JP6891956B2 - Telemetry system - Google Patents

Description

The present invention relates to a telemetry system (remote measurement system).

Conventionally, a telemetry system (remote measurement system) has been used as a technique for acquiring measurement data (or acquiring and monitoring measurement data) at a location away from the measurement target. As an example (application example) of a telemetry system, for example, in a hospital, a doctor / nurse waits for data such as an electrocardiogram, pulse, blood pressure, body temperature, and pulse oximeter acquired (measured) by attaching a sensor to a hospitalized patient. A wireless telemetry-type biometric information monitor that sends the data to the place where it is used is used.

Further, for example, Patent Document 1 discloses a physiological condition monitoring system that transmits measurement data from a physiological condition sensor to a physiological condition meter via a secure wireless link. More specifically, this physiological condition monitoring system measures a user's physiological condition and uses a secure wireless link based on a private key to transmit the measured physiological condition data. And, it is equipped with a physiological condition meter that receives physiological condition data via a secure wireless link based on a private key and displays the received physiological condition data.

In this physiological condition monitoring system, when the physiological condition sensor and the physiological condition meter are in close proximity to each other, a private key is generated in response to an instruction and transmitted using a secure wireless link (ie, secret). By exchanging the key), the physiological condition meter and the physiological condition sensor are paired.

JP 2015-510291

As described above, in the physiological state monitoring system described in Patent Document 1, since the physiological state sensor and the physiological state meter are paired one-to-one, the same number of physiological states as the physiological state sensor are used. You will need a meter. That is, when one user wants to attach a plurality of physiological condition sensors, or when he / she wants to attach a physiological condition sensor to each of a plurality of users, the same number of physiological condition meters as the number of physiological condition sensors used is used. Is required. In addition, in this physiological condition monitoring system, it is also necessary to pair a pair of physiological condition sensors and a physiological condition meter before measurement.

Further, when the measurement data transmitted from a plurality of physiological condition sensors is received by a plurality of paired physiological condition meters, complicated processing is performed to integrate the measurement data received by each physiological condition meter. May be required. Therefore, there is a problem that the extensibility of the system is very low.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a telemetry system (remote measurement system) capable of easily expanding the system without deteriorating usability.

The telemetry system according to the present invention is a control having a measurement target information acquisition unit that acquires measurement target information that can identify a measurement target, and a first communication unit that transmits measurement target information acquired by the measurement target information acquisition unit. The device, the measurement unit attached to the measurement target and acquiring the measurement data from the measurement target, and the measurement target information transmitted from the first communication unit are received, and the measurement target information and the measurement data are associated with each other. A measuring device having a second communication unit for transmission, a third communication unit for receiving measurement target information and measurement data transmitted from the second communication unit, and a control unit for processing measurement data in association with the measurement target information. It is characterized by comprising a processing apparatus having the above.

According to the telemetry system according to the present invention, the control device acquires measurement target information that can identify the measurement target, and transmits the measurement target information. On the other hand, the measurement target information is received by the measuring device, and the measurement target information and the acquired measurement data are associated and transmitted. Then, the measurement target information and the measurement data are received in the processing device, and the measurement data is processed in association with the measurement target information. Here, since the measurement data is transmitted in association with the measurement target information, the processing device can recognize (distinguish) the measurement target of the measurement data. Therefore, for example, pairing between each device becomes unnecessary (that is, there is no limitation on the combination of each device). Further, even if the number (number) of measuring devices and control devices increases, it can be easily dealt with, and the expandability is excellent. Further, after the measurement target information is set, the control device does not need to exist within the communicable range of the measurement device (measurable), and is convenient. As a result, the system (telemetry system) can be easily expanded without deteriorating usability.

According to the present invention, it is possible to provide a telemetry system having excellent system expandability and improving usability.

It is a block diagram which shows the structure of the telemetry system (remote measurement system) which concerns on 1st Embodiment. It is a sequence diagram which shows the procedure of the remote measurement processing by the telemetry system (remote measurement system) which concerns on 1st Embodiment. It is a block diagram which shows the structure of the telemetry system which concerns on 2nd Embodiment. It is a sequence diagram which shows the procedure of the remote measurement processing by the telemetry system which concerns on 2nd Embodiment. It is a block diagram which shows the structure of the telemetry system which concerns on 3rd Embodiment. It is a sequence diagram which shows the procedure of the remote measurement processing by the telemetry system which concerns on 3rd Embodiment. It is a block diagram which shows the structure of the telemetry system which concerns on 4th Embodiment. It is a sequence diagram which shows the procedure of the remote measurement processing by the telemetry system which concerns on 4th Embodiment. It is a block diagram which shows the structure of the telemetry system which concerns on 5th Embodiment. It is a sequence diagram which shows the procedure of the remote measurement processing by the telemetry system which concerns on 5th Embodiment. It is a block diagram which shows the structure of the telemetry system which concerns on a modification.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. In the figure, the same reference numerals are used for the same or corresponding parts. Further, in each figure, the same elements are designated by the same reference numerals, and duplicate description will be omitted.

(First Embodiment)
First, the configuration of the telemetry system (remote measurement system) 1 according to the first embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing a functional configuration of the telemetry system 1. Here, a case where the present invention is applied to a system used in a hospital will be described as an example.

The telemetry system (remote measurement system) 1 is mainly composed of a control device 11 which is communicably connected by wireless communication, a measurement device 12, and a processing device 13. In particular, the telemetry system 1 is configured so that the system can be easily expanded without deteriorating usability.

The control device 11 (sensor module control unit) mainly includes an input unit 111, a control unit 112, a storage unit 113, a display unit 114, and a first wireless communication unit 115. The control device 11 is configured to be portable and movable. The control device 11 is carried by a nurse, for example, in a hospital. As the control device 11, for example, a mobile information communication terminal such as a smartphone can be used.

The input unit 111 acquires measurement target information that can identify the measurement target with respect to the measurement target (for example, an inpatient). That is, the input unit 111 functions as the measurement target information acquisition unit described in the claims. Examples of the measurement target information include information such as the ID, name, age, and gender of the inpatient, and biometric information such as the face and veins. Therefore, as the input unit 111, for example, a bar code reader that reads a bar code including information such as an inpatient ID, name, age, and gender, a touch panel (input key) for inputting an inpatient ID, a face, and the like. A camera (imaging device) or the like that acquires imaging data of veins or the like can be appropriately used.

Here, when a barcode reader is used, the holder (inpatient) carries a barcode indicating the measurement target (holder of the measuring device 12, for example, an inpatient), or only the holder (inpatient). It is preferable to attach it to something used by the patient (for example, a bed or desk). On the other hand, when face recognition is performed using a camera, the captured face photograph may be transmitted to an external server or the like to identify the holder (inpatient), or feature amount data is received from the external server in advance. However, the control device 11 may identify the holder. In the case of vein authentication, the holder can be specified in the same manner. The measurement target information acquired by the input unit 111 is output to the storage unit 113, the display unit 114, the first wireless communication unit 115, and the like.

The control unit 112 mainly includes a microprocessor that performs calculations, an EEPROM that stores a program or the like for causing the microprocessor to execute each process, and the like. The control unit 112 comprehensively controls the acquisition, storage, transmission, and the like of the measurement target person information.

The storage unit 113 is composed of, for example, a memory such as SRAM or EEPROM, and stores the acquired measurement target information or the like.

The display unit 114 is composed of, for example, an LCD display or the like, and displays the acquired measurement target information or the like. The user (for example, a nurse) can confirm whether or not the measurement target information is accurately (definitely) acquired by checking the measurement target information displayed on the display unit 114.

The first wireless communication unit 115 has, for example, a transmission function and a reception function based on BLE (Bluetooth (registered trademark) Low Energy). The first wireless communication unit 115 transmits the acquired measurement target information to the measuring device 12. That is, the first wireless communication unit 115 functions as the first communication unit described in the claims.

The measuring device 12 (sensor module) mainly includes a biological sensor 121, a control unit 122, a storage unit 123, and a second wireless communication unit 125. The measuring device 12 is attached (or built-in) to a measurement target (for example, an inpatient) and acquires (measures) biological information of the measurement target (inpatient).

The biological sensor 121 is attached to a measurement target (hospitalized patient) and acquires measurement data (biological information) from the measurement target. The biosensor 121 corresponds to the measuring unit described in the claims. Here, as the biological information, for example, oxygen saturation, blood pressure, blood pressure level, posture, core body temperature, body surface temperature, sleep state, position, heart rate, pulse rate, exercise amount, ECG, PPG, respiration and the like can be mentioned. Can be done. That is, the biosensor 121 includes various biosensors (for example, oxygen saturation sensor, pressure sensor, blood glucose level sensor, acceleration sensor, body temperature sensor, pulse wave sensor, electrocardiographic electrode, etc.) that acquire (detect) these biometric information. ) Is used.

The control unit 122 mainly includes a microprocessor that performs calculations, an EEPROM that stores a program or the like for causing the microprocessor to execute each process, and the like. The control unit 122 comprehensively controls acquisition of measurement data, transmission / reception / storage of measurement target person information and measurement data, and the like.

The storage unit 123 is composed of, for example, a memory such as SRAM or EEPROM, and stores measurement target information received by the second wireless communication unit 125. Further, the storage unit 123 stores the acquired measurement data in association with the measurement target information.

The second wireless communication unit 125 has, for example, a transmission function and a reception function based on BLE. The second wireless communication unit 125 receives the measurement target information transmitted from the control device 11 (first wireless communication unit 115). Further, the second wireless communication unit 125 combines (associates) the measurement target information with the measurement data and transmits the measurement device 13. That is, the second wireless communication unit 125 functions as the second communication unit described in the claims.

The processing device 13 (measurement data receiver) mainly includes a control unit 132, a storage unit 133, and a third wireless communication unit 135. The processing device 13 is installed, for example, in each hospital room, entrance, corridor, or the like.

The control unit 132 mainly includes a microprocessor that performs calculations, an EEPROM that stores a program or the like for causing the microprocessor to execute each process, and the like. The control unit 132 comprehensively controls the processing of measurement data (for example, transmission / reception, storage, relay (gate / way), etc.) associated with the measurement target information.

The storage unit 133 is composed of, for example, a memory such as SRAM or EEPROM, and stores measurement target information, measurement data, and the like received by the third wireless communication unit 135. The measurement target information and the measurement data stored in the storage unit 133 are appropriately output to the control unit 132 or the like described above.

The third wireless communication unit 135 has, for example, a transmission function and a reception function based on BLE. The third wireless communication unit 135 receives the measurement target information and measurement data transmitted from the measuring device 12 (second wireless communication unit 125). That is, the third wireless communication unit 135 functions as the third communication unit described in the claims. The measurement target information and measurement data received by the third wireless communication unit 135 are output to the storage unit 133 described above. The third wireless communication unit 135 may transmit (relay) the measurement target information and the measurement data to, for example, an external server.

Next, the operation of the telemetry system (remote measurement system) 1 will be described with reference to FIG. FIG. 2 is a sequence diagram showing a procedure of remote measurement processing by the telemetry system (remote measurement system) 1.

First, the input unit 111 of the control device 11 acquires the measurement target information of the measurement target (for example, an inpatient) to which the measurement device 12 is attached (step S100). Since the measurement target information and the acquisition method thereof are as described above, detailed description thereof will be omitted here.

Next, the acquired measurement target information is displayed on the display unit 114 of the control device 11 (step S102). At this time, the user (nurse) operating the control device 11 can verbally confirm the name and the like of the measurement target (inpatient), for example.

When it is confirmed that the measurement target information acquired by the control device 11 is correct, the measurement target information is transmitted from the first wireless communication unit 115 to the measurement device 12 (step S104). At that time, for example, setting data for changing the control setting (measurement setting) of the measuring device 12 according to the measurement target (hospitalized patient) may be transmitted together with the measurement target information. The transmitted measurement target information and the like are received by the measuring device 12 (second wireless communication unit 125) and stored in the measuring device 12 (storage unit 123) (step S106).

After that, a command (command) requesting the start of measurement is transmitted from the first wireless communication unit 115 of the control device 11 to the measurement device 12 (step S108). The transmitted measurement start request is received by the measuring device 12 (second wireless communication unit 125) (step S110).

After receiving the measurement start request, the measuring device 12 is in the standby state until the measurement start time is reached, and when the measurement disclosure time is reached, the acquisition (measurement) of the biological information is started (step S112). Then, the measuring device 12 (second wireless communication unit 125) transmits the measurement data to the processing device 13 in association with the measurement target information at a predetermined timing (step S114). In addition, in order to confirm that the measurement has been started normally, the control device 11 may request the measuring device 12 or the processing device 13 to transmit the measurement data after the measurement is started. Further, the measurement of the biological information may be executed at the timing when the measurement request is received from the control device 11.

The processing device 13 that has received the measurement data stores (saves) the measurement data in the recording unit 133 in association with the measurement target information (step S116). The processing device 13 may be configured to transfer measurement data or the like to an external server.

When the measurement of the biological information is completed, the control device 11 (or the processing device 13) transmits a measurement stop request (command) to the measurement device 12 (step S118 or S122). Upon receiving the measurement stop request (command), the measuring device 12 stops the measurement of the biological information (step S120 or S124).

As described in detail above, according to the present embodiment, the control device 11 acquires the measurement target information that can identify the measurement target, and transmits the measurement target information. On the other hand, the measuring device 12 receives the measurement target information and transmits the measurement target information in association with the acquired measurement data. Then, the processing device 13 receives the measurement target information and the measurement data, and processes (stores, etc.) the measurement data in association with the measurement target information. Here, since the measurement data is transmitted in association with the measurement target information, the processing device 13 can recognize (distinguish) the measurement target of the measurement data. Therefore, for example, pairing between each device becomes unnecessary (that is, there is no limitation on the combination of each device). Further, even if the number (number of units) of the measuring device 12 and the control device 11 increases, it can be easily dealt with, and the expandability is excellent. Further, after the measurement target information is set, the control device 11 does not need to exist within the communicable range of the measurement device 12 (measurable), and is convenient. As a result, the system (telemetry system) can be easily expanded without deteriorating usability.

According to the present embodiment, since the control device 11 is configured to be portable, for example, a nurse can carry the control device 11 and move it, and the usability can be further improved.

According to the present embodiment, since the state of the living body (inpatient) is measured by the biological sensor 121 of the measuring device 12, for example, in a hospital, the inpatient is located at a place away from the inpatient to which the measuring device 12 is attached. It becomes possible to monitor the status.

(Second Embodiment)
Next, the telemetry system 2 according to the second embodiment will be described with reference to FIG. Here, the same or similar configurations as those in the above-described first embodiment will be simplified or omitted, and the differences will be mainly described. FIG. 3 is a block diagram showing a functional configuration of the telemetry system 2. In FIG. 3, the same components as those in the first embodiment are designated by the same reference numerals.

The telemetry system 2 is different from the above-mentioned telemetry system 1 in that the control device 21, the measuring device 22, and the processing device 23 are provided in place of the control device 11, the measuring device 12, and the processing device 13. The control device 21 is different from the above-mentioned control device 11 in that it has a first short-range wireless communication unit 215A and a first medium-long-distance wireless communication unit 215B instead of the first wireless communication unit 115. .. Similarly, the measuring device 22 has the second short-range wireless communication unit 225A and the second medium-long-distance wireless communication unit 225B in place of the second wireless communication unit 125, and is different from the measurement device 12 described above. It's different. Further, the processing device 23 is different from the above-mentioned control device 13 in that it has a third medium- and long-distance wireless communication unit 235B instead of the third wireless communication unit 135. Since the other configurations are the same as or the same as those of the above-described first embodiment, detailed description thereof will be omitted here.

As described above, the control device 21 has a first short-range wireless communication unit 215A and a first medium-long-range wireless communication unit 215B having different communication methods and different communication range (communication range / communication area). I have. The first short-range wireless communication unit 215A adopts the same communication method as the second short-range wireless communication unit 225A of the measuring device 22, and can communicate with each other. Similarly, the first medium- and long-distance wireless communication unit 215B adopts the same communication method as the second medium- and long-distance wireless communication unit 225B of the measuring device 22 and the third medium- and long-distance wireless communication unit 235B of the processing device 23. It is possible to communicate with each other.

The first short-range wireless communication unit 215A includes a wireless communication system (wireless communication standard) having a communicable distance of, for example, several centimeters to one meter, for example, NFC (Near Field Communication) (ISO / IEC 18092) or the like. , MIFARE (registered trademark) (ISO / IEC 14443) and other wireless communication methods (wireless communication standards) are used. The first short-range wireless communication unit 215A transmits the measurement target information to the measuring device 22 (second short-range wireless communication unit 225A).

The first medium- and long-range wireless communication unit 215B has a communication method (that is, longer than the first short-range wireless communication unit 215A) having a communicable distance (communication area) of, for example, several meters to several tens of meters (that is, longer than the first short-range wireless communication unit 215A). Wireless communication standards), for example, wireless communication methods (wireless communication standards) such as BLE (Bluetooth (registered trademark) Low Energy), WiFi, LTE (Long Term Evolution), and subgiga (900 MHz band) are used.

Similarly, the measuring device 22 includes a second short-range wireless communication unit 225A and a second medium-long-range wireless communication unit 225B, which have different communication methods and different communication range (communication range). The second short-range wireless communication unit 225A adopts the same communication method as the first short-range wireless communication unit 215A of the control device 21, and is made capable of communicating with each other. Similarly, the second medium- and long-distance wireless communication unit 225B adopts the same communication method as the first medium- and long-distance wireless communication unit 215B of the control device 21 and the third medium- and long-distance wireless communication unit 235B of the processing device 23. It is possible to communicate with each other.

Since the wireless communication method (wireless communication standard) of the second short-range wireless communication unit 225A is the same as that of the first short-range wireless communication unit 215A described above, detailed description thereof will be omitted here. The second short-range wireless communication unit 225A receives the measurement target information and the like transmitted from the control device 22.

Since the wireless communication method (wireless communication standard) of the second medium- and long-distance wireless communication unit 225B is the same as that of the first medium- and long-distance wireless communication unit 215B described above, detailed description thereof will be omitted here. The second medium- and long-distance wireless communication unit 225B associates the measurement target information with the measurement data and transmits the measurement device 23 (third medium- and long-distance wireless communication unit 235B).

The processing device 23 includes a third medium- and long-distance wireless communication unit 235B. The third medium- and long-distance wireless communication unit 235B adopts the same communication method as the first medium- and long-distance wireless communication unit 215B of the control device 21 and the second medium- and long-distance wireless communication unit 225B of the measuring device 22, and can communicate with each other. Has been made.

Since the wireless communication method (wireless communication standard) of the third medium- and long-distance wireless communication unit 235B is the same as that of the first medium- and long-distance wireless communication unit 215B described above, detailed description thereof will be omitted here. The third medium- to long-distance wireless communication unit 235B receives the measurement target information and the measurement data transmitted from the measurement device 22. Since the other configurations are the same as or the same as those of the above-described first embodiment, detailed description thereof will be omitted here.

Next, the operation of the telemetry system 2 will be described with reference to FIG. FIG. 4 is a sequence diagram showing a procedure of remote measurement processing by the telemetry system 2. Here, the points different from the sequence diagram (procedure of remote measurement processing by the telemetry system 1) shown in FIG. 2 described above will be mainly described.

Since steps S200 to S202 are the same as steps S100 to S102 described above, detailed description thereof will be omitted here.

When it is confirmed that the measurement target information acquired by the control device 21 is correct, the measurement target information is transmitted from the first short-range wireless communication unit 215A to the measurement device 22 (step S204). The transmitted measurement target information and the like are received by the measuring device 22 (second short-range wireless communication unit 225A) and stored in the measuring device 22 (storage unit 123) (step S206).

After that, a command (command) requesting the start of measurement is transmitted from the first short-range wireless communication unit 215A of the control device 21 to the measurement device 22 (step S208). The transmitted measurement start request is received by the measuring device 22 (second short-range wireless communication unit 225A) (step S210).

After receiving the measurement start request, the measuring device 22 is in a standby state until the measurement start time is reached, and when the measurement disclosure time is reached, acquisition (measurement) of biological information is started (step S212). Then, the measuring device 22 (second medium- and long-distance wireless communication unit 225B) transmits the measurement data to the processing device 23 in association with the measurement target information at a predetermined timing (step S214).

The processing device 23 (third medium- and long-distance wireless communication unit 235B) that has received the measurement data and the like stores (saves) the measurement data in the recording unit 133 in association with the measurement target information (step S216).

When the measurement of the biological information is completed, the control device 21 (or the processing device 23) transmits a measurement stop request (command) to the measurement device 22 (step S218 or S220). Upon receiving the measurement stop request (command), the measuring device 22 stops the measurement of the biological information (step S220 or S224).

According to the present embodiment, the measurement target information is transmitted from the first short-range wireless communication unit 215A of the control device 21, and the first short-range wireless communication unit 215A (1st short-range wireless communication unit 215A) is transmitted by the second short-range wireless communication unit 225A of the measurement device 22. The measurement target information transmitted from the control device 21) is received. That is, since the measurement target information is transmitted and received between the control device 21 and the measurement device 22 using the wireless communication unit having a shorter communicable distance, for example, crosstalk, erroneous connection, eavesdropping of the measurement target information, etc. It becomes possible to prevent it effectively. On the other hand, the measurement data and the measurement target information are transmitted and received using the communication unit (second medium- and long-range wireless communication unit 215B and third medium- and long-range wireless communication unit 235B) having a relatively long communicable distance, and thus the measurement device. Even if the distance between 22 and the processing device 23 is relatively large, it is possible to transmit and receive measurement data and measurement target information.

Further, according to the present embodiment, communication between the first short-range wireless communication unit 215A and the second short-range wireless communication unit 225A and the second medium-long-range wireless communication unit 225B and the third medium-long-range wireless communication unit 235B. By making the method different, the communicable distance (communicable range) can be appropriately changed (different).

(Third Embodiment)
Next, the telemetry system 3 according to the third embodiment will be described with reference to FIG. Here, the same or similar configurations as those in the second embodiment described above will be simplified or omitted, and the differences will be mainly described. FIG. 5 is a block diagram showing a functional configuration of the telemetry system 3. In FIG. 5, the same components as those in the second embodiment are designated by the same reference numerals.

The telemetry system 3 is different from the above-mentioned telemetry system 2 in that the control device 21, the measuring device 32, and the processing device 33 are provided in place of the control device 21, the measuring device 22, and the processing device 23. Further, the control device 31 is different from the above-mentioned control device 21 (control unit 212) in that the control unit 312 has the secret key generation unit 312a. Similarly, the processing device 33 is different from the above-mentioned control device 23 (control unit 232) in that the control unit 332 has the public key generation unit 332a.

The secret key generation unit 312a of the control device 31 (control unit 312) generates the secret key. Further, the control device 31 (control unit 312) uses the first medium- and long-distance wireless communication unit 215B to transmit a command requesting a public key to the processing device 33. Then, the control device 31 (control unit 312) acquires the public key from the processing device 33. Further, the control device 31 (control unit 312) transmits the generated private key, the acquired public key, and the measurement target information to the measurement device 32 by using the first short-range wireless communication unit 215A.

The measuring device 32 (second short-range wireless communication unit 225A) receives the private key, public key, and measurement target information transmitted from the control device 31 (first short-range wireless communication unit 215A). Then, the measuring device 32 (control unit 322) encrypts the private key and the measurement target information using the public key, and uses the second medium- to long-range wireless communication unit 325B to encrypt the encrypted private key and the measurement target information. It is transmitted to the processing device 33. After that (after the start of measurement), the measuring device 32 (control unit 322) encrypts the measurement target information and the measurement data using the private key. Then, the measuring device 32 (second medium- and long-distance wireless communication unit 325B) transmits the encrypted measurement target information and measurement data to the processing device 33.

On the other hand, the public key generator unit 332a of the processing device 33 (control unit 332) generates the public key. The processing device 33 (third medium- to long-distance wireless communication unit 235B) transmits (replies) the public key in response to a request from the control device 31. Further, the processing device 33 (third medium- and long-range wireless communication unit 235B) receives the private key encrypted using the public key and the measurement target information from the measurement device 32 (second medium- and long-range wireless communication unit 325B). Then, decrypt using the public key to obtain the private key and measurement target information. After that, the processing device 33 (third medium- and long-range wireless communication unit 235B) receives the measurement target information and measurement data encrypted with the private key from the measurement device 32 (second medium- and long-range wireless communication unit 325B). Then, the processing device 33 (control unit 332) decodes the measurement target information and the measurement data using the secret key, and acquires the measurement target information and the measurement data. Since the other configurations are the same as or the same as those of the second embodiment described above, detailed description thereof will be omitted here.

Next, the operation of the telemetry system 3 will be described with reference to FIG. FIG. 6 is a sequence diagram showing a procedure of remote measurement processing by the telemetry system 3. Here, the points different from the sequence diagram (procedure of remote measurement processing by the telemetry system 2) shown in FIG. 4 described above will be mainly described.

Since steps S300 to S302 are the same as steps S200 to S202 described above, detailed description thereof will be omitted here.

Next, in step S304, the secret key is generated by the secret key generation unit 312a of the control device 31 (control unit 312). On the other hand, the first medium- to long-distance wireless communication unit 215B of the control device 31 transmits a command (command) requesting the public key to the processing device 33 (step S306). The processing device 33 (public key generator unit 312a) generates a public key, and the third medium- to long-distance wireless communication unit 235B transmits (replies) the public key in response to a request from the control device 31 (step S308). ..

The control device 31 (first medium- and long-distance wireless communication unit 215B) receives and acquires the public key from the processing device 33 (step S310). Next, the control device 31 (control unit 312) transmits the generated private key, the acquired public key, and the measurement target information to the measurement device 32 by using the first short-range wireless communication unit 215A. (Step S312).

The measuring device 32 (second short-range wireless communication unit 325A) receives the private key, the public key, and the measurement target information transmitted from the control device 31 (step S314). Then, the measuring device 32 (second medium- and long-distance wireless communication unit 325B) transmits the private key encrypted using the public key and the measurement target information to the processing device 43 (step S316).

The processing device 33 (third medium- to long-range wireless communication unit 235B) receives the private key encrypted using the public key and the measurement target information from the measuring device 32, decrypts the information using the public key, and decrypts the private key. , Acquire the measurement target information (step S318). After that, the processing device 33 uses the third medium- and long-distance wireless communication unit 235B to transmit information indicating that the setup is completed to the measuring device 32.

After that, a command (command) requesting the start of measurement is transmitted from the first short-range wireless communication unit 315A of the control device 31 to the measurement device 32 (step S320). The transmitted measurement start request is received by the measuring device 32 (second short-range wireless communication unit 325A) (step S322).

After receiving the measurement start request, the measuring device 32 is in the standby state until the measurement start time is reached, and when the measurement disclosure time is reached, the acquisition (measurement) of the biological information is started (step S324). Then, the measuring device 32 (second medium- and long-distance wireless communication unit 325B) transmits the measurement target information and the measurement data encrypted with the private key to the processing device 33 at a predetermined timing (step S326).

The processing device 33 (third medium- to long-range wireless communication unit 235B) receives the measurement target information and the measurement data encrypted with the private key from the measurement device 32 (step S328). The processing device 33 (control unit 332) that has received the measurement target information and the measurement data encrypted with the private key decodes the measurement target information and the measurement data using the private key, and acquires the measurement target information and the measurement data. To do. Then, the measurement data is stored (saved) in the recording unit 333 in association with the measurement target information (step S330).

When the measurement of the biological information is completed, the control device 31 (or the processing device 33) transmits a measurement stop request (command) to the measurement device 32 (step S332 or S336). Upon receiving the measurement stop request (command), the measuring device 32 stops the measurement of the biometric information (step S334 or S338).

According to the present embodiment, the measuring device 32 (second medium- to long-range wireless communication unit 325B) transmits a private key encrypted using a public key and measurement target information, and then encrypts using the private key. The converted measurement target information and measurement data are transmitted to the processing device 33. On the other hand, the processing device 33 (third medium- to long-range wireless communication unit 235B) receives, decrypts / decrypts the private key encrypted with the public key, obtains the private key, and then encrypts with the private key. The measurement target information and measurement data are received and decrypted. Therefore, it is possible to improve the security in transmitting and receiving measurement data and the like. Further, since the private key and the measurement target information are transmitted at the same time, it is possible to prevent the combination (pair) of the private key and the measurement target information from being registered by mistake.

(Fourth Embodiment)
Next, the telemetry system 4 according to the fourth embodiment will be described with reference to FIG. 7. Here, the same or similar configurations as those in the second embodiment described above will be simplified or omitted, and the differences will be mainly described. FIG. 7 is a block diagram showing a functional configuration of the telemetry system 4. In FIG. 7, the same reference numerals are given to the components that are the same as or equivalent to those of the second embodiment.

The telemetry system 4 is different from the above-mentioned telemetry system 2 in that it is configured to further include a server 44 in addition to the control device 21, the measuring device 22, and the processing device 23. The server 44 can be assumed to be, for example, an electronic medical record system of a hospital.

The server 44 mainly includes a control unit 442, a storage unit 443, and a fourth medium- and long-distance wireless communication unit 445B (corresponding to the fourth communication unit described in the claims).

The third medium- and long-distance wireless communication unit 435B of the processing device 43 transmits measurement data, measurement target information, and the like to the server 44 (fourth medium- and long-distance wireless communication unit 445B). The fourth medium- and long-distance wireless communication unit 445B of the server 44 receives the measurement target information, measurement data, and the like transmitted from the third medium- and long-distance wireless communication unit 435B of the processing device 43. The received measurement target information, measurement data, and the like are stored (stored) in the storage unit 443 of the server 44. Since the other configurations are the same as or the same as those of the second embodiment described above, detailed description thereof will be omitted here.

Next, the operation of the telemetry system 4 will be described with reference to FIG. FIG. 8 is a sequence diagram showing a procedure of remote measurement processing by the telemetry system 4. Here, the points different from the sequence diagram (procedure of remote measurement processing by the telemetry system 2) shown in FIG. 4 described above will be mainly described.

Since steps S400 to S414 are the same as steps S200 to S214 described above, detailed description thereof will be omitted here.

The processing device 43 (third medium- and long-distance wireless communication unit 435B) that has received the measurement data associated with the measurement target information transmits the measurement data and the like to the server 44 (step S416). The server 44 (fourth medium- and long-distance wireless communication unit 445B) receives the measurement data associated with the measurement target information, and stores (saves) the received measurement data and the like in the recording unit 443 (step S418). Since the other (subsequent) procedures (processes) are the same as those of the telemetry system 2 described above, detailed description will be given here.

As described above, since the measurement data is associated with the measurement target information, according to the present embodiment, for example, even if there are a plurality of measurement devices 42 and processing devices 43 constituting the system, the server 44 side. Measurement data can be collected and managed in an integrated manner. Further, even if the number of measuring devices 42 and processing devices 43 constituting the system increases, it is possible to easily cope with the increase.

Further, according to the present embodiment, the combination of the measuring device 22 and the processing device 43 can be freely changed. Therefore, for example, a plurality of processing devices 43 can be installed in the action range of the measurement target person (inpatient). It is possible to increase the degree of freedom of the system.

(Fifth Embodiment)
Next, the telemetry system 5 according to the fifth embodiment will be described with reference to FIG. Here, the same or similar configuration as the above-described third embodiment will be simplified or omitted, and the differences will be mainly described. FIG. 9 is a block diagram showing a functional configuration of the telemetry system 5. In FIG. 9, the same components as those in the third embodiment are designated by the same reference numerals.

The telemetry system 5 is different from the above-mentioned telemetry system 3 in that the server 54 is further provided and the server 54 has the secret key generation unit 543a instead of the processing device 33.

The secret key generation unit 312a of the control device 31 (control unit 312) generates the secret key. The control device 31 (control unit 312) uses the first medium- and long-distance wireless communication unit 215B to transmit a command requesting a public key to the server 54 via the processing device 53. Then, the control device 31 (control unit 312) acquires the public key from the server 54 via the processing device 53. Further, the control device 31 (control unit 312) transmits the generated private key, the acquired public key, and the measurement target information to the measurement device 32 by using the first short-range wireless communication unit 215A.

The measuring device 32 (second short-range wireless communication unit 225A) receives the private key, the public key, and the measurement target information transmitted from the control device 31. Then, the measuring device 32 (control unit 322) encrypts the private key and the measurement target information using the public key, and uses the second medium- to long-range wireless communication unit 225B to encrypt the encrypted private key and the measurement target information. , Is transmitted to the server 54 via the processing device 53 (relaying).

After that (after the start of measurement), the control unit 322 of the measuring device 32 encrypts the measurement target information and the measurement data using the private key. Then, the measuring device 32 (second medium- and long-distance wireless communication unit 325B) transmits the encrypted measurement target information and the measurement data to the server 54 via the processing device 53. Here, in the present embodiment, the processing device 53 acts as a repeater (gateway).

On the other hand, the public key generator unit 542a of the server 54 (control unit 542) generates the public key. The server 54 (fourth medium- and long-distance wireless communication unit 545B) transmits (replies) the public key via the processing device 53 in response to a request from the control device 31. Further, the server 54 (fourth medium- to long-range wireless communication unit 545B) receives the private key and the measurement target information encrypted using the public key from the measuring device 32 via the processing device 53, and uses the public key. To decrypt and obtain the private key and measurement target information. After that, the server 54 (fourth medium- and long-distance wireless communication unit 545B) receives the measurement target information and the measurement data encrypted with the private key from the measurement device 32 via the processing device 53. Then, the server 54 (control unit 542) decodes the measurement target information and the measurement data using the private key, and acquires the measurement target information and the measurement data. Since the other configurations are the same as or the same as those in the third embodiment described above, detailed description thereof will be omitted here.

Next, the operation of the telemetry system 5 will be described with reference to FIG. FIG. 10 is a sequence diagram showing a procedure of remote measurement processing by the telemetry system 5. Here, the points different from the sequence diagram (procedure of remote measurement processing by the telemetry system 3) shown in FIG. 6 described above will be mainly described.

Since steps S500 to S502 are the same as steps S300 to S302 described above, detailed description thereof will be omitted here.

Next, in step S504, the secret key is generated by the secret key generation unit 312a of the control device 31 (control unit 312). Then, the first medium- to long-distance wireless communication unit 215B transmits (relays) an instruction (command) requesting the public key to the server 54 via the processing device 53 (step S506). The server 54 (public key generator 542a) generates a public key, and the public key is transmitted (replied) (from the fourth medium- to long-distance wireless communication unit 545B) in response to a request from the control device 31 (step S508). ).

The control device 31 (control unit 312) receives (relays) the public key from the server 54 via the processing device 53 and acquires the public key (step S510). Next, the control device 31 (control unit 312) transmits the generated private key, the acquired public key, and the measurement target information to the measurement device 32 by using the first short-range wireless communication unit 215A. (Step S512).

The measuring device 32 (second short-range wireless communication unit 225A) receives the private key, the public key, and the measurement target information transmitted from the control device 31 (step S514). Then, the measuring device 32 (control unit 322) encrypts the private key and the measurement target information using the public key, and uses the second medium- and long-range wireless communication unit 225B to encrypt the encrypted private key and the measurement target information. , Is transmitted to the server 54 via the processing device 53 (relaying) (step S516).

The server 54 (fourth medium- to long-range wireless communication unit 545B) receives the private key encrypted using the public key and the measurement target information from the measuring device 32, decrypts them using the public key, and obtains the private key. Acquire the measurement target information (step S518). After that, the fourth medium- and long-distance wireless communication unit 545B is used to transmit information indicating that the setup is completed to the measuring device 32.

After that, a command requesting the start of measurement is transmitted from the first short-range wireless communication unit 215A of the control device 31 to the measurement device 32 (step S520). The transmitted measurement start request is received by the measuring device 32 (second short-range wireless communication unit 225A) (step S522).

After receiving the measurement start request, the measuring device 32 is in the standby state until the measurement start time is reached, and when the measurement disclosure time is reached, the acquisition (measurement) of the biological information is started (step S524). Then, the measuring device 32 (control unit 322) encrypts the measurement target information and the measurement data using the secret key at a predetermined timing, and encrypts the measurement target information and the measurement data with the secret key using the second medium- and long-range wireless communication unit 325B. The measured measurement target information and measurement data are transmitted (relayed) to the server 54 via the processing device 53 (step S526).

The server 54 (fourth medium- and long-distance wireless communication unit 545B) receives (relays) the measurement target information and the measurement data encrypted with the private key from the measurement device 32 via the processing device 43 (step S528). ). The server 54 (control unit 542) that receives the measurement target information and the measurement data encrypted with the private key decodes the measurement target information and the measurement data using the private key, and acquires the measurement target information and the measurement data. .. Then, the measurement data is stored (saved) in the recording unit 543 in association with the measurement target information (step S530).

When the measurement of the biological information is completed, the control device 31 (or the processing device 33) transmits a measurement stop request (command) to the measurement device 32 (step S532 or S536). Upon receiving the measurement stop request (command), the measuring device 32 stops the measurement of the biometric information (step S534 or S538).

According to the present embodiment, the measuring device 32 (second medium- to long-range wireless communication unit 225B) transmits a private key encrypted using a public key and measurement target information, and then encrypts using the private key. The converted measurement target information and measurement data are transmitted to the server 54 via (via) the processing device 53. On the other hand, the private key encrypted with the public key is received and decrypted by the server 54 via the processing device 53 (via) to obtain the private key, and then the measurement target encrypted with the private key. Information and measurement data are received and decrypted. Therefore, it is possible to improve the security in transmitting and receiving measurement data and the like.

Further, by having the public key generation unit 542a on the server 54 side instead of the processing device 33, even if there are a plurality of processing devices 33, it is not necessary to distribute the private key to other processing devices 33, so that the management can be performed. Can be prevented from becoming complicated (that is, the usability can be further improved).

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments and can be modified in various ways. For example, in the above embodiment, the case where the number of the control devices 11 to 31, the measuring devices 12 to 32, and the processing devices 13 to 53 constituting the system is one is described as an example, but it is shown in FIG. 11, for example. A plurality of measuring devices 12 (three in the example of FIG. 11), a plurality of processing devices 13 (two in the example of FIG. 11), and / or a plurality of control devices 11 (1 in the example of FIG. 11). It may be configured to include a stand). In FIG. 11, a plurality of measuring devices 12 and processing devices 13 are provided based on the above-described first embodiment, but in the second to fifth embodiments, the control devices 21 to 31 and the measuring devices 22 to 32 are provided. , A configuration may be configured in which a plurality of processing devices 23 to 53 are provided. In this case, for example, even if there are a plurality of control devices 11 to 31, measuring devices 12 to 32, and processing devices 13 to 53 constituting the system, measurement data can be collected and managed in an integrated manner. Further, even if the number of control devices 11 to 31, measuring devices 12 to 32, and processing devices 13 to 53 constituting the system increases, it is possible to easily cope with the increase.

Further, in the second embodiment, the communicable distance (communicable range) is made variable by changing the wireless communication method (standard), but communication is possible by making the transmission output variable (switching to two or more stages). It may be configured to change the distance. That is, by lowering the transmission output (making it a low output state), the above-mentioned first short-range wireless communication unit 215A and second short-range wireless communication unit 225A are realized, and the transmission output is increased (making it a high output state). Thereby, the above-mentioned first medium- and long-distance wireless communication unit 215B, second medium- and long-distance wireless communication unit 225B, and third medium- and long-distance wireless communication unit 235B and 435B can be realized.

Further, in the above-described embodiments (first to fifth embodiments), the telemetry systems (remote measurement systems) 1 to 5 have been described by taking as an example the case where the biological data of an inpatient is measured remotely in a hospital. The present invention can be applied to systems other than those for measuring biological data. That is, the measurement target is not limited to a living body (for example, an inpatient), and may be, for example, a machine or the like. Therefore, it can be applied to, for example, a system used in a factory or a work site, for example, a system for remotely measuring and monitoring the operating status of a machine. In this case, instead of the biosensor 121, a sensor for measuring the state (operating state) of the machine is used. In this way, it is possible to monitor the state of the machine (for example, the operating state of the machine, the degree of wear of the machine, etc.) at a place away from the measuring device (the machine to be measured).

1,2,3,4,5 Telemetry system (remote measurement system)
11 1,21,31 Control device 111 Input unit 112, 212, 312 Control unit 312a Secret key generation unit 113 Storage unit 114 Display unit 115 1st wireless communication unit 215A 1st short-range wireless communication unit 215B 1st medium- to long-range wireless communication Unit 12, 22, 32 Measuring device 121 Biosensor 122, 222, 322 Control unit 123 Storage unit 125 Second wireless communication unit 225A Second short-range wireless communication unit 225B Second medium- and long-range wireless communication unit 13, 23, 33, 43,53 Processing device 132,232,332 Control unit 332a Public key generator 133 Storage unit 135 Third wireless communication unit 235B, 435B Third medium- and long-range wireless communication unit 44,54 Server 442,542 Control unit 542a Public key Generation unit 443 Storage unit 445B, 545B 4th medium- to long-range wireless communication unit

Claims (9)

A control device having a measurement target information acquisition unit that acquires measurement target information that can identify a measurement target, and a first communication unit that transmits the measurement target information acquired by the measurement target information acquisition unit.
A measurement unit attached to the measurement target and acquiring measurement data from the measurement target receives the measurement target information transmitted from the first communication unit, and associates the measurement target information with the measurement data. measuring a constant device that having a, a second communication unit for transmitting Te,
A processing device having the measurement target information transmitted from the second communication unit, a third communication unit that receives the measurement data, and a control unit that processes the measurement data in association with the measurement target information.
Equipped with a,
The control device further includes a private key generator that generates a private key.
The processing device further includes a public key generator that generates a public key.
The first communication unit acquires the public key from the processing device, transmits the private key, the public key, and the measurement target information.
The second communication unit receives the private key, the public key, and the measurement target information transmitted from the first communication unit, and the private key and the measurement target information encrypted by using the public key. Is then transmitted, and then the measurement target information and the measurement data encrypted using the private key are transmitted.
The third communication unit receives the secret key and the measurement target information encrypted using the public key transmitted from the second communication unit, and then is encrypted using the secret key. Receives and decodes the measurement target information and the measurement data.
A telemetry system characterized by this. A server having a fourth communication unit capable of communicating with the third communication unit is further provided.
The third communication unit transmits the measurement data and the measurement target information, and receives the measurement data.
The fourth communication unit receives the measurement target information and the measurement data transmitted from the third communication unit.
The telemetry system according to claim 1. A control device having a measurement target information acquisition unit that acquires measurement target information that can identify a measurement target, and a first communication unit that transmits the measurement target information acquired by the measurement target information acquisition unit.
A measurement unit attached to the measurement target and acquiring measurement data from the measurement target receives the measurement target information transmitted from the first communication unit, and associates the measurement target information with the measurement data. measuring a constant device that having a, a second communication unit for transmitting Te,
A processing device having the measurement target information transmitted from the second communication unit, a third communication unit that receives the measurement data, and a control unit that processes the measurement data in association with the measurement target information.
A server having a fourth communication unit capable of communicating with the third communication unit, a public key generation unit that generates a public key, and a server.
Equipped with a,
The control device further includes a private key generator that generates a private key.
The fourth communication unit transmits the public key and
The first communication unit acquires the public key and transmits the private key, the public key, and the measurement target information.
The second communication unit receives the private key, the public key, and the measurement target information transmitted from the first communication unit, and the private key and the measurement target information encrypted by using the public key. Is then transmitted, and then the measurement target information and the measurement data encrypted using the private key are transmitted.
The third communication unit receives the private key and the measurement target information encrypted by using the public key transmitted from the second communication unit, and also receives the encrypted private key and the measurement. The target information is transmitted, and then the measurement target information and the measurement data encrypted using the private key are received, and the encrypted measurement target information and the measurement data are transmitted.
The fourth communication unit receives the secret key and the measurement target information encrypted using the public key transmitted from the third communication unit, and then is encrypted using the secret key. Receives and decodes the measurement target information and the measurement data.
A telemetry system characterized by this. The second communication unit includes a second short-range wireless communication unit and a second medium-long-range wireless communication unit having different communicable distances.
The first communication unit has a first short-range wireless communication unit that is made communicable with the second short-range wireless communication unit and communicates with the second short-range wireless communication unit.
The third communication unit has a third medium- and long-distance wireless communication unit that is made communicable with the second medium- and long-distance wireless communication unit and communicates with the second medium- and long-distance wireless communication unit.
The telemetry system according to any one of claims 1 to 3, wherein the telemetry system is characterized in that. The telemetry system according to claim 4 , wherein the second short-range wireless communication unit and the second medium-long-range wireless communication unit have different communication methods. The telemetry system according to claim 4 , wherein the second short-range wireless communication unit and the second medium-long-range wireless communication unit are realized by varying the transmission output. The telemetry system according to any one of claims 1 to 6 , wherein the control device is configured to be portable. The telemetry system according to any one of claims 1 to 7 , wherein the measuring unit constituting the measuring device is a sensor for measuring a state of a living body. The telemetry system according to any one of claims 1 to 7 , wherein the measuring unit constituting the measuring device is a sensor for measuring a state of a machine.

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