JP7421051B2 - Biological information acquisition system - Google Patents

Description

The present invention relates to a biological information acquisition system .

If the health condition of the driver who drives the vehicle deteriorates, there is a risk that the driving of the vehicle will be adversely affected, so it is desirable to detect the deterioration of the health condition in advance and take some countermeasures. As a countermeasure to this, biological information such as blood flow and blood pressure is estimated based on the measurement results such as pulse waves by non-contact blood flow sensors embedded in the seat surface and back surface of the seat. There is a known technology for understanding the health condition of a driver (see Patent Document 1).

Japanese Patent Application Publication No. 2016-168177

By the way, cuffless (not using a cuff-type blood pressure monitor) blood pressure measurement based on pulse wave propagation time etc. has large individual differences, and requires calibration using a cuff-type blood pressure monitor depending on the subject. However, it is basically difficult to attach a cuff-type blood pressure monitor to a vehicle. Additionally, when a vehicle is equipped with a biosensor that detects biometric information, vibrations from the vehicle tend to become noise, making it difficult to accurately detect biometric information, which may lead to incorrectly calculating the reference value for blood pressure calculation. There is sex.

In order to solve the above problems, the invention according to claim 1 is a biological information acquisition system, comprising:
A first measuring means and a second measuring means for acquiring biological information of a person;
The data of the first measurement value related to the biological information measured by the first measurement means and the data of the second measurement value related to the biological information measured by the second measurement means can be received by data communication. , correction means for correcting the second measurement value based on the first measurement value;
a vehicle in which the person rides;
a seat provided inside the vehicle for the person to sit on;
It is equipped with
The first measurement value and the second measurement value include personal identification information that identifies the person,
The first measuring means is capable of being worn by the person and is located at a location other than the vehicle ;
The second measuring means is provided on the sheet ,
The second measuring means is configured to include biological sensors provided in at least two places on the sheet so as to be spaced apart from each other,
One of the biosensors is provided on the seat back of the seat,
one of the biosensors is provided on a seat cushion of the seat ;
The correction means corrects the data of the second measurement value by the second measurement means based on the data of the first measurement value by the first measurement means in a state not affected by vibrations of the vehicle. It is characterized by

The invention according to claim 2 is characterized in that, in the biological information acquisition system according to claim 1, the place other than the vehicle is the person's home or a medical institution .

The invention according to claim 3 is a biological information acquisition system,
A first measuring means and a second measuring means for acquiring biological information of a person;
The data of the first measurement value related to the biological information measured by the first measurement means and the data of the second measurement value related to the biological information measured by the second measurement means can be received by data communication. , correction means for correcting the second measurement value based on the first measurement value;
a vehicle in which the person rides;
a seat provided inside the vehicle for the person to sit on;
It is equipped with
The first measurement value and the second measurement value include personal identification information that identifies the person,
The first measuring means and the second measuring means are provided inside a vehicle in which the person rides,
The first measuring means is capable of being worn on the person,
The second measuring means is provided on the sheet,
The second measuring means is configured to include biological sensors provided in at least two places on the sheet so as to be spaced apart from each other,
One of the biosensors is provided on the seat back of the seat,
one of the biosensors is provided on a seat cushion of the seat;
The correction means corrects the data of the second measurement value by the second measurement means based on the data of the first measurement value by the first measurement means when the person is stopping the vehicle. It is characterized by

The invention according to claim 4 is the biological information acquisition system according to claim 3 , wherein the first measuring means is provided in an armrest of the seat ,
The armrest is characterized in that a storage section is provided in which the first measurement means is stored .

The invention according to claim 5 is the biometric information acquisition system according to any one of claims 1 to 4, in which the biosensor provided on the seat back is configured to detect a portion of the seated person among the cushion pads on the seat back. side, and provided on the back side of the outer skin of the seat back,
The biosensor provided on the seat cushion is provided on the upper surface of a cushion pad in the seat cushion and on the back side of the outer skin of the seat cushion .

The invention according to claim 6 is the biological information acquisition system according to any one of claims 1 to 5,
The first measuring means is a sphygmomanometer that measures the blood pressure of the person,
The data of the first measurement value is blood pressure measurement value data measured by the sphygmomanometer,
The biological sensor senses a pulse wave of the person sitting on the seat,
The second measuring means is configured to include the biological sensors provided at least two places on the sheet so as to be spaced apart from each other, and measures the distance between at least two points where the biological sensors are installed, and the biological sensors. The blood pressure estimated value data, which is the second measurement value, is derived by a blood pressure estimation method based on pulse wave transit time, which estimates blood pressure based on the time difference of pulse wave sensing at at least two points where the blood pressure sensor is installed.
The correction means is characterized in that the blood pressure estimated value data is corrected using the blood pressure measured value data as a reference .

The invention according to claim 7 is the biological information acquisition system according to any one of claims 1 to 6, wherein the correction means is provided inside the vehicle,
The second measurement means and the correction means are communicably connected,
The data of the first measurement value obtained by the first measurement means is transmitted to the correction means through a computer network.

The invention according to claim 8 is the biological information acquisition system according to any one of claims 1 to 6, in which the correction means has a short distance between the first measurement means and the second measurement means. It is installed on information terminals capable of wireless communication.
The data of the first measurement value obtained by the first measurement means and the data of the second measurement value obtained by the second measurement means are transmitted to the information terminal by short-range wireless communication. do.

The invention according to claim 9 is the biological information acquisition system according to any one of claims 1 to 6, in which the correction means has information that can be communicated by short-range wireless communication with the second measurement means. It is installed on the terminal,
The data of the first measurement value acquired by the first measurement means is transmitted to the information terminal through a computer network,
The data of the second measurement value acquired by the second measurement means is characterized in that it is transmitted to the information terminal by short-range wireless communication.

According to the invention set forth in claim 1 , the first measuring means when not provided inside the vehicle is not subjected to vibrations from the vehicle. Therefore, it is possible to correct the second measurement value related to the biological information of the person riding in the vehicle based on the first measurement value that is not affected by vehicle vibration, and as a result, accurate biological information can be obtained. Cheap.
Furthermore , since the second measuring means is provided on a seat in the vehicle where a person is seated, biological information can be acquired and corrected not only while riding but also while driving.
Furthermore, since the first measuring means is designed to be wearable on a person, accurate blood pressure can be easily detected by measuring the wearable device as close to the heart as possible in a resting state.
In addition, the second measuring means is a biological sensor provided at at least two places on the seat, so for example, both biological sensors may be a pulse wave sensor, or one biological sensor may be an electrocardiogram sensor, and the other biological sensor may be a pulse wave sensor. By using a pulse wave sensor as the biological sensor, blood pressure can be estimated by a known method using pulse wave propagation time.
Then, since the second measured value is corrected based on the first measured value, it is easier to obtain more accurate biological information.

According to the invention set forth in claim 2, the same effects as the invention set forth in claim 1 can be obtained.

According to the invention described in claim 3, both the first measuring means and the second measuring means are provided in the vehicle, and the second measured value is corrected based on the first measured value, so that, for example, the first measured value It is easier to obtain accurate biometric information than by using either the measuring device or the second measuring device alone to obtain biometric information about a person.
Moreover, it is easier to detect biological information accurately than, for example, when acquiring biological information of a person using either the first measuring means or the second measuring means alone.
Furthermore, if both the first measuring means and the second measuring means are installed in the vehicle, there is no need to install either one in a location other than the vehicle, which allows the system to be consolidated and improves efficiency in terms of maintenance, etc. .
Furthermore, since the first measuring means is designed to be wearable on a person, accurate blood pressure can be easily detected by measuring the wearable device as close to the heart as possible in a resting state.
In addition, the second measuring means is a biological sensor provided at at least two places on the seat, so for example, both biological sensors may be a pulse wave sensor, or one biological sensor may be an electrocardiogram sensor, and the other biological sensor may be a pulse wave sensor. By using a pulse wave sensor as the biological sensor, blood pressure can be estimated by a known method using pulse wave propagation time.
Then, since the second measured value is corrected based on the first measured value, it is easier to obtain more accurate biological information.

According to the invention set forth in claim 6, the same effects as those of the invention set forth in claim 1 or claim 3 can be obtained.

According to the invention set forth in claim 7, the data of the first measurement value acquired by the first measurement means is transmitted to the correction means provided in the vehicle through the computer network, and the second measurement means and the correction means communicate with each other. This makes it possible to correct the second measured value with reference to the first measuring value, even when the vehicle is moving, for example at a distance from the first measuring means, and to ensure accuracy. It is possible to obtain biological information.

According to the invention set forth in claim 8, since the correction means is provided in the information terminal capable of short-range wireless communication with the first measurement means and the second measurement means, the correction means is configured to adjust the first measurement value in advance. If the data is transmitted to the information terminal via short-range wireless communication, even when the vehicle is running or, for example, in a place far away from the first measurement means, the second measurement value can be calculated based on the first measurement value. can be corrected and accurate biological information can be obtained.

According to the invention described in claim 9, the correction means is provided in an information terminal capable of short-range wireless communication with the second measurement means, and the data of the first measurement value acquired by the first measurement means is , is transmitted to the correction means installed in the information terminal through the computer network, so even if the vehicle is running or, for example, in a place far away from the first measurement means, the first measurement value can be used as a reference. The second measurement value can be corrected, and accurate biological information can be obtained.

FIG. 3 is a diagram showing a state in which biological sensors are provided at two locations on the seat. 3 is a graph and a table showing experimental data of a blood pressure estimation method based on pulse wave transit time. FIG. 2 is a diagram illustrating a method of acquiring biometric information using a computer network. 2 is a flowchart illustrating a method of acquiring biometric information using a computer network. FIG. 2 is a diagram illustrating a method of acquiring biometric information using an information terminal. It is a flowchart explaining the method of acquiring biometric information using an information terminal. FIG. 2 is a diagram illustrating a method of acquiring biometric information using a computer network and an information terminal. 2 is a flowchart illustrating a method of acquiring biometric information using a computer network and an information terminal. FIG. 2 is a diagram showing a state in which a cuff-type blood pressure monitor is provided in the car and biological sensors are provided at two locations on the seat.

Embodiments of the present invention will be described below with reference to the drawings. However, although the embodiments described below have various limitations that are technically preferable for implementing the present invention, the technical scope of the present invention is not limited to the embodiments and illustrated examples below. do not have.

[First embodiment]
In FIG. 1, reference numeral 1 indicates a vehicle seat (hereinafter referred to as seat 1) on which a person sits. This seat 1 is provided in a vehicle such as an automobile. The vehicle may be one that runs only manually, or may be one that can run by switching between automatic and manual operation.

The seat 1 includes a seat cushion 2 that supports a person's buttocks and thighs, a seat back 3 whose lower end is supported by the seat cushion 2 and serves as a backrest, and a seat back 3 that is provided on the seat back 3 to support the person's head. A headrest 4 is provided.

The seat cushion 2 is mainly composed of a seat cushion frame serving as a skeleton, a cushion pad provided on the seat cushion frame, and an outer skin covering the seat cushion frame and the cushion pad.

The seat back 3 is mainly composed of a seat back frame serving as a skeleton, a cushion pad provided on the seat back frame, and an outer skin covering the seat back frame and the cushion pad.

The seat 1 is provided with a plurality of biological sensors 10 and 11 (i.e., second measuring means) as a means for ascertaining the health condition of a seated person (living body: seated person). More specifically, the biosensors 10 and 11 in this embodiment detect a pulse wave from the blood flow at a position facing the skin surface of the seated person as biometric information.
In this embodiment, one biological sensor 10 corresponds to the position of the seated person's heart (thoracic aorta), and is provided on the seat back 3 on the seated person's side of the cushion pad and on the back side of the epidermis. ing. Another biosensor 11 corresponds to the position of the seated person's buttocks (the center of the left and right ischial bones) or the thigh, and is provided on the upper surface of the cushion pad of the seat cushion 2 and on the back side of the epidermis. It is being
Note that the biosensor 10 corresponding to the position of the seated person's heart may be an electrocardiogram sensor that detects the seated person's electrocardiogram.

The biological sensors 10 and 11 that detect pulse waves include, for example, photoelectric pulse wave sensors that measure the pulse waves of a seated person using light, and sensors that measure pressure waves on the body surface of the seated person. Examples include a piezoelectric pulse wave sensor that measures the pulse wave of a seated person, and an electromagnetic pulse wave sensor that uses electromagnetic waves to measure the pulse wave of a seated person.
In the present embodiment, any of these plural types of pulse wave sensors may be employed, or these plural types of pulse wave sensors may be used in appropriate combination.

Further, the seat 1 is provided with a control device 5 connected to each of the biological sensors 10 and 11 through a harness or the like so as to be capable of data communication. The control device 5 in this embodiment is provided at the bottom of the seat 1. In other words, it is installed inside the car.
The control device 5 is also referred to as a so-called ECU (Electronic Control Unit), and functions as a blood pressure estimating section that estimates the blood pressure of the seated person from the pulse waves (electrocardiograms) obtained by the biological sensors 10 and 11. A blood pressure estimation program is stored in a memory (not shown) in the control device 5, and data related to the estimated value of the blood pressure of the seated person (i.e., the second measured value) can be calculated and derived based on this blood pressure estimation program. shall be able to do so. Therefore, the control device 5 functions as a second measuring means together with the plurality of biological sensors 10 and 11.

To explain in more detail, blood pressure is estimated based on the distance between the two points where the biosensors 10 and 11 are installed and the time difference between pulse wave sensing at the two points where the biosensors 10 and 11 are installed. Blood pressure can be estimated using a known blood pressure estimation method based on pulse wave propagation time. The blood pressure estimation program described above is created based on the blood pressure estimation method, and is executed by the control device 5 described above.
In other words, if the plurality of biosensors 10 and 11 are arranged in at least two places on the seat 1 so as to be spaced apart from each other as shown in FIG. It becomes possible to detect wave data. Thereby, the accuracy when estimating blood pressure from detected pulse wave data and calculating the health condition of the seated person can be improved compared to the case where only one biosensor is used.

By the way, the method of estimating blood pressure based on pulse wave propagation time tends to have large individual differences, as shown by the experimental data in FIGS. It is also susceptible to vibrations from vehicles.
Therefore, in this embodiment, in order to make it easier to derive accurate blood pressure using a blood pressure estimation method based on pulse wave propagation time even when riding in a vehicle, the device can be attached to a person's extremities as shown in Figure 3. Blood pressure is measured multiple times in advance using a blood pressure monitor 20 (hereinafter referred to as cuff type blood pressure monitor 20) having a cuff 21 (see FIG. 9), and the control device 5 collects blood pressure measurement value data measured by the blood pressure monitor. is used as a reference to correct (calibrate) blood pressure estimate data estimated by the blood pressure estimation method based on pulse wave transit time.

That is, the control device 5 functions as a correction unit that corrects the estimated blood pressure data based on the measured blood pressure data.
To explain in more detail, a correction program for realizing the function as the correction means is stored in the memory of the control device 5, and the control device 5 adjusts the blood pressure measurement value data based on this correction program. The estimated blood pressure data is corrected as a reference.
Such a correction program causes the control device 5, which is a computer, to calculate the biological information of a person based on the data of the first measurement value related to the biological information measured by the first measuring means for acquiring the biological information of the person. It functions as a correction means for correcting the data of the second measurement value related to the biological information measured by the second measurement means for acquiring the biological information.
Therefore, the control device 5 also functions as the second measuring means as described above, and also functions as the correcting means.

In addition, the control device 5 further includes a communication unit for connecting to computer networks such as the Internet 6, and can access a server (not shown) compatible with cloud computing via the Internet 6. It becomes.

Note that the blood pressure estimated value data includes pulse wave transit time [PWTT (Pulse Wave Transit Time)]. Further, the blood pressure estimated value data includes personal identification information for identifying an individual. The means for identifying individuals is not particularly limited, and for example, the seated person may transmit the seated person's ID (identification information) to the control device 5, the seated person may input information himself/herself, or a seated sensor may be used to measure the body weight. identify an individual by using personal information or using other means of personal authentication. The vehicle shall be equipped with appropriate equipment and functions necessary to identify individuals.

The cuff-type blood pressure monitor 20 (i.e., the first measurement means) employs an indirect measurement method (also referred to as an indirect method, non-invasive method, or non-invasive method), and in this embodiment, It is said to be an automatic blood pressure monitor that can perform mechanical measurements. The main body includes at least a display section 20a that displays blood pressure, a pump (not shown) that sends air to the cuff 21, and a communication section (not shown) that sends data to the outside. .

The communication unit is capable of transmitting blood pressure measurement value data (ie, first measurement value) to the outside by using a computer network such as the Internet 6.
As shown in FIG. 3, the communication unit in this embodiment is configured to transmit blood pressure measurement values to a server (not shown) that supports cloud computing via the Internet 6.

Note that the blood pressure measurement value data measured by the cuff type blood pressure monitor 20 includes personal identification information for identifying the individual. There are no particular limitations on the means for identifying an individual, and for example, sending an ID (identification information) to the cuff-type blood pressure monitor 20, reading an ID composed of a bar code, etc., or inputting information by yourself. Individuals may be identified by using personal information or other means of personal authentication. It is assumed that the cuff-type blood pressure monitor 20 or its peripheral equipment is appropriately equipped with functions necessary for identifying individuals.

The cuff 21 is a compression band that can be wrapped around a person's extremities, and is inflated by air being pumped in from the pump in the blood pressure monitor body, and senses blood pressure using an acoustic sensor such as a built-in microphone.
Furthermore, the blood pressure monitor body and the cuff 21 are connected by a connection line for transmitting sensing information by an acoustic sensor to the blood pressure monitor body, and an air supply pipe 21a (see FIG. 9) that sends air from a pump in the blood pressure monitor body to the cuff 21. It is connected.

In this embodiment, the cuff type blood pressure monitor 20 is located at a location other than the vehicle, and specifically, is located at the home of the person sitting on the seat 1. However, the location is not limited to this, and may be a medical institution such as a hospital, or any other location. In other words, it is only necessary that the cuff type blood pressure monitor 20 be placed in a place other than the vehicle, in an environment where a computer network can be used, and in an environment where individuals can be identified.

Here, a method for acquiring the blood pressure (i.e., biological information) of a seated person using the cuff-type blood pressure monitor 20 and the plurality of biological sensors 10 and 11 as described above will be described.

As shown in FIG. 4, first, a person (seated person) measures his or her blood pressure using a cuff-type blood pressure monitor 20 at a location other than the vehicle, in this embodiment, at home (step S1). Thereby, blood pressure measurement value data, which is the first measurement value, can be derived.

Subsequently, the communication unit in the cuff-type blood pressure monitor 20 transmits the blood pressure measurement data via the Internet 6 to a server compatible with cloud computing (step S2).

Subsequently, the control device 5 provided in the vehicle downloads blood pressure measurement value data from the above-mentioned server via the Internet 6 (step S3).
The timing at which the control device 5 downloads the blood pressure measurement value data may be immediately after the blood pressure measurement value data is transmitted to the server by the communication unit in the cuff type blood pressure monitor 20, or may be at the timing when the person is seated on the seat 1. The timing may be such that the blood pressure is estimated by the plurality of biosensors 10 and 11 after the person is seated.

Next, the blood pressure of the seated person is estimated using the plurality of biological sensors 10 and 11 provided on the seat 1 using a known blood pressure estimation method based on pulse wave propagation time (step S4). Thereby, blood pressure estimated value data (pulse wave transit time), which is the second measured value, can be derived.

Then, when the blood pressure estimated value data is derived, the control device 5 corrects the blood pressure estimated value data using the downloaded blood pressure measured value data as a reference, and calculates the blood pressure measurement result (step S5). That is, the "current" blood pressure of the person sitting on the seat 1 can be derived in a relatively accurate state based on the blood pressure measurement value data.

In the present embodiment, the control device 5 uses blood pressure measurement data measured by the cuff-type blood pressure monitor 20 to correct (calibrate) blood pressure estimation data estimated by the blood pressure estimation method using pulse wave transit time. The calculation formula in this case is as follows.
Formula) BP=α×PWTT+β

Here, BP is the blood pressure to be derived, and the unit is [mmHg]. Further, PWTT is pulse wave propagation time, and has a unit [sec], that is, "second".
Further, α and β are personal parameters, and numerical values based on blood pressure measurement data measured by the cuff type blood pressure monitor 20, which is the first measuring means, are applied. To explain with reference to FIG. 2, α is an approximate straight line (that is, slope) derived from the blood pressure measurement data obtained by measuring a person's blood pressure multiple times with the cuff-type blood pressure monitor 20, and β is the approximate straight line (that is, the slope) of the blood pressure. The measured value (i.e., the intercept). Therefore, in FIG. 2, "Mr. A" has α of "-705" and β of "+235", and "Mr. B" has α of "-670", β of "+245", and "C "Mr." has α of "-472" and β of "+188."
Here, for example, if "Mr. A" is a seated person and the pulse wave transit time [PWTT] is derived from the plurality of biological sensors 10 and 11 after sitting on the seat 1 of the vehicle and applied to the above formula, the correction can be made. It is now possible to calculate blood pressure values. For example, when the pulse wave transit time [PWTT] derived by the plurality of biosensors 10 and 11 is 0.160 "sec", the blood pressure is calculated as 122.2 [mmHg].

The blood pressure of the seated person can be obtained in the manner described above.
In addition, in this embodiment, blood pressure is mentioned as a person's biological information that can be acquired by the biological information acquisition system, but it is not limited to this, and for example, biological information (vital signs) such as body temperature can also be acquired. good.

According to this embodiment, the cuff type blood pressure monitor 20, which is not provided inside the vehicle, is not subjected to vibrations from the vehicle. Therefore, it is necessary to correct the estimated blood pressure data related to the biological information of the person riding in the vehicle (i.e., the subject of the cuffless blood pressure measurement device) based on the blood pressure measurement data that is not affected by vehicle vibration. As a result, it is easier to obtain accurate biological information.
Furthermore, even if both the cuff-type blood pressure monitor 20 and the biological sensors 10 and 11 are installed in the vehicle, the estimated blood pressure data is corrected based on the blood pressure measurement data. , 11 alone to obtain a person's blood pressure, it is easier to obtain accurate biological information.

Furthermore, since the cuff-type blood pressure monitor 20 is not subjected to vibrations from the vehicle, the pulse wave (and pulse wave transit time) of the person riding in the vehicle is measured based on blood pressure measurement data that is not affected by vehicle vibration. ), it becomes possible to correct the estimated blood pressure data, making it easier to obtain accurate blood pressure values.

Furthermore, since the plurality of biosensors 10 and 11 are provided in the seat 1 in the vehicle where a person is seated, biometric information can be acquired and corrected not only while riding but also while driving.

Moreover, if the cuff-type blood pressure monitor 20 is used, accurate blood pressure can be easily detected by measuring the cuff 21 as close to the heart as possible in a resting state.
Furthermore, if the biosensors 10 and 11 provided at at least two places on the sheet are used, for example, both biosensors 10 and 11 can be used as pulse wave sensors, or one biosensor 10 can be used as an electrocardiogram sensor, and the other biosensor 10 can be used as a pulse wave sensor. By using a pulse wave sensor as the sensor 11, blood pressure can be estimated by a known method using pulse wave propagation time.
Then, since the estimated blood pressure data is corrected based on the measured blood pressure data, it is easier to obtain more accurate biological information.

Further, since the blood pressure measurement value data and the blood pressure estimation value data include personal identification information that identifies a person, it is possible to obtain the blood pressure of each individual.

Further, the blood pressure measurement value data acquired by the cuff-type blood pressure monitor 20 is transmitted to the control device 5 provided in the vehicle through the computer network, and the plurality of biological sensors 10 and 11 and the control device 5 are communicably connected. Therefore, even if the vehicle is running or, for example, in a place far away from the cuff-type blood pressure monitor 20, the estimated blood pressure data can be corrected based on the blood pressure measurement data, and accurate blood pressure can be obtained. can do.

[Second embodiment]
Next, a second embodiment of the present invention will be described with reference to the drawings. Note that for convenience of explanation, only the constituent parts that are different from the first embodiment described above will be explained.

In this embodiment, as shown in FIG. 5, the correction means includes a cuff type blood pressure monitor 20 as a first measurement means and a plurality of biological sensors 10 and 11 (including a control device 5) as a second measurement means. The information terminal 7 is provided with the information terminal 7 capable of short-distance wireless communication between the two terminals.
The information terminal 7 employs a portable information processing device such as a smartphone or a tablet terminal, and has a short-range wireless communication unit such as Bluetooth (registered trademark). Note that a smartphone is employed in this embodiment.

A correction program for causing the information terminal 7 to function as a correction means is stored in a storage section included in the information terminal 7, and executed by a control section included in the information terminal 7.
Further, this information terminal 7 is used by a person to be measured using a cuff type blood pressure monitor 20 and a plurality of biological sensors 10 and 11.

The cuff-type blood pressure monitor 20 includes a short-range wireless communication unit in order to transmit blood pressure measurement value data, which is a first measurement value, to the information terminal 7.
It is assumed that the second measuring means in this embodiment is constituted by a plurality of biological sensors 10 and 11 and a control device 5. That is, the control device 5 is communicably connected to the plurality of biological sensors 10 and 11, and includes a short-range wireless communication section.

Here, a method for acquiring the blood pressure (i.e., biological information) of a seated person using the cuff-type blood pressure monitor 20 and the plurality of biological sensors 10 and 11 as described above will be described.

As shown in FIG. 6, first, a person (seated person) measures blood pressure using the cuff type blood pressure monitor 20 at a place other than the vehicle, in this embodiment, at home (step S11). Thereby, blood pressure measurement value data, which is the first measurement value, can be derived.

Subsequently, blood pressure measurement value data is transmitted from the cuff-type blood pressure monitor 20 to the information terminal 7 using short-range wireless communication. In other words, the information terminal 7 receives blood pressure measurement value data from the cuff type blood pressure monitor 20 (step S12).

Next, the blood pressure of the seated person is estimated using the plurality of biosensors 10 and 11 provided on the seat 1 using a known blood pressure estimation method based on pulse wave propagation time (step S13). Thereby, blood pressure estimated value data (pulse wave transit time), which is the second measured value, can be derived.

Subsequently, blood pressure estimate data is transmitted from the control device 5 provided in the seat 1 to the information terminal 7 using short-range wireless communication. In other words, the information terminal 7 receives the estimated blood pressure data from the control device 5 (step S14).

The information terminal 7 then corrects the estimated blood pressure data based on the blood pressure measurement data and calculates the blood pressure measurement result (step S15). That is, the "current" blood pressure of the person sitting on the seat 1 can be derived in a relatively accurate state based on the blood pressure measurement value data.
The information terminal 7 may correct the estimated blood pressure data immediately after receiving the estimated blood pressure data from the control device 5, or when the person to be measured (seated person) corrects the estimated blood pressure data on the touch panel of the information terminal 7. It may be operated at any timing.
The blood pressure of the seated person can be obtained in the manner described above.

According to the present embodiment, the correction means performs short-range wireless communication between the cuff-type blood pressure monitor 20 that is the first measurement means and the plurality of biological sensors 10 and 11 (including the control device 5) that is the second measurement means. Since it is provided in the information terminal 7 that can communicate, if blood pressure measurement value data, which is the first measurement value data, is transmitted to the information terminal 7 by short-range wireless communication in advance, even when the vehicle is running, For example, even if the location is far from the cuff-type blood pressure monitor 20, the estimated blood pressure data can be corrected based on the measured blood pressure data, and accurate biological information can be obtained.

[Third embodiment]
Next, a third embodiment of the present invention will be described with reference to the drawings. For convenience of explanation, only the constituent parts that are different from the first and second embodiments described above will be explained.

In this embodiment, as shown in FIG. 7, the correction means is an information terminal capable of short-range wireless communication with a plurality of biological sensors 10 and 11 (including the control device 5) serving as the second measurement means. It is set at 7.
Further, blood pressure measurement value data acquired by the cuff type blood pressure monitor 20, which is the first measurement means, is transmitted to the information terminal 7 through a computer network such as the Internet 6. The estimated blood pressure data acquired by the plurality of biological sensors 10 and 11 is transmitted to the information terminal 7 by short-range wireless communication.

The information terminal 7 is equipped with a communication unit for connecting to a computer network such as the Internet 6, and can access a server (not shown) compatible with cloud computing via the Internet 6. There is. The information terminal 7 also includes a short-range wireless communication unit such as Bluetooth (registered trademark).

The cuff-type blood pressure monitor 20 is equipped with a communication unit (not shown) for transmitting blood pressure measurement value data to the outside using a computer network such as the Internet 6, and is connected to a cloud computer via the Internet 6. It is possible to access a server (not shown) that supports this service.
Further, the control device 5 communicably connected to the plurality of biosensors 10 and 11 includes a short-range wireless communication section.

Here, a method for acquiring the blood pressure (i.e., biological information) of a seated person using the cuff-type blood pressure monitor 20 and the plurality of biological sensors 10 and 11 as described above will be described.

As shown in FIG. 8, first, a person (seated person) measures blood pressure using the cuff type blood pressure monitor 20 at a place other than the vehicle, in this embodiment, at home (step S21). Thereby, blood pressure measurement value data, which is the first measurement value, can be derived.

Subsequently, the communication unit in the cuff-type blood pressure monitor 20 transmits the blood pressure measurement data via the Internet 6 to a server compatible with cloud computing (step S22).

Subsequently, the information terminal 7 downloads blood pressure measurement value data from the above-mentioned server via the Internet 6 (step S23).
The timing at which the information terminal 7 downloads the blood pressure measurement value data may be immediately after the blood pressure measurement value data is transmitted to the server by the communication unit in the cuff type blood pressure monitor 20, or may be at the timing when the person is seated on the seat 1. The timing may be such that the blood pressure is estimated by the plurality of biosensors 10 and 11 after the person is seated.

Subsequently, the blood pressure of the seated person is estimated using the plurality of biological sensors 10 and 11 provided on the seat 1 using a known blood pressure estimation method based on pulse wave propagation time (step S24). Thereby, blood pressure estimated value data (pulse wave transit time), which is the second measured value, can be derived.

Subsequently, blood pressure estimate data is transmitted from the control device 5 provided in the seat 1 to the information terminal 7 using short-range wireless communication. In other words, the information terminal 7 receives the estimated blood pressure data from the control device 5 (step S25).

The information terminal 7 then corrects the estimated blood pressure data using the blood pressure measurement data as a reference and calculates the blood pressure measurement result (step S26). That is, the "current" blood pressure of the person sitting on the seat 1 can be derived in a relatively accurate state based on the blood pressure measurement value data.
The information terminal 7 may correct the estimated blood pressure data immediately after receiving the estimated blood pressure data from the control device 5, or when the person to be measured (seated person) corrects the estimated blood pressure data on the touch panel of the information terminal 7. It may be operated at any timing.
The blood pressure of the seated person can be obtained in the manner described above.

According to the present embodiment, the correction means is provided in the information terminal 7 capable of short-range wireless communication with the plurality of biological sensors 10 and 11 (including the control device 5) serving as the second measurement means, and The blood pressure measurement value data, which is the first measurement value data acquired by the cuff-type blood pressure monitor 20, which is one measurement means, is transmitted to the correction means provided in the information terminal 7 through the computer network. For example, even if the location is far away from the cuff-type blood pressure monitor 20, the estimated blood pressure data can be corrected based on the measured blood pressure data, and accurate biological information can be obtained.

[Modified example]
Note that the embodiments to which the present invention is applicable are not limited to the embodiments described above, and can be modified as appropriate without departing from the spirit of the present invention. Modifications will be described below. The following modifications may be combined as much as possible.
Furthermore, in each of the following modifications, elements common to the above embodiments are given the same reference numerals, and the description thereof will be omitted or simplified.

In this modification, as shown in FIG. 9, both the first measuring means and the second measuring means are provided inside the vehicle.
The plurality of biosensors 10 and 11 serving as the second measurement means and the control device 5 are provided on the seat 1 similarly to the embodiment described above.
The cuff type sphygmomanometer 20, which is the first measuring means, may be provided at any location in the car, and in this modification, it is provided on the seat back 3 near the upper arm of the seated person or on an armrest (not shown). It is assumed that
In addition, when the cuff type blood pressure monitor 20 is provided in the seat 1, it is preferable that the blood pressure monitor main body is built into the seat 1, and a storage part for storing the cuff 21 and the air tube 21a is provided in the seat back 3 or the armrest.

As described above, the cuff type blood pressure monitor 20 is installed inside the vehicle, and when the blood pressure of a seated person is measured using the cuff type blood pressure monitor 20, the blood pressure of a seated person is basically measured while the vehicle is stopped .

According to this modification, it is easier to detect biological information accurately than, for example, when acquiring human biological information using either the first measuring means or the second measuring means alone. Furthermore, biometric information can be acquired and corrected not only while riding but also while driving.
Furthermore, if both the first measuring means and the second measuring means are installed in the vehicle, there is no need to install either one in a location other than the vehicle, which allows the system to be consolidated and improves efficiency in terms of maintenance, etc. .

1 Seat 2 Seat cushion 3 Seat back 4 Headrest 5 Control device 6 Internet 7 Information terminal 10 Biosensor 11 Biosensor 20 Blood pressure monitor 20a Display unit 21 Cuff 21a Air tube

Claims (9)

A first measuring means and a second measuring means for acquiring biological information of a person;
The data of the first measurement value related to the biological information measured by the first measurement means and the data of the second measurement value related to the biological information measured by the second measurement means can be received by data communication. , correction means for correcting the second measurement value based on the first measurement value;
a vehicle in which the person rides;
a seat provided inside the vehicle for the person to sit on;
It is equipped with
The first measurement value and the second measurement value include personal identification information that identifies the person,
The first measuring means is capable of being worn by the person and is located at a location other than the vehicle;
The second measuring means is provided on the sheet,
The second measuring means is configured to include biological sensors provided in at least two places on the sheet so as to be spaced apart from each other,
One of the biosensors is provided on the seat back of the seat,
one of the biosensors is provided on a seat cushion of the seat;
The correction means corrects the data of the second measurement value by the second measurement means based on the data of the first measurement value by the first measurement means in a state not affected by vibrations of the vehicle. A biological information acquisition system characterized by: The biometric information acquisition system according to claim 1, wherein the location other than the vehicle is the person's home or a medical institution. A first measuring means and a second measuring means for acquiring biological information of a person;
The data of the first measurement value related to the biological information measured by the first measurement means and the data of the second measurement value related to the biological information measured by the second measurement means can be received by data communication. , correction means for correcting the second measurement value based on the first measurement value;
a vehicle in which the person rides;
a seat provided inside the vehicle for the person to sit on;
It is equipped with
The first measurement value and the second measurement value include personal identification information that identifies the person,
The first measuring means and the second measuring means are provided inside a vehicle in which the person rides,
The first measuring means is capable of being worn on the person,
The second measuring means is provided on the sheet,
The second measuring means is configured to include biological sensors provided in at least two places on the sheet so as to be spaced apart from each other,
One of the biosensors is provided on the seat back of the seat,
one of the biosensors is provided on a seat cushion of the seat;
The correction means corrects the data of the second measurement value by the second measurement means based on the data of the first measurement value by the first measurement means when the person is stopping the vehicle. A biological information acquisition system characterized by: The first measuring means is provided on an armrest of the seat,
4. The biological information acquisition system according to claim 3, wherein the armrest is provided with a storage section that stores the first measuring means. The biosensor provided on the seat back is located on the seated person's side of the cushion pad in the seat back and on the back side of the outer skin of the seat back,
5. The biosensor provided on the seat cushion is provided on the upper surface of the cushion pad of the seat cushion and on the back side of the outer skin of the seat cushion. The biological information acquisition system according to item (1). The first measuring means is a sphygmomanometer that measures the blood pressure of the person,
The data of the first measurement value is blood pressure measurement value data measured by the sphygmomanometer,
The biological sensor senses a pulse wave of the person sitting on the seat,
The second measuring means is configured to include the biological sensors provided at least two places on the sheet so as to be spaced apart from each other, and measures the distance between at least two points where the biological sensors are installed, and the biological sensors. The blood pressure estimated value data, which is the second measurement value, is derived by a blood pressure estimation method based on pulse wave transit time, which estimates blood pressure based on the time difference of pulse wave sensing at at least two points where the blood pressure sensor is installed.
6. The biological information acquisition system according to claim 1, wherein the correction means corrects the estimated blood pressure data using the measured blood pressure data as a reference. The correction means is provided inside the vehicle,
The second measurement means and the correction means are communicably connected,
The biological information acquisition system according to any one of claims 1 to 6, wherein data of the first measurement value acquired by the first measurement means is transmitted to the correction means through a computer network. The correction means is provided in an information terminal capable of short-range wireless communication with the first measurement means and the second measurement means,
The data of the first measurement value obtained by the first measurement means and the data of the second measurement value obtained by the second measurement means are transmitted to the information terminal by short-range wireless communication. The biological information acquisition system according to any one of claims 1 to 6. The correction means is provided in an information terminal capable of short-range wireless communication with the second measurement means,
The data of the first measurement value acquired by the first measurement means is transmitted to the information terminal through a computer network,
Biological information acquisition according to any one of claims 1 to 6, characterized in that the data of the second measurement value acquired by the second measurement means is transmitted to the information terminal by short-range wireless communication. system.

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