate will be described. Using the water level sensor 2, the fluctuation frequency of the water surface is measured at regular intervals,
A heartbeat interval length that can be derived from a heart rate at a predetermined time is continuously obtained in time, and a fast Fourier transform is performed on the time-series data of the heartbeat interval length at a predetermined period in which a part of the data overlaps with each other. An example of a power spectrum obtained by the application is shown. Generally, the heartbeat interval is not constant, but fluctuates as the interval becomes shorter or longer, and the fluctuation appears as a peak of the power spectrum. As can be seen from the power spectrum of FIG. 3, two large peaks mainly appear, a low frequency peak is an LF (Low Frequency) peak, and a high frequency side is an HF (High Frequency) peak.
ency) peak. Physiologically, it is considered that HF indicates the function of parasympathetic nerve, and LF indicates the function of parasympathetic nerve and sympathetic nerve.

As shown in FIG. 1, the biological information measuring device 1
Further includes a determination unit 4 for determining the physical condition of the bather based on the biological information derived by the calculation unit 3.
Therefore, when examining the magnitudes of the peaks of LF and HF shown in FIG. 3, for example, if HF appears large, it indicates that the parasympathetic nerve is activated. It can be determined that the degree of relaxation is high.

Next, attention is paid to respiration. In FIG. 2, the frequency peak of respiration was measured at 0.5 (Hz) to show the electric signal strength measured when the respiration interval was controlled.
In an actual measurement, the frequency peak shifts according to the respiratory rate. Therefore, it is possible to determine that the degree of fatigue is small when the measured respiratory rate is small, and that the degree of fatigue is high when the measured respiratory rate is large. Also, rather than simply looking at the respiratory rate, the past respiratory rate data of the bather (normal value for the bather) stored in the determination means 4 is compared with the actually measured value. It can also be determined that the physical condition is poor when the number is large and that the physical condition is good when the number is smaller than the normal value. In addition, if the determination means 4 simultaneously stores past heart rate data, the physical condition of the bather can be similarly determined from the heart rate.

Another advantage is that heart rate and respiration are measured simultaneously. For example, when the bather drowns, the heartbeat may be measured for a while after stopping the breathing. However, if the breathing does not appear in the measurement result and only the heartbeat appears in the measurement result, the determination means 4 takes a bath. Person can be determined to be in a drowning state as described above.

As described above, when the determination means 4 determines that there is a modulation in the physical condition of the bather, or when a heart rate or respiratory rate exceeding a preset threshold for the heart rate or respiratory rate is measured. Alternatively, the determination means 4 may instruct the alarm means 5 to issue an alarm. When the alarm means 5 used here is realized by an acoustic device such as a buzzer installed in the bathroom, a device outside the bathroom (alarm means 5a) using a wired or wireless communication means.
, And a warning may be transmitted to the cohabitants. In the latter case, as a device outside the bathroom (alarm means 5a), a kitchen remote control used for adjusting the hot water temperature of the water heater in the kitchen, a normal sound device (buzzer, audio device, etc.), There are lighting devices such as lamps, and alarms are transmitted by character information, audio information, and optical information (flashing of lamps, etc.).

In addition, even when the measured heart rate or respiratory rate does not exceed the above-mentioned threshold value, the breathing or heart rate suddenly becomes faster or slower during bathing. In this case, the determination means 4 can determine that there has been any modulation in the physical condition of the bather, and can give an instruction to issue an alarm to the alarm means 5 based on the determination result in the same manner as described above. it can.

In the above-described embodiment, a case has been described in which a pressure sensor provided in advance in a hot water supply pipe is used as the water level sensor 2. However, the water level sensor 2 may be provided later. For example, a water level sensor 2 can be newly provided on a drain plug provided at the bottom of a bathtub or the like. in this case,
Electrical continuity between the water level sensor 2 and the calculating means 3 can be performed using a chain normally connected to pull out a drain plug. However, the chain must be insulated from the bath water.

In the above-described embodiment, the heart rate and respiration rate of a bather are measured and analyzed to estimate the degree of relaxation and fatigue. By examining how the power spectrum of a bather changes when environmental music, fragrance, etc. are changed, what decoration, environmental music, fragrance, etc., as a result, will relax the bather You can know. Therefore, it is also possible to actively adjust the decoration, environmental music, aroma, and the like in the bathroom based on the measured biological information, and change the configuration to provide a bathroom in which the bather can relax more. .

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a biological information measuring device.

FIG. 2 is a graph showing a fluctuation frequency of a water surface.

FIG. 3 is a graph showing a power spectrum of a frequency component corresponding to a heartbeat.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Biological information measuring device 2 Water level sensor (water pressure measuring means) 3 Calculation means 4 Judgment means 5 Alarm means

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Tomoaki Ueda 17 Kantoji Minamicho, Shimogyo-ku, Kyoto-shi, Kyoto F-term in Kansai New Technology Research Laboratories (reference) 2F014 AC01 BA00 GA10 4C017 AA10 AA16 AB10 AC03 BC16 BD06 CC02 CC06 4C094 AA01 DD14 FF09 FF17 GG12

Claims (5)

[Claims] 1. A water pressure measuring means for converting a water pressure in a bathtub into an electric signal for measurement, and extracting a frequency component corresponding to a heartbeat of the bather from a temporal change of the electric signal, and corresponding to the heartbeat. A biological information measuring device comprising: arithmetic means for deriving heart rate information as biological information of the bather from frequency components. 2. The computing means further extracts a frequency component corresponding to a bather's respiration from a temporal change of the electric signal, and derives respiration information from the extracted frequency component as biological information of the bather. 2. The method according to claim 1, wherein
The biological information measuring device according to claim 1. 3. The biological information measuring device according to claim 1, further comprising: a determination unit configured to determine a physical condition of the bather based on the derived biological information. 4. The biological information measuring device according to claim 3, further comprising an alarm unit that issues an alarm based on a result of the determination by the determination unit. 5. The living body information measurement according to claim 1, wherein the water pressure measurement means is a water level sensor for hot water supply control provided at a predetermined location in the bathtub in advance. apparatus.