JP2024043037A - System, measuring device, and control program - Google Patents

Abstract

The present invention provides a system, a measuring device, and a control program that are capable of transmitting and receiving information with a valid communication partner while suppressing manufacturing costs and power consumption.
An information management system 100 according to one aspect of the present invention includes an information terminal 5 that transmits a beacon signal, a measuring device 1, and a wireless communication unit that performs wireless communication with the information terminal 5. and a measurement device 1 that transmits an advertisement signal for wireless communication when a beacon signal is received by the measurement device.
[Selection diagram] Figure 1

Description

The present invention relates to a system, a measuring device, and a control program.

Conventionally, a terminal device and an externally connected device (magnet) are provided, and the externally connected device detects the approach of the terminal device by a Hall device, and transitions to a Bluetooth (registered trademark) discoverable state to connect the terminal device and externally connected device. A method of pairing is known (Patent Document 1). Furthermore, a pairing method is known that includes a repeater (portable terminal) and a measuring device and shifts the measuring device to a pairing mode by pressing a button on the measuring device or the like (Patent Document 2). In addition, a biometric information measurement system is known that includes a transmitter (blood sugar measuring device) and a mobile phone, where the mobile phone detects the approach of the transmitter and performs new pairing (mutual authentication) between the approaching transmitter and the mobile phone. (Patent Document 3).

Specific Publication No. 2020-534725 JP2014-216723A Japanese Patent Application Publication No. 2020-036814

According to the pairing method of Patent Document 1, when transitioning to a Bluetooth discoverable state, the Bluetooth keyboard broadcasts information about the Bluetooth keyboard. According to the pairing method of Patent Document 2, pairing information is transmitted and received when a repeater is brought close to a measuring device and the reception strength exceeds a certain threshold. According to the biological information measurement system disclosed in Patent Document 3, the transmitter is identified based on the change in radio field intensity caused by bringing the mobile phone close to the transmitter, and the transmitter and the mobile phone are paired.

In this way, in Patent Document 1, when the Bluetooth enters the discoverable state during pairing, information on the Bluetooth keyboard is broadcast, and this is a method for detecting a communication partner by transmitting an advertisement signal in wireless communication. It is thought that it is used. However, in the case of Patent Document 1, when detecting a communication partner, it is necessary to detect the proximity of the communication partner using a magnetic sensor, which increases manufacturing costs. Further, Patent Document 2 and Patent Document 3 describe specifying a partner based on the strength of a signal, but do not describe transmitting an advertisement signal in wireless communication at that time. Therefore, there is room for improvement in identifying a communication partner by transmitting an advertisement signal during pairing.

One aspect of the present invention has been made in view of the above circumstances, and its purpose is to provide a system that can transmit and receive information with a legitimate communication partner while suppressing manufacturing costs and power consumption. The purpose is to provide a measuring device and a control program.

In order to solve the above problems, the present invention employs the following configuration.

(1)
An information terminal that transmits a beacon signal,
A measuring device, comprising a wireless communication unit that performs wireless communication with the information terminal, and transmits an advertisement signal for the wireless communication when the wireless communication unit receives the beacon signal;
system containing.

According to (1), wireless communication between the measuring device and the information terminal can be started when the measuring device and the information terminal approach each other. It is possible to perform wireless communication between the measurement device and the information terminal, which are communication partners. In addition, since the measuring device can detect the approach of the information terminal using a wireless communication unit that performs wireless communication with the information terminal, a sensor for detecting the proximity between the measuring device and the information terminal (for example, a magnetic sensor or NFC (Near Since it is not necessary to provide a field communication (field communication) chip, etc. in the measuring device, it is possible to reduce the manufacturing cost and power consumption of the measuring device. Moreover, since wireless communication can be performed between the measuring device and the information terminal without constantly transmitting advertising signals, the power consumption of the measuring device can be suppressed.

(2)
The system described in (1),
The measuring device transmits the advertising signal when the received strength of the beacon signal satisfies a first condition.
system.

According to (2), the measuring device transmits the advertising signal when the reception strength of the beacon signal at the measuring device satisfies a predetermined condition. Therefore, wireless communication between the measuring device and the information terminal, which are legitimate communication partners, can be performed.

(3)
The system according to (2),
The first condition is that the change in the reception intensity has become a first pattern.
system.

According to (3), the measuring device transmits the advertising signal when the change in the received strength of the beacon signal becomes a predetermined pattern. Therefore, wireless communication between the measuring device and the information terminal, which are legitimate communication partners, can be performed.

(4)
The system according to (3),
the information terminal issues a notification to prompt a user to change a positional relationship of the information terminal with respect to the measurement device in a second pattern;
The second pattern is a pattern in which the change in the reception intensity becomes the first pattern.
system.

According to (4), by changing the position of the information terminal in a predetermined pattern by the user according to instructions notified from the information terminal, the measuring device can transmit an advertising signal, so that the measuring device and the information terminal can Wireless communication can be performed between legitimate communication partners.

(5)
The system according to any one of (1) to (4),
The information terminal transmits the beacon signal when detecting that the information terminal is stationary in a specific posture.
system.

According to (5), since it is possible to transmit a beacon signal when the information terminal stands still in a specific posture, it is possible to ensure wireless communication between the measuring device and the information terminal, which are legitimate communication partners. .

(6)
The system described in (5),
including a holding member that holds the information terminal in the specific posture;
system.

According to (6), the information terminal can be held in a specific position by the holding member, so that wireless communication between the measuring device and the information terminal, which are both legitimate communication partners, can be performed more reliably.

(7)
The system according to (6),
The holding member is provided on the measuring device.
system.

According to (7), since the information terminal can be held still in a specific posture by the holding member provided on the measuring device, wireless communication between the measuring device and the information terminal, which are legitimate communication partners, can be performed more reliably. be able to.

(8)
a wireless communication section that performs wireless communication with the information terminal;
a control unit that causes the wireless communication unit to transmit an advertisement signal for the wireless communication when the wireless communication unit receives a beacon signal from the information terminal;
A measuring device comprising:

According to (8), wireless communication with the information terminal can be started when the information terminal approaches, so wireless communication can be performed with the information terminal of the legitimate communication partner without having to press and hold the communication button. Can be done. In addition, since the approach of an information terminal can be detected using a wireless communication unit that performs wireless communication with the information terminal, there is no need to provide a sensor for proximity detection (for example, a magnetic force sensor or an NFC chip, etc.), which reduces manufacturing costs. Power consumption can be reduced. Moreover, since wireless communication can be performed with the information terminal without constantly transmitting advertisement signals, power consumption can be suppressed.

(9)
A control program for a measuring device including a wireless communication unit that wirelessly communicates with an information terminal,
a processor of the measuring device;
when the wireless communication unit receives a beacon signal from the information terminal, causing the wireless communication unit to transmit an advertisement signal for the wireless communication;
A control program for executing processing.

According to (9), since it is possible to start wireless communication between the measuring device and the information terminal when the measuring device and the information terminal approach each other, the legitimate communication partner does not have to press and hold the communication button on the measuring device. Wireless communication between the measuring device and the information terminal can be reliably performed. In addition, since the measuring device can detect the approach of the information terminal using a wireless communication unit that performs wireless communication with the information terminal, it is possible to use a sensor for detecting the proximity between the measuring device and the information terminal (for example, a magnetic sensor, an NFC chip, etc.). ) does not need to be provided in the measuring device, it is possible to reduce the manufacturing cost and power consumption of the measuring device. Moreover, since wireless communication can be performed between the measuring device and the information terminal without constantly transmitting advertising signals, the power consumption of the measuring device can be suppressed.

According to the present invention, it is possible to provide a system, a measuring device, and a control program that can transmit and receive information to and from a valid communication partner while suppressing manufacturing costs and power consumption.

1 is a diagram showing a measuring device 1 and an information terminal 5 in an information management system 100 according to a first embodiment to which the present invention is applied. 1 is a diagram showing a measurement state when a user measures body weight and body composition using a weight and body composition meter 1A that is an example of the measuring device 1. FIG. FIG. 2 is a diagram showing an example in which an information terminal 5 is connected to a network. 1 is a block diagram showing the configuration of a measuring device 1. FIG. 2 is a block diagram showing the configuration of an information terminal 5. FIG. FIG. 2 is a sequence diagram showing an example of the operation of the information management system 100 in the first embodiment. FIG. 2 is a diagram showing a sphygmomanometer 1B which is an example of the measurement device 1. It is a diagram showing the configuration of a system 200 according to a second embodiment to which the present invention is applied. 9 is a diagram showing a state in which the smartphone 70 is installed on the pedestal 64 of the blood pressure monitor 60 in FIG. 8. FIG. FIG. 7 is a sequence diagram showing an example of the operation of the system 200 in the second embodiment.

Embodiments according to one aspect of the present invention will be described below based on the drawings.

§1 First application example <Information management system 100 to which the present invention is applied>
FIG. 1 is a diagram showing an information management system 100 according to a first embodiment to which the present invention is applied. The information management system 100 includes a measuring device 1 and an information terminal 5 that performs wireless communication with the measuring device 1. The information management system 100 is an example of the "system" of the present invention.

The measuring device 1 includes a biological information measuring device that measures biological information such as weight, body composition, blood pressure, pulse, heart rate, body temperature, blood sugar, or blood oxygen saturation, and an activity measuring device such as the number of steps, walking distance, or calories burned. an activity measuring device that measures the amount of activity. The measurement device includes a measurement sensor for measuring the amount to be measured. Depending on the measuring device, the measurement target quantity of the measurement sensor may include biological information such as body weight, body fat percentage, blood pressure value, pulse rate, heart rate, body temperature, blood sugar level, or blood oxygen saturation level, number of steps, This includes the amount of activity such as distance traveled or calories burned. The measuring device 1 is, for example, a non-wearable measuring device such as a scale, a body composition meter, a blood pressure meter, a thermometer, or a blood sugar meter, or a wearable measuring device such as a pedometer or an activity meter. A non-wearable measuring device is a measuring device that is not wearable, and is, for example, a measuring device that is used while being installed on the ground or on a table. A wearable measuring device is a measuring device that is carried by being worn on the user's body. The measuring device 1 transmits the measured biological information and activity amount to the information terminal 5 by wireless communication as the user's management measurement information.

The information terminal 5 stores the management measurement information received from the measuring device 1 in a data storage unit within the information terminal 5. The information terminal 5 is also capable of wireless communication with devices other than the measuring device 1, and stores information acquired from external devices in a data storage unit within the information terminal 5. The information terminal 5 is an information processing device that analyzes various information acquired from the measuring device 1 and other external devices. The information terminal 5 is, for example, a terminal having a display such as a smartphone, a tablet terminal, a wearable terminal, a notebook computer, or a desktop computer. The information terminal 5 may be set to acquire the management measurement information from a specific measuring device 1. The specific measuring device 1 from which the management measurement information is acquired may be registered in advance in the data storage unit of the information terminal 5.

FIG. 2 is a diagram showing a measurement state when the user W measures the weight and body composition using the weight and body composition meter 1A, which is an example of the measurement device 1. The weight and body composition meter 1A is an example of a biological information measuring device, and measures the weight and body composition of the user W, outputs the measurement results to the user W, for example, numerically, and also uses the measurement results as management measurement information of the user W. It is transmitted to the information terminal 5 by wireless communication.

FIG. 3 is a diagram showing an example in which the information terminal 5 is connected to a network. As shown in FIG. 3, the information terminal 5 may be connected to a cloud server 90 via a wide area network N such as the Internet. The information terminal 5 may transmit the management measurement information stored therein to the cloud server 90 via the wide area network N, and the cloud server 90 may manage the management measurement information of the user W as a database. Further, the information terminal 5 may acquire management measurement information managed in the cloud server 90 via the wide area network N, and use the acquired management measurement information.

§2 Configuration example <Configuration of measuring device 1>
FIG. 4 is a block diagram showing the configuration of the measuring device 1. As shown in FIG. The measurement device 1 includes a display unit 11 that displays various information, an operation unit 12 that is operated by the user, a measurement unit 13 that measures biological information, activity level, etc., and a wireless communication unit that communicates with external devices. A portion 14 is provided. The measuring device 1 also includes a RAM 16 that temporarily stores information, a data storage section 17 that stores information and programs, and a controller 18 that controls the overall operation. The controller 18 is an example of the "control unit" and "processor" of the present invention.

The display unit 11 includes, for example, a liquid crystal display or an organic EL (Electro Luminescence) display. The operation unit 12 is a user interface such as a button or a touch panel that accepts user operations. The buttons include buttons physically provided on the measuring device 1 and virtual buttons displayed on the display unit 11.

The measurement unit 13 measures biological information such as weight, body composition, blood pressure, pulse, heart rate, body temperature, blood sugar, and blood oxygen saturation, as well as activity levels such as number of steps, walking distance, and calorie consumption. What is measured differs depending on the object to be measured by the measuring device 1.

The wireless communication unit 14 is a communication unit that performs short-range wireless communication, for example, a circuit (module) that performs communication in accordance with the BLE (Bluetooth Low Energy (registered trademark)) standard. The wireless communication (BLE communication) performed by the wireless communication unit 14 is, for example, communication using a 2.4 GHz frequency. The wireless communication unit 14 can operate as a central and a peripheral in BLE communication.

The wireless communication unit 14 operates, for example, as a central unit and receives beacon signals by scanning. The beacon signal refers to a signal transmitted, for example, to specify a communication partner for transmitting and receiving management measurement information, that is, a signal instructing a transition to pairing mode.

The wireless communication unit 14 also operates as a peripheral, for example, and transmits an advertising signal to an unspecified number of external devices by broadcast communication. Specifically, when the wireless communication unit 14 receives a beacon signal, it transmits an advertising signal including a change instruction signal for changing the reception strength of the beacon signal in the wireless communication unit 14. The change instruction signal is a signal that instructs a communication partner that wishes to connect via BLE communication to change the strength of the beacon signal. When a communication partner that complies with the change instruction is detected, the wireless communication unit 14 transmits an advertising signal for transmitting and receiving management measurement information such as biological information and activity level measured by the measurement unit 13.

RAM 16 is composed of semiconductor devices such as DRAM or SRAM, and temporarily stores information and serves as a working area for controller 18.

The data storage unit 17 is a recording medium that stores parameters, control programs, and management measurement information required to realize a specified process. The data storage unit 17 is configured, for example, by a hard disk drive (HDD) or a semiconductor storage device (SSD).

The controller 18 implements predetermined processing by executing a control program. In this embodiment, for example, health management application software for a measuring device is preinstalled as a control program in the data storage unit 17, and the controller 18 executes predetermined processing by executing this health management application software. Realize.

For example, the controller 18 causes the wireless communication unit 14 to operate as a central device and controls the wireless communication unit 14 to receive an advertisement signal (for example, an advertisement signal including a beacon signal) from an external device by scanning.

Further, for example, the controller 18 causes the wireless communication unit 14 to operate as a peripheral, and controls the wireless communication unit 14 to transmit an advertisement signal at a predetermined transmission cycle. Specifically, when the wireless communication unit 14 receives a beacon signal, the controller 18 transmits an advertisement signal including a change instruction signal for changing the reception strength of the beacon signal in the wireless communication unit 14. Controls the communication section 14. The change instruction is an instruction to change the reception strength of the beacon signal in a predetermined pattern. The predetermined pattern is, for example, a pattern in which a beacon signal is received by repeatedly changing its strength. The predetermined pattern is an example of the first pattern of the present invention. In addition, when the controller 18 receives a beacon signal with a reception strength according to the change instruction from an external device after transmitting the change instruction signal, the controller 18 performs management measurement of biological information, activity level, etc. measured by the measurement unit 13. The wireless communication unit 14 is controlled to transmit an advertisement signal for transmitting and receiving information. Further, the controller 18 controls the wireless communication unit 14 so as to transmit the advertising signal including, for example, the name and attribute information of the measuring device 1.

The controller 18 causes the wireless communication unit 14 to operate as a central unit when receiving a beacon signal. Furthermore, when transmitting an advertisement signal, the controller 18 causes the wireless communication unit 14 to operate as a peripheral. The controller 18 alternately switches the wireless communication unit 14 between the central operating state and the peripheral operating state according to a predetermined measurement cycle set in the measuring device 1.

<Configuration of information terminal 5>
FIG. 5 is a block diagram showing the configuration of the information terminal 5. As shown in FIG. The information terminal 5 includes a display unit 51 that displays various information, an operation unit 52 that is operated by the user, a sensor 53 that detects the stationary state of the information terminal 5, and a first wireless communication device that communicates with external devices. It includes a communication section 54 and a second wireless communication section 55. The information terminal 5 also includes a RAM 56 that temporarily stores information, a data storage section 57 that stores information and programs, and a controller 58 that controls the overall operation.

The display section 51 is composed of, for example, a liquid crystal display or an organic EL display. The operation unit 52 is a user interface that accepts user operations such as buttons or a touch panel. The buttons include buttons physically provided on the information terminal 5 and virtual buttons displayed on the display unit 51.

The sensor 53 is, for example, a gyro sensor. The sensor 53 detects that the information terminal 5 is stationary in a specific posture. The specific posture is a posture preset for each information terminal 5. Standing still in a specific posture includes, for example, a posture in which the user interface of the measuring device 1 is lying face down, a posture in which the user interface is tilted in the front-back direction, a posture in which the measuring device 1 is upside down, and a posture in which the measuring device 1 is upside down. Examples include standing still in a position where the bottom or top surface of the screen is not horizontal, or in a position where the horizontal direction of the screen is not horizontal. Stationary means that a specific posture continues for a certain period of time (for example, 3 seconds).

The first wireless communication unit 54 is a communication unit that performs cellular communication, for example, a circuit (module) that performs communication in accordance with standards such as 4G, 5G, and LTE (Long Term Evolution: registered trademark). Further, the first wireless communication unit 54 is a communication unit that performs wireless LAN communication, for example, a circuit (module) for performing communication in accordance with standards such as Wi-Fi. The second wireless communication unit 55 is a communication unit that performs short-range wireless communication, for example, a circuit (module) for performing communication according to the BLE standard. The wireless communication (BLE communication) performed by the second wireless communication unit 55 is, for example, communication using a 2.4 GHz frequency.

The second wireless communication unit 55 can operate as a peripheral and a central in BLE communication. The second wireless communication unit 55 operates, for example, as a peripheral, and transmits an advertisement signal including a beacon signal for instructing a transition to pairing mode to an unspecified number of external devices by broadcast communication. Further, the second wireless communication unit 55 operates, for example, as a central unit and receives a change instruction signal for changing the reception strength of the beacon signal by scanning. Further, the second wireless communication unit 55 operates as a peripheral and transmits an advertisement signal including a beacon signal whose intensity is changed according to the change instruction signal. Further, the second wireless communication unit 55 operates as a central unit and receives an advertisement signal for transmitting and receiving management measurement information such as biological information and an amount of activity by scanning.

RAM 56 is composed of semiconductor devices such as DRAM or SRAM, and temporarily stores information and serves as a working area for controller 58.

The data storage unit 57 is a recording medium that stores parameters, control programs, management measurement information acquired from the measurement device 1, etc. necessary for realizing predetermined processing. The data storage unit 57 includes, for example, a hard disk drive (HDD) or a semiconductor storage device (SSD).

The controller 58 implements predetermined processing by executing a control program. In this embodiment, for example, health management application software for information terminals is preinstalled as a control program in the data storage unit 57, and the controller 58 executes predetermined processing by executing this health management application software. Realize.

For example, the controller 58 causes the second wireless communication unit 55 to operate as a peripheral, and controls the second wireless communication unit 55 to transmit advertisement signals including beacon signals at a predetermined transmission cycle.

Further, the controller 58 controls the second wireless communication unit 55 to operate as a central unit and receive the change instruction signal by scanning. When the controller 58 receives the change instruction signal, the controller 58 detects that the change instruction signal is from the measurement device 1, and changes the reception strength of the beacon signal according to the instruction. Notify the user to change the positional relationship. Specifically, the controller 58 notifies the measuring device 1 to move the information terminal 5 closer to or farther away from the measurement device 1 so that the beacon signal is received with repeated changes in strength.

Further, the controller 58 operates the second wireless communication unit 55 as a peripheral, and controls the second wireless communication unit 55 to transmit an advertisement signal including a beacon signal with a strength according to the change instruction.

Further, the controller 58 causes the second wireless communication unit 55 to operate as a central unit and scan the second wireless communication unit 55 so as to receive advertising signals for transmitting and receiving management measurement information such as biological information and activity level. 55.

The controller 58 operates the second wireless communication unit 55 as a peripheral when transmitting a beacon signal. Further, when receiving the change instruction signal, the controller 58 causes the second wireless communication unit 55 to operate as a central unit. The controller 58 alternately switches the second wireless communication unit 55 between the peripheral operating state and the central operating state according to a predetermined terminal cycle set in the information terminal 5. Further, when transmitting the advertisement signal, the controller 58 controls the second wireless communication unit 55 so as to include, for example, the name and attribute information of the information terminal 5 in the advertisement signal.

§3 Operation example <Operation example of the information management system 100>
Next, an example of the operation of the information management system 100 will be described with reference to FIG. FIG. 6 is a sequence diagram showing the operations of the measuring device 1 and the information terminal 5 in the information management system 100. In this example, the following description will be made assuming that the measuring device 1 is a weight and body composition meter 1A, and the information terminal 5 is a smartphone 5A.

It is assumed that the weight and body composition of the user W are measured by the weight and body composition meter 1A, and the measurement results are stored in the data storage unit 17 as user W's management measurement information. It is assumed that the user W carries the smartphone 5A and is near the weight and body composition meter 1A in order to collect the management measurement information of the user W stored in the weight and body composition meter 1A. It is assumed that the user W launches the health management application on the smartphone 5A and touches, for example, a "connection button" to wirelessly connect the smartphone 5A to the weight and body composition meter 1A.

First, the smartphone 5A starts transmitting a beacon signal that instructs the smartphone 5A to transition to pairing mode (step S11). Next, the smartphone 5A transmits an advertising signal including the beacon signal at a predetermined transmission cycle during peripheral operation (step S12).

Next, during central operation, the body weight/body composition scale 1A scans and receives an advertising signal including a beacon signal. Then, the body weight/body composition scale 1A starts transmitting a change instruction signal to change the reception strength of the beacon signal in the body weight/body composition scale 1A (step S13). Next, during peripheral operation, the body weight/body composition scale 1A transmits an advertising signal including the change instruction signal at a predetermined transmission cycle (step S14).

Next, the smartphone 5A scans and receives an advertisement signal including a change instruction signal during central operation. Then, the smartphone 5A prompts the user W to repeatedly move the smartphone 5A toward and away from the weight and body composition meter 1A in accordance with the change instruction signal from the weight and body composition meter 1A (step S15). . For example, the smartphone 5A prompts the user by displaying on the display screen of the smartphone 5A, "Please move the smartphone closer and further away from the weight and body composition monitor repeatedly." Furthermore, the smartphone 5A may prompt the user by outputting the content to be displayed on the screen audibly.

Next, during peripheral operation, the smartphone 5A sends an advertisement signal including a beacon signal (near) when the user W brings the smartphone 5A close to the weight and body composition meter 1A, and The advertisement signal including the beacon signal (far) when moving away from the target is repeatedly transmitted (steps S16, S17, S18). The smartphone 5A transmits an advertisement signal including the name and attribute information of the smartphone 5A.

Next, during the central operation, the weight and body composition meter 1A scans and receives an advertising signal including a beacon signal (near) and an advertising signal including a beacon signal (far). The weight and body composition meter 1A detects an external device having the highest average reception strength and whose reception strength changes by a certain amount or more from among advertisement signals received from external devices. The highest average reception strength means that the device is located closest to the weight and body composition meter 1A. The fact that the reception strength is changing by a certain amount or more means that the reception strength of the beacon signal is changing according to the change instruction. Then, the weight and body composition meter 1A starts transmitting an advertisement signal for transmitting and receiving management measurement information (step S19). Next, the weight and body composition meter 1A transmits an advertisement signal including a transmission/reception signal of management measurement information at a predetermined transmission cycle during peripheral operation (step S20). The weight and body composition meter 1A transmits an advertisement signal including the name and attribute information of the weight and body composition meter 1A.

Next, the smartphone 5A scans and receives an advertisement signal from the weight and body composition meter 1A during the central operation. Next, the smartphone 5A transmits a connection request signal requesting communication connection during peripheral operation (step S21). The smartphone 5A transmits a connection request signal including the name and attribute information of the smartphone 5A.

Next, when the weight and body composition meter 1A receives a connection request from the smartphone 5A, it switches to one-to-one connection communication with the smartphone 5A. Thereby, the weight and body composition meter 1A and the smartphone 5A are connected via BLE. Next, the weight and body composition meter 1A transfers the management measurement information of the user W to the smartphone 5A via BLE communication (step S22). Next, when the smartphone 5A finishes receiving the management measurement information, it transmits a disconnection request signal requesting disconnection of BLE communication to the weight and body composition meter 1A (step S23). The weight and body composition meter 1A that received the disconnection request disconnects the BLE connection with the smartphone 5A, thereby ending communication between the two.

As explained above, according to the information management system 100, when the weight and body composition meter 1A (measuring device) receives a beacon signal from the smartphone 5A (information terminal), it transmits an advertisement signal to determine the weight and body composition. BLE communication can be started between a total of 1A and a smartphone 5A. Therefore, for example, even if the user does not press and hold the communication button on the weight and body composition meter 1A, it is possible to pair the weight and body composition meter 1A and the smartphone 5A, which are legitimate communication partners. , it is possible to reliably perform BLE communication between the two. Moreover, the weight and body composition meter 1A can detect the approach of the smartphone 5A using the wireless communication unit 14 that performs BLE communication with the smartphone 5A. Therefore, since it is not necessary to provide a sensor for detecting the proximity between the weight and body composition meter 1A and the smartphone 5A (for example, a magnetic sensor or an NFC chip) in the weight and body composition meter 1A, the manufacturing cost of the weight and body composition meter 1A is reduced. and power consumption can be reduced. Moreover, since the weight and body composition meter 1A can perform BLE communication with the smartphone 5A without constantly transmitting advertisement signals, the power consumption of the weight and body composition meter 1A can be suppressed.

Furthermore, according to the information management system 100, the weight and body composition meter 1A performs management when the reception strength of the received beacon signal changes in a predetermined pattern that satisfies the conditions according to the change instruction from the weight and body composition meter 1A. Send an advertisement signal to transfer measurement information. Therefore, BLE communication between the weight and body composition meter 1A and the smartphone 5A, which are legitimate communication partners, can be performed more reliably.

Further, according to the information management system 100, when the user moves the smartphone 5A closer to or away from the weight and body composition meter 1A according to instructions notified from the smartphone 5A, an advertisement signal for transferring management measurement information is transmitted to the body weight. It can be sent from body composition analyzer 1A. Therefore, it is possible to reliably perform BLE communication between the weight and body composition meter 1A and the smartphone 5A as legitimate communication partners.

<Measurement using a blood pressure monitor>
The measuring device 1 in the present invention may be, for example, a blood pressure monitor 1B as shown in FIG. The sphygmomanometer 1B measures the user's blood pressure, outputs the measurement result to the user, for example, as a numerical value, and transmits the measurement result as the user's management measurement information to the information terminal 5 via wireless communication. For example, the blood pressure monitor 1B includes a main body 21, a cuff 22 that can be wrapped around the user's upper arm, and an air tube 23 that connects the main body 21 and the cuff 22. In the example of FIG. 7, the cuff 22 and the main body 21 are separate bodies, but the cuff 22 and the main body 21 may be integrated. Even when measuring the user's blood pressure, pulse rate, and heart rate using the blood pressure monitor 1B, it is possible to perform pairing with an authorized communication partner and perform BLE communication reliably, similarly to the weight and body composition monitor 1A. Moreover, the manufacturing cost of the blood pressure monitor 1B can be reduced, and power consumption can be suppressed.

§4 Second application example <Information management system 200 to which the present invention is applied>
FIG. 8 is a diagram showing an information management system 200 of a second embodiment to which the present invention is applied. The information management system 200 is a system that measures a user's blood pressure and displays the measurement results to the user. Information management system 200 includes a blood pressure monitor 60 and a smartphone 70. The information management system 200 is an example of the "system" of the present invention. The blood pressure monitor 60 is an example of the "measuring device" of the present invention. The smartphone 70 is an example of the "information terminal" of the present invention.

The blood pressure monitor 60 includes a main body 61, a cuff 62, and an air tube 63. The main body 61 is connected to a cuff 62 via an air tube 63. The main body 61 uses the cuff 62 to measure the user's blood pressure by, for example, an oscillometric method.

The main body 61 includes a pedestal 64 and a measurement start switch 65. The pedestal 64 is an example of the "holding member" of the present invention. The pedestal 64 is a portion of the main body 61 on which the smartphone 70 can be installed. By installing the smartphone 70 on the pedestal 64, the smartphone 70 is held in a preset specific posture. As described above, the specific postures include, for example, a posture in which the touch panel 71 of the smartphone 70 is face down, a posture in which the touch panel 71 is tilted in the front-back direction, a posture in which the smartphone 70 is upside down, and a posture in which the bottom surface of the touch panel 71 is not horizontal. Posture, etc.

The pedestal 64 includes a bottom portion 64a, a leaning surface 64b, and an anti-slip portion 64c. The bottom part 64a can place the side part of the smartphone 70, and supports the placed smartphone 70 from below (in the direction of gravity). The leaning surface 64b is a surface that is adjacent to the bottom portion 64a and extends in a direction intersecting the bottom portion 64a, and is capable of leaning the smartphone 70 placed on the bottom portion 64a. Further, the leaning surface 64b is inclined with respect to the vertical direction, and supports the smartphone 70 obliquely. The anti-slip portion 64c is a portion adjacent to the bottom portion 64a on the opposite side of the leaning surface 64b and protrudes upward. The anti-slip portion 64c prevents the smartphone 70 from sliding on the bottom portion 64a and the leaning surface 64b.

For example, the smartphone 70 can be placed vertically on the base 64 so that the side portion extending in the short direction of the smartphone 70, which is a roughly rectangular plate-like shape, contacts the bottom portion 64a of the base 64. The smartphone 70 can also be placed horizontally on the base 64 so that the side portion extending in the long direction of the smartphone 70 contacts the bottom portion 64a of the base 64. The base 64 can hold the smartphone 70 still in a specific position by placing the smartphone 70 on the bottom portion 64a of the base 64 and leaning it against the leaning surface 64b.

The measurement start switch 65 is a press-down switch that receives an instruction to start blood pressure measurement by the blood pressure monitor 60. Although not shown, the pedestal 64 may be provided with a display unit (for example, a liquid crystal display) that can display the results of blood pressure measurement by the blood pressure monitor 60. The display section may be provided, for example, on the leaning surface 64b of the pedestal 64.

The smartphone 70 is an information terminal capable of communicating with the blood pressure monitor 60. The smartphone 70 also includes a touch panel 71 capable of displaying the blood pressure measurement results obtained by the blood pressure monitor 60.

FIG. 9 is a diagram showing an example of a state in which the smartphone 70 is installed on the pedestal 64 of the blood pressure monitor 60. As shown in FIG. 9, the smartphone 70 is placed vertically with respect to the pedestal 64 of the blood pressure monitor 60, with the side portion extending in the lateral direction of the smartphone 70 touching the bottom portion 64a, and the touch panel 71 is placed backward (on the back). The touch panel 71 is tilted and placed in such a position that the bottom surface of the touch panel 71 is horizontal. In this example, it is assumed that this posture is set as the specific posture of the smartphone 70. When the smartphone 70 is placed on the pedestal 64 of the blood pressure monitor 60 in a specific posture, the smartphone 70 receives the blood pressure measurement results measured by the blood pressure monitor 60 from the blood pressure monitor 60 and displays the received blood pressure measurement results on the touch panel 71. do.

§5 Operation example <Operation example of the information management system 200>
Next, an example of the operation of the information management system 200 will be described with reference to FIG. 10. FIG. 10 is a sequence diagram showing the operations of the blood pressure monitor 60 (measuring device) and the smartphone 70 (information terminal) in the information management system 200.

It is assumed that the blood pressure of the user is measured by the blood pressure monitor 60, and the measurement result is stored in the data storage unit 17 of the blood pressure monitor 60 as the user's management measurement information. It is assumed that the user is near the blood pressure monitor 60 while carrying the smartphone 70 in order to collect the user's management measurement information stored in the blood pressure monitor 60 .

First, the blood pressure monitor 60 starts scanning during central operation (step S31).

Next, assume that the touch panel 71 of the smartphone 70 is operated by the user and the health management application of the smartphone 70 is started (step S32). The sensor 53 detects whether the smartphone 70 is installed on the pedestal 64 of the blood pressure monitor 60, that is, whether the smartphone 70 is stationary in a specific posture (step S33). As explained in FIG. 9, the smartphone 70 is installed on the pedestal 64 in a vertical position with the lateral side of the smartphone 70 in contact with the bottom 64a, and the touch panel 71 is placed backwards (on the back). This means that the touch panel 71 is tilted and placed in a position where the bottom surface of the touch panel 71 is horizontal. Next, the smartphone 70 starts scanning during central operation (step S34).

Next, when the smartphone 70 operates as a peripheral, it transmits an advertisement signal including a beacon signal instructing a transition to pairing mode at a predetermined transmission cycle (step S35).

Next, when the blood pressure monitor 60 scans during central operation and receives an advertisement signal including a beacon signal, it stops scanning (step S36). Next, during peripheral operation, the blood pressure monitor 60 transmits an advertisement signal including a transmission/reception signal for transmitting and receiving management measurement information at a predetermined transmission cycle (step S37). The blood pressure monitor 60 transmits an advertisement signal including the name and attribute information of the weight and body composition monitor 1A.

Next, the smartphone 70 scans and receives an advertisement signal from the blood pressure monitor 60 during the central operation. Next, the smartphone 70 transmits a connection request signal requesting communication connection during peripheral operation (step S38). The smartphone 70 transmits a connection request signal including the name and attribute information of the smartphone 70.

Next, when the blood pressure monitor 60 receives a connection request from the smartphone 70, it switches to one-to-one connection communication with the smartphone 70. As a result, the blood pressure monitor 60 and the smartphone 70 are connected via BLE. Next, the blood pressure monitor 60 transfers the user's management measurement information to the smartphone 70 via BLE communication (step S39). Next, when the smartphone 70 finishes receiving the management measurement information, it transmits a disconnection request signal requesting disconnection of BLE communication to the blood pressure monitor 60 (step S40). The blood pressure monitor 60 that has received the disconnection request disconnects the BLE connection with the smartphone 70, thereby ending communication between the two.

As explained above, according to the information management system 200, the smartphone 70 transmits a beacon signal when the smartphone 70 is stopped in a specific posture. Therefore, the blood pressure monitor 60 and the smartphone 70, which are legitimate communication partners, can be paired without the user performing any special operations (for example, pressing and holding the communication button). Wireless communication can be performed with 70.

In addition, according to the information management system 200, the smartphone 70 can be held in a specific position by the base 64. This allows the smartphone 70 to be reliably held still in a specific position, and the blood pressure monitor 60 and the smartphone 70, which are both valid communication partners, can be paired, making BLE communication even more reliable.

Further, according to the information management system 200, the smartphone 70 can be held still in a specific posture by the pedestal 64 provided on the blood pressure monitor 60. Thereby, the blood pressure monitor 60 and the smartphone 70, which are legitimate communication partners, can be paired more reliably, and BLE communication can be performed.

§6 Program The method for controlling the measuring device 1 or the information terminal 5 described in the above-described embodiments can be realized by executing a control program prepared in advance on a computer. This control program is recorded on a computer-readable storage medium, and is executed by being read from the storage medium. Further, this control program may be provided in a form stored in a non-transitory storage medium such as a flash memory, or may be provided via a network such as the Internet. The computer that executes this control program may be included in the measuring device 1 or the information terminal 5, or may be an electronic device such as a smartphone, a tablet terminal, or a personal computer that can communicate with the measuring device 1 or the information terminal 5. It may be included in the measuring device 1, the information terminal 5, and the server device that can communicate with the electronic device.

Although the embodiments of the present invention have been described in detail above, the above description is merely an illustration of the present invention in all respects. Various improvements and modifications can be made without departing from the scope of the invention.

1 Measuring device 1A Weight body composition meter 1B Blood pressure monitor 5 Information terminal 13 Measuring unit 14 Wireless communication unit 18 Controller (control unit, processor)
53 Sensor 54 First wireless communication section 55 Second wireless communication section 58 Controller 60 Blood pressure monitor 61 Main body 64 Pedestal 64a Bottom section 64b Standing surface 64c Anti-slip section 70 Smartphone 71 Touch panel 90 Cloud server 100, 200 Information management system N Wide area network

Claims (9)

An information terminal that transmits a beacon signal,
A measuring device, comprising a wireless communication unit that performs wireless communication with the information terminal, and transmits an advertisement signal for the wireless communication when the wireless communication unit receives the beacon signal;
system containing. 2. The system of claim 1,
The measurement device transmits the advertising signal when the reception strength of the beacon signal satisfies a first condition.
system. 3. The system according to claim 2,
The first condition is that the change in the reception strength has become a first pattern.
system. 4. The system according to claim 3,
The information terminal provides a notification urging the user to change the positional relationship of the information terminal with respect to the measurement device in a second pattern,
The second pattern is a pattern in which the change in the received strength is the first pattern,
system. The system according to claim 1,
The information terminal transmits the beacon signal when detecting that the information terminal is stationary in a specific posture.
system. 6. The system according to claim 5,
including a holding member that holds the information terminal in the specific posture;
system. 7. The system according to claim 6,
the holding member is provided in the measuring device;
system. a wireless communication section that performs wireless communication with the information terminal;
a control unit that causes the wireless communication unit to transmit an advertisement signal for the wireless communication when the wireless communication unit receives a beacon signal from the information terminal;
A measuring device comprising: A control program for a measuring device including a wireless communication unit that wirelessly communicates with an information terminal,
a processor of the measuring device;
when the wireless communication unit receives a beacon signal from the information terminal, causing the wireless communication unit to transmit an advertisement signal for the wireless communication;
A control program for executing processing.

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