JP2011092611A - Biological information analytical system, and biological information analytical method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a biological information analytical system capable of collecting efficiently biological information, and capable of outputting useful information, based on the collected biological information. <P>SOLUTION: A bodily temperature information acquisition part obtains bodily temperature information, a positional information acquisition part obtains positional information indicating a position at the time when the bodily temperature information is obtained by the bodily temperature information acquisition part, and a bodily temperature tendency DB generation part 45 generates a bodily temperature tendency DB 48 stored with a tendency of a bodily temperature of a person existing within an area, in each area, based on the bodily temperature information and the positional information. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a biological information analysis system and a biological information analysis method for outputting a tendency of body temperature of a person in the area for each area.

  2. Description of the Related Art Conventionally, there is a health management system that collects user health data, manages the user's health condition, and provides the user with appropriate diet information (see, for example, Patent Document 1). In this health management system, health data related to the user's health is transmitted from the mobile phone to the health management server. Then, the health management server analyzes the received health management data and generates menu data indicating the menu most suitable for the user.

JP 2006-72665 A

In a system that collects biological information and analyzes the collected biological information, such as the health management system described above, the biological information can be collected more efficiently, and useful information is obtained based on the collected biological information. There is a need to output.
The present invention has been made in view of the above-described circumstances, a biological information analysis system capable of efficiently collecting biological information and outputting useful information based on the collected biological information, and a biological information analysis method The purpose is to provide.

In order to achieve the above object, the present invention provides a biological information analysis system including a plurality of body temperature information acquisition units that acquire body temperature information indicating body temperature, and a position when body temperature information is acquired by the body temperature information acquisition unit. Based on the position information acquisition unit for acquiring the position information indicating the body temperature information acquired by the body temperature information acquisition unit and the position information acquired by the position information acquisition unit, for each area, And a body temperature tendency output unit for outputting a body temperature tendency.
According to this configuration, based on the body temperature information acquired by the body temperature information acquisition unit and the position information acquired by the position information acquisition unit, the tendency of the body temperature of the people in the area is output for each area. For this reason, body temperature information which is biological information can be efficiently collected using a plurality of body temperature acquisition units, and useful information such as a tendency of body temperature of a person in the area can be output using the collected body temperature information. . The trend of the temperature of the person in the area is, for example, information that the temperature of the person in the area tends to be high. By analyzing this information, for example, a predetermined temperature with an increase in body temperature is obtained. It is possible to grasp that there is a possibility that an infectious disease in the area is prevalent. Therefore, the tendency of the body temperature of the people in the area is useful information.

Here, in the biological information analysis system according to the invention, the body temperature information output unit further includes a time information acquisition unit that acquires time information indicating a time when the body temperature information is acquired by the body temperature information acquisition unit, Based on the body temperature information acquired by the body temperature information acquisition unit, the position information acquired by the position information acquisition unit, and the time information acquired by the time information acquisition unit, the area coverage according to the passage of time The tendency of the person's body temperature may be output.
According to this configuration, not only the trend of the temperature of the people in the area at the present time but also the trend of the temperature of the people in the area according to the passage of time can be output, which is more useful in reflecting the passage of time. Information can be output.

Further, in the biological information analysis system of the above invention, an area having a predetermined characteristic related to a temperature trend based on a tendency of the temperature of the person in the area corresponding to the passage of time output by the body temperature trend output unit You may make it further provide the prediction information output part which outputs the prediction information which shows prediction of transition of this.
According to this configuration, it is possible to output more useful information than the prediction information indicating the prediction of the transition of the area having the predetermined characteristic related to the body temperature tendency. In addition, the area having a predetermined characteristic related to the tendency of body temperature refers to, for example, an area where the temperature of the person in the area tends to be high, and prediction information indicating the future transition of the area where the temperature of the person in charge is high By analyzing this, for example, it is possible to grasp in advance an area where a predetermined infectious disease accompanied by an increase in body temperature is predicted to be prevalent. Therefore, prediction information is more useful information.

In the biological information analysis system of the above invention, the temperature trend of the person in the area output by the body temperature tendency output unit may be output to a predetermined target.
According to this configuration, it is possible to promote the use of useful information such as the body temperature tendency of the people in the area.

In the biological information analysis system of the above invention, a thermometer has the body temperature information acquisition unit, and a mobile phone that can be communicably connected to the thermometer has the position information acquisition unit, via the network and the mobile phone. A server that can communicate with each other may have the body temperature tendency output unit.
According to this configuration, it is possible to easily collect body temperature information using existing products such as a thermometer and a mobile phone that are widely spread.

In order to achieve the above object, the present invention provides a biological information analysis method, wherein body temperature information is acquired by a body temperature information acquisition unit, and body temperature information is acquired by the body temperature information acquisition unit by a position information acquisition unit. The position information indicating the position at the time of being acquired is acquired, based on the body temperature information acquired by the body temperature information acquisition unit and the position information acquired by the position information acquisition unit, for each area, It is characterized by outputting a trend of body temperature.
According to this method, based on the body temperature information acquired by the body temperature information acquisition unit and the position information acquired by the position information acquisition unit, the tendency of the body temperature of the people in the area is output for each area. For this reason, body temperature information which is biological information can be efficiently collected using a plurality of body temperature acquisition units, and useful information such as a tendency of body temperature of a person in the area can be output using the collected body temperature information. . The tendency of the temperature of the person in the area is, for example, information that the temperature of the person in the area tends to be high. By analyzing this information, for example, it can be grasped that there is a possibility that a predetermined infectious disease accompanied by an increase in body temperature is prevalent in the area. Therefore, the tendency of the body temperature of the people in the area is useful information.

  According to the present invention, biological information can be efficiently collected, and useful information can be output based on the collected biological information.

It is a figure showing roughly composition of a living body information analysis system. It is a block diagram which shows the functional structure of a thermometer and a mobile telephone. It is a block diagram which shows the functional structure of a biometric information analysis server. It is a figure which shows typically the structure of a body temperature information database. It is a figure which shows typically the structure of a body temperature tendency database. It is a flowchart which shows operation | movement of a biometric information analysis server. It is a figure which shows a body temperature information database and a body temperature tendency database. It is a figure for demonstrating operation | movement of a prediction information output part. It is a flowchart which shows the operation | movement of a thermometer and a mobile telephone. It is a flowchart which shows operation | movement of a biometric information analysis server.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram schematically showing a configuration of a biological information analysis system 1 according to the present embodiment.
As shown in FIG. 1, the biological information analysis system 1 includes a plurality of thermometers 10 and a mobile phone 11, and the thermometer 10 and the mobile phone 11 comply with a predetermined standard such as the Bluetooth (registered trademark) standard. It is configured to be capable of near field communication. The mobile phone 11 is connected to a communication network 13 (network) such as the Internet or a mobile communication network via a wireless base station 12, and a server such as a biological information analysis server 14 (server) is connected via the communication network 13. Various data can be transmitted to and received from the device.
In the present embodiment, one area is defined for each cell of the radio base station 12 (range in which radio waves of the radio base station 12 reach). The biological information analysis system 1 is intended to output the temperature trend of the person in the area for each area using the body temperature information indicating the body temperature measured by the thermometer 10.

FIG. 2 is a block diagram showing functional configurations of the thermometer 10 and the mobile phone 11.
The thermometer 10 is a device that is sandwiched between human sides and measures the human body temperature. The thermometer-side control unit 20, the thermometer measurement unit 21, the thermometer-side display unit 22, and the thermometer-side short-range wireless communication unit 23. And.
The thermometer-side control unit 20 centrally controls each part of the thermometer 10 and includes a CPU, a ROM, a RAM, and other peripheral circuits. The CPU controls each part of the thermometer 10 by executing a control program stored in the ROM. The thermometer-side control unit 20 includes a body temperature information acquisition unit 24. The body temperature information acquisition unit 24 acquires body temperature information indicating body temperature based on an input value from a body temperature measurement unit 21 described later.
The body temperature measurement unit 21 includes a temperature sensor, a CR transmission circuit, and the like, converts a change in resistance value output from the temperature sensor into a frequency, and then outputs the change to the thermometer-side control unit 20.
The thermometer side display unit 22 includes a liquid crystal display panel, and displays various information including information indicating the measured body temperature on the liquid crystal display panel under the control of the thermometer side control unit 20.
The thermometer-side short-range wireless communication unit 23 performs short-range wireless communication based on a predetermined standard with the mobile phone 11 under the control of the thermometer-side control unit 20. In the present embodiment, the thermometer-side control unit 20 controls the thermometer-side short-range wireless communication unit 23 so that the body temperature information acquired by the body temperature information acquiring unit 24 is obtained every time the body temperature information acquiring unit 24 acquires the body temperature information. Transmit to the mobile phone 11.

The mobile phone 11 includes a mobile side control unit 30, a mobile side display unit 31, a mobile side input unit 32, a mobile side short-range wireless communication unit 33, and a wireless communication unit 34.
The mobile side control unit 30 centrally controls each unit of the mobile phone 11 and includes a CPU, a ROM, a RAM, and other peripheral circuits. The portable control unit 30 can execute various timing operations based on a reference clock generated by an oscillator (not shown), and in particular can count the current date and time (year / month / day and time). The portable control unit 30 includes a position information acquisition unit 35 and a time information acquisition unit 36, which will be described later.
The portable display unit 31 includes a liquid crystal display panel, and displays various information on the liquid crystal display panel under the control of the portable control unit 30.
The mobile side input unit 32 detects a user operation on the operation switch provided in the mobile phone 11 and outputs the detected operation to the mobile side control unit 30.
The portable short-range wireless communication unit 33 performs short-range wireless communication based on a predetermined standard with the thermometer 10 under the control of the portable control unit 30. In the present embodiment, the portable side control unit 30 controls the portable side short-range wireless communication unit 33 to acquire body temperature information from the thermometer 10.
The wireless communication unit 34 performs wireless communication based on a predetermined standard with the wireless base station 12 in the area (= cell) where the mobile phone 11 is located under the control of the mobile side control unit 30. Each radio base station 12 stores area information, which is information indicating the area of the radio base station 12, and the mobile-side control unit 30 can acquire the area information by controlling the radio communication unit 34. is there.
When receiving the body temperature information from the thermometer 10, the position information acquisition unit 35 included in the portable side control unit 30 controls the wireless communication unit 34 to access the wireless base station 12, and obtains area information from the wireless base station 12. get. That is, when the body temperature is measured using the thermometer 10, the position information acquisition unit 35 acquires position information that is information indicating an area where the body temperature is measured.
Moreover, the time information acquisition part 36 acquires the information which shows the received date, when body temperature information is received from the thermometer 10. FIG. That is, when the body temperature is measured using the thermometer 10, the time information acquisition unit 36 acquires time information that is information indicating the date and time when the body temperature is measured. Although not shown, the mobile phone 11 includes components and devices included in a general mobile phone, such as a speaker, a microphone, and an antenna for call communication.
In this embodiment, whenever the portable-side control unit 30 receives body temperature information from the thermometer 10, the received body temperature information, the position information acquired by the position information acquisition unit 35, and the time acquired by the time information acquisition unit 36. The data including the information is transmitted to the biological information analysis server 14 via the wireless base station 12 and the communication network 13.

FIG. 3 is a block diagram showing a functional configuration of the biological information analysis server 14.
The biological information analysis server 14 includes a server-side control unit 40, a server-side display unit 41, a server-side input unit 42, an interface unit 43, and a storage unit 44.
The server-side control unit 40 centrally controls each unit of the biological information analysis server 14, and includes a CPU, a ROM, a RAM, and other peripheral circuits. The server-side control unit 40 includes a body temperature tendency DB generation unit 45 (body temperature tendency output unit) and a prediction information output unit 46, which will be described later.
The server side display unit 41 includes a display panel such as a liquid crystal display panel or an organic EL display panel, and displays various types of information on the display panel under the control of the server side control unit 40.
The server side input unit 42 includes an input device such as a mouse or a keyboard, detects a user operation on the input device, and outputs it to the server side control unit 40.
The interface unit 43 performs communication based on the communication standard with the communication partner of the biological information analysis server 14 under the control of the server-side control unit 40.
The storage unit 44 includes a storage device such as a hard disk or an EEPROM, and stores various data in a rewritable manner. The storage unit 44 stores a body temperature information database 47, a body temperature trend database 48, and prediction information 49.

FIG. 4 is a diagram schematically showing the configuration of the body temperature information database 47.
One record of the body temperature information database 47 includes a body temperature information field 47a, a position information field 47b, and a time information field 47c. Body temperature information is stored in the body temperature information field 47a, position information is stored in the position information field 47b, and time information is stored in the time information field 47c.
As described above, each time the portable-side control unit 30 of the mobile phone 11 receives the body temperature information from the thermometer 10, the received body temperature information, the position information acquired by the position information acquisition unit 35, and the time information acquisition unit 36. Is transmitted to the biological information analysis server 14 via the wireless base station 12 and the communication network 13. Each time the data is received, the server-side control unit 40 of the biological information analysis server 14 generates one record in the body temperature information database 47 based on the data.
More specifically, when the server-side control unit 40 receives data including body temperature information, position information, and time information from the mobile phone 11, the server-side control unit 40 analyzes the data and detects the body temperature information included in the data. Is stored in the body temperature information field 47a, the position information is stored in the position information field 47b, and the time information is stored in the time information field 47c, thereby generating one record.
As described above, the body temperature information database 47 stores the measured body temperature, the area where the body temperature was measured, and the date and time when the body temperature was measured for the body temperature measurement using the thermometer 10. To do.

FIG. 5 is a diagram schematically showing the configuration of the body temperature tendency database 48.
The body temperature trend database 48 is a database that stores, for each area, a predetermined time zone and trend information indicating a trend of body temperature of a person in the area in the time zone in association with each other. Here, in the present embodiment, as the trend information, a high heat tendency indicating that the temperature of the person in the area tends to be high, and a normal heat indicating that the temperature of the person in the area tends to be close to normal heat. There is a trend. The difference between these high heat trends and normal heat trends, and what areas are determined as high heat trends and normal heat trends will be described in detail later.
One record of the body temperature trend database 48 includes an area field 48a, a time zone field 48b, and a trend information field 48c. Area data indicating an area is stored in the area field 48a. The time zone field 48b stores time zone data indicating the time zone. Trend information is stored in the trend information field 48c.
The body temperature tendency DB generation unit 45 generates one record of the body temperature tendency database 48 for each area at a predetermined timing. In this embodiment, the time zone is divided every hour on the basis of 12:00, such as 12:00 to 13:00, 13: 0 to 14:00, 14: 0 to 15:00, and so on. At the timing when the time zone break has elapsed, the body temperature tendency DB generation unit 45 creates a record for the time zone closest to the break for each area.
Hereinafter, the operation when the body temperature tendency DB generation unit 45 generates a record of the body temperature tendency database 48 will be described in detail.

FIG. 6 shows an example of an operation when the body temperature tendency DB generation unit 45 generates a record of the body temperature tendency database 48. Specifically, the body temperature tendency DB generation unit 45 has an area A1 as one of the areas. FIG. 7 is a flowchart showing an operation when generating a record related to a time zone of 12:00 to 13:00 on 2009/1/1, and FIG. 7 is a diagram used for explaining the operation.
In the operation shown in the flowchart of FIG. 6, the body temperature tendency DB generation unit 45 generates the body temperature information database 47 generated based on the body temperature information acquired by the body temperature information acquisition unit 24 and the position information acquired by the position information acquisition unit 35. For each area, it functions as a body temperature tendency output unit that generates a body temperature tendency database 48 in which the body temperature tendency of the people in the area is stored.

Referring to FIG. 6, body temperature trend DB generation unit 45 determines whether or not the time zone break has elapsed, in this example, whether or not 13:00 of 2009/1/1 has passed (step SA1). ). When the time zone break has elapsed, the body temperature tendency DB generation unit 45 refers to the position information field 47b and the time information field 47c of the body temperature information database 47 (step SA2), and stores the position stored in the position information field 47b. A record in which the information indicates the area A1 and the time information stored in the time information field 47c is included in 12:00 to 13:00 of 2009/1/1 is specified (step SA3). Assume that the records identified here are 10 records shown in FIG.
Next, based on the body temperature information stored in the body temperature information field 47a of the specified record, the body temperature tendency DB generation unit 45 calculates an average value of these body temperature information (step SA4). In the example of FIG. 7A, the average value is “37.64 (° C.)”.
Next, the body temperature tendency DB generation unit 45 tends to have a high temperature (high fever tendency) for the people in the area for one area, or a tendency for the temperature of the people in the area to be close to normal (a normal heat tendency). It is determined whether or not the average value calculated in step SA4 exceeds the threshold value (“37.5 (° C.)” in the present embodiment) for determining whether or not there is (step SA5). As described above, information indicating the high heat tendency or the normal heat tendency corresponds to the trend information.
When it exceeds, body temperature tendency DB production | generation part 45 discriminate | determines that area A1 makes high heat tendency (step SA6). In this example, since the average value (37.64 ° C.)> The threshold value (37.5 ° C.), the area A1 is determined to have a high heat tendency. On the other hand, when it falls below, body temperature tendency DB generation part 45 will discriminate | determine that area A1 corresponds to a normal heat tendency (step SA7).
Next, the body temperature tendency DB generation unit 45 generates one record of the body temperature tendency database 48 related to the area A1. In this example, as shown in FIG. 7B, the body temperature tendency DB generation unit 45 stores area data indicating the area A1 in the area field 48a of the body temperature tendency database 48, and 2009/1 / in the time zone field 48b. The time zone data indicating 1/12: 0 to 13:00 is stored, and the trend information determined that the area A1 corresponds as a result of the determination in step SA5 is stored in the trend information field 48c. In this example, since it is determined that the area A1 has a high heat tendency, the trend information field 48c stores information indicating a high heat tendency.
For each area, a record of the body temperature tendency database 48 is generated at a predetermined timing in the same manner as the area A1.

  As described above, in the present embodiment, in the body temperature trend database 48, the trend information indicating the trend of the body temperature of each area and the people in each area, specifically, the body temperature of the people in the area tends to be high. Information indicating a certain high fever tendency or information indicating a normal fever tendency in which the body temperature of people in the area tends to be normal fever is stored in association with each other. By analyzing the information stored in the body temperature trend database 48, for example, it is possible to grasp that a certain infectious disease accompanied by an increase in body temperature may be prevalent in the area. It becomes.

Next, the prediction information output unit 46 and the prediction information 49 included in the server-side control unit 40 of the biological information analysis server 14 will be described.
The prediction information 49 indicates that, for an area, the area is expected to shift from a high heat area to a normal heat area, and from the normal heat area to a high heat area, and the time when the transfer is expected to occur, It is information including. The prediction information output unit 46 outputs prediction information 49 based on the body temperature tendency database 48.

FIG. 8 is a diagram used for explaining the operation of the prediction information output unit 46, and schematically shows a state in which each area is developed on the same plane. In the following description, an area determined to have a high heat tendency is referred to as a high heat area, and an area determined to have a normal heat tendency is referred to as a normal heat area.
The prediction information output unit 46 refers to the body temperature trend database 48 every predetermined time, and whether or not the high heat area has spread with a predetermined regularity or has converged with a predetermined regularity. To detect.
For example, it is assumed that the distribution of the high heat area and the normal heat area is in a situation as shown in FIG. In addition, the prediction information output part 46 can acquire whether each area is a high heat area or a normal heat area about the past arbitrary time zones by referring to the body temperature tendency database 48.
Then, it is assumed that the distribution of the high heat area and the normal heat area in a time zone in which a predetermined time has elapsed from the time zone in FIG. 8A is in a situation as shown in FIG. In this case, the prediction information output unit 46 detects the movement vector of the high heat area based on the distribution situation of the high heat area shown in FIG. 8A and the distribution situation of the high heat area shown in FIG. Based on the detected movement vector, an area that transitions from the normal heat area to the high heat area, a time when the transition occurs, an area that transitions from the high heat area to the flat heat area, and a time when the transition occurs are detected. For example, when the prediction information output unit 46 reaches the date and time when a predetermined time has elapsed from the time zone of FIG. 8B, the areas B2 and B3 are changed from the high heat area to the normal heat area as shown in FIG. 8C. Further, it is detected that the areas C1, C2, and C3 are predicted to shift from the normal heat area to the high heat area.
Based on the detection result, the prediction information output unit 46 predicts that, for a certain area, the area shifts from the high heat area to the flat heat area, and from the flat heat area to the high heat area. Prediction information 49, which is information including the time when the transition is expected to occur, is output.

As described above, in the present embodiment, the prediction information output unit 46 predicts that, for a certain area, the area will shift from the high heat area to the flat heat area, and from the flat heat area to the high heat area, and The prediction information 49 that is information including the time when the transition is expected to occur is output and stored in the storage unit 44.
By analyzing this prediction information 49, for example, in the situation where infectious diseases with high fever are prevalent in various places, the epidemic spreads in which area in the future, and the epidemic of infectious diseases converges in which area You can get information about what to do. Based on the acquired information, for example, it is possible to warn people in areas where infectious diseases are predicted to be epidemic, and to take countermeasures. It is possible to tell them to purchase more products that deal with infectious diseases. That is, the prediction information 49 is very useful information as information used for dealing with a situation predicted from the current situation.

Referring to FIG. 1, an information provider server 15 (predetermined target) that is owned by an information provider or that can be used by contract is connected to the communication network 13. An information provider is a provider that provides various types of information as a service using television, the Internet, radio, mail, and other means.
In the present embodiment, the biological information analysis server 14 transmits data indicating the body temperature trend database 48 and the prediction information 49 to the information provider server 15 via the communication network 13 in response to a request from the information provider. To do. The data may be transmitted to the information provider server 15 at regular intervals instead of a request from the information provider, and the biological information analysis server 14 can be accessed to the information provider server 15. The data may be obtained from the information provider server 15 side. When the information provider server 15 obtains these data by making the biometric information analysis server 14 accessible to the information provider server 15, the biometric information analysis server 14 sends the data to the information provider server 15. Data is output.

When the information provider server 15 acquires the body temperature trend database 48 and the prediction information 49, the information provider can perform, for example, the following services based on these data.
For example, an information provider can provide information indicating an area in a hot area at the present time by describing on a predetermined homepage on the Internet, using a television or radio, delivering a mail to a pre-registered mail address, Information indicating an area determined to shift to a high heat area in the future can be notified.
A person who recognizes the notification such as a homepage viewer recognizes the area where he / she is located based on the notified information, and takes appropriate measures, for example, the area where he / she is located is a high heat area. If there is a transition to a high fever area in the future, an infection with a high fever will occur in that area, and there is a possibility that it will occur in the future. Effective measures (such as wearing a mask) can be taken.
In addition, the person in charge of the store recognizes the area where the store is located based on the notified information, and then adjusts the inventory of the store, for example, whether the area where the store is located is a high heat area. In addition, if you move to a high fever area in the future, infectious diseases with high fever will occur in that area, and there is a possibility that it will occur in the future, so there are a lot of products (masks etc.) corresponding to infectious diseases It becomes possible to take measures such as stocking.

Next, operations of the thermometer 10, the mobile phone 11, and the biological information analysis server 14 will be described using the flowcharts shown in FIGS. 9A shows the operation of the thermometer 10, FIG. 9B shows the operation of the mobile phone, and FIG. 10 shows the operation of the biological information analysis server 14.
With reference to FIG. 9A, the thermometer-side control unit 20 of the thermometer 10 determines whether or not the measurement of the body temperature has been performed (step SB1). When the body temperature is measured (step SB1: YES), the body temperature information acquisition unit 24 of the thermometer-side control unit 20 acquires body temperature information (step SB2). Next, the thermometer-side control unit 20 controls the thermometer-side short-range wireless communication unit 23 to transmit temperature information to the mobile phone 11 (step SB3).
Referring to FIG. 9 (B), mobile-side control unit 30 of mobile phone 11 monitors whether or not body temperature information has been acquired from thermometer 10 (step SC1). When body temperature information is received (step SC1: YES), that is, when body temperature information is transmitted from the thermometer 10 to the mobile phone 11 at step SB3 in FIG. The acquisition unit 35 acquires position information (step SC2). As described above, the position information is information indicating the area where the body temperature is measured. Next, the time information acquisition unit 36 of the portable control unit 30 acquires time information (step SC3). As described above, the time information is information indicating the date and time when the body temperature is measured. Next, the portable control unit 30 controls the wireless communication unit 34 to transmit body temperature information, position information, and time information to the biological information analysis server 14 (step SC4).

Referring to FIG. 10, server-side control unit 40 of biological information analysis server 14 determines whether or not it is time to generate a record in body temperature trend database 48 (step SD1). As described above, in the present embodiment, at the timing when the time zone break has elapsed, a record for the time zone closest to the break is generated for each area, but the timing of generating the record of the body temperature trend database 48 is For example, a record may be generated every predetermined period. When it is time to generate a record of the body temperature trend database 48 (step SD1: YES), the body temperature trend DB generation unit 45 of the server-side control unit 40 generates a predetermined record of the body temperature trend database 48 (step SD2). ). When the timing for generating the record of the body temperature tendency database 48 has not arrived (step SD1: NO), the server-side control unit 40 shifts the processing procedure to step SD3.
In step SD3, the server-side control unit 40 determines whether or not the timing for generating the prediction information 49 has arrived. When it is time to generate the prediction information 49 (step SD3: YES), the prediction information output unit 46 of the server-side control unit 40 generates (outputs) the prediction information 49 (step SD4). When the timing for generating the prediction information 49 has not arrived (step SD3: NO), the server-side control unit 40 shifts the processing procedure to step SD5.
In step SD5, the server-side control unit 40 determines whether data including body temperature information, position information, and time information has been received from the mobile phone 11, that is, in step SD4 of FIG. 9B, the mobile phone 11 determines whether the data has been transmitted. When the data is received (step SD5: YES), the server-side control unit 40 generates a record of the body temperature information database 47 based on the received data (step SD6), and returns the processing procedure to step SD1. On the other hand, if the data has not been received (step SD5: NO), the server-side control unit 40 returns the processing procedure to step SD1.

As described above, the biological information analysis system 1 according to the present embodiment includes a plurality of thermometers 10 including the body temperature information acquisition unit 24 that acquires body temperature information indicating body temperature, and the body temperature information acquisition unit 24 further provides body temperature information. The mobile phone 11 having the position information acquisition unit 35 that acquires the position information indicating the position when the position is acquired, the body temperature information acquired by the body temperature information acquisition unit 24, and the position information acquired by the position information acquisition unit 35 And a biological information analysis server 14 having a body temperature tendency DB generating unit 45 that generates (outputs) a body temperature tendency database 48 that stores information indicating the body temperature tendency of the people in the area. Yes.
According to this, body temperature information which is biological information can be efficiently collected using the plurality of thermometers 10 having the body temperature information acquisition unit 24, and the body temperature of the people in the area can be collected using the collected body temperature information. Useful information such as trends can be output.

In the present embodiment, the mobile phone 11 includes a time information acquisition unit 36 that acquires time information indicating the time when the body temperature information is acquired by the body temperature information acquisition unit 24 of the thermometer 10. The body temperature trend DB generation unit 45 of the biological information analysis server 14 is acquired by the body temperature information acquired by the body temperature information acquisition unit 24, the position information acquired by the position information acquisition unit 35, and the time information acquisition unit 36. Based on the obtained time information, a body temperature trend database 48 is generated (output) for storing information indicating the temperature trend of the people in the area corresponding to the passage of time for each area.
According to this, it is possible to output not only the trend of the temperature of the people in the area at the current time but also the trend of the temperature of the people in the area according to the passage of time, so more useful information reflecting the passage of time Can be output.

Further, in the present embodiment, the biological information analysis server 14 includes a prediction information output unit 46 that outputs prediction information 49 indicating prediction of transition of a high heat area that is an area having a predetermined characteristic related to a tendency of body temperature.
According to this, it becomes possible to output more useful information than the prediction information 49 indicating the prediction of the transition of the high heat area.

Further, in the present embodiment, the biological information analysis server 14 outputs a body temperature trend database 48 including information related to body temperature trends of people in the area to the information provider server 15.
According to this, utilization of useful information such as a tendency of the body temperature of the people in the area can be promoted.

Further, in this embodiment, the thermometer 10 has a body temperature information acquisition unit 24, and the mobile phone 11 that can be connected to the thermometer 10 so as to be communicable has a position information acquisition unit 35, via the mobile phone 11 and the communication network 13. The biological information analysis server 14 that can communicate with each other has a body temperature tendency DB generation unit 45.
According to this, it is possible to easily collect body temperature information by using widely existing products such as a thermometer and a mobile phone.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.
In the present embodiment, the trend information includes two pieces of information, ie, a high heat trend and a normal heat trend. However, the trend information is not limited to this, and for example, a slight heat trend may be provided between the high heat trend and the normal heat trend. Or you may make it provide other tendency information, such as the tendency information which shows that there exists a tendency for body temperature of 36.0 degreeC-37.0 degreeC to be many.
In the present embodiment, for an area, whether the area has a high fever tendency or a normal fever tendency is determined depending on whether the average value of the body temperature of the people in the area exceeds or falls below a threshold value. However, for example, in the area, the ratio of the number of humans having a body temperature exceeding a predetermined threshold may be determined as to whether the area has a high fever tendency or a normal fever tendency.
In addition, when the mobile phone 11 has a GPS function, the position information may be acquired using the GPS function. In this case, the area may be defined by polygon data. Polygon data is data indicating a polygonal area defined by connecting a plurality of points indicated by coordinate values composed of longitude and latitude.

  DESCRIPTION OF SYMBOLS 1 ... Biological information analysis system, 10 ... Thermometer, 11 ... Mobile phone, 13 ... Communication network (network), 14 ... Biological information analysis server (server), 15 ... Information provider server (predetermined object), 35 ... Location information Acquisition unit, 36 ... time information acquisition unit, 45 ... body temperature trend DB generation unit (body temperature trend output unit), 46 ... prediction information output unit, 49 ... prediction information.

Claims (6)

  A plurality of body temperature information acquisition units that acquire body temperature information indicating body temperature, a position information acquisition unit that acquires position information indicating a position when the body temperature information is acquired by the body temperature information acquisition unit, and the body temperature information acquisition unit A temperature trend output unit that outputs a trend of the temperature of the person in the area for each area based on the body temperature information acquired by the position information acquired by the position information acquisition unit. Biological information analysis system. A time information acquisition unit for acquiring time information indicating a time when the body temperature information is acquired by the body temperature information acquisition unit;
The body temperature tendency output unit is based on body temperature information acquired by the body temperature information acquisition unit, position information acquired by the position information acquisition unit, and time information acquired by the time information acquisition unit. The biological information analysis system according to claim 1, wherein a tendency of the temperature of the person in the area corresponding to the course is output.   Based on the temperature trend of the people in the area according to the passage of time output by the body temperature trend output unit, the prediction information indicating the prediction of the transition of the area having a predetermined characteristic related to the temperature trend is output. The biological information analysis system according to claim 2, further comprising a prediction information output unit.   The biological information analysis system according to any one of claims 1 to 3, wherein the tendency of the body temperature of the person in the area output by the body temperature tendency output unit is output to a predetermined target.   A thermometer has the body temperature information acquisition unit, a mobile phone that can be connected to the thermometer in a communicable manner has the position information acquisition unit, and a server that can communicate with the mobile phone via a network is the body temperature trend output unit The biological information analysis system according to any one of claims 1 to 4, further comprising:   The body temperature information is acquired by the body temperature information acquisition unit, the position information acquisition unit acquires position information indicating the position when the body temperature information is acquired by the body temperature information acquisition unit, and is acquired by the body temperature information acquisition unit. A biological information analysis method that outputs, for each area, a tendency of body temperature of a person in the area based on body temperature information and the position information acquired by the position information acquisition unit.

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