TWM501832U - Portable health measurement management system featuring wireless transmission - Google Patents

Description

Portable health measurement management system with wireless transmission

This creative department is related to health management. In more detail, it refers to a portable health measurement management system with wireless transmission.

Due to the changes in the socio-economic structure and the changes in the way of life of the Chinese people, chronic diseases have replaced acute infectious diseases as the main diseases affecting the health of Chinese people. Among them, hypertension, diabetes and obesity are diseases causing cerebrovascular, cardiovascular and dyslipidemia and death. Important reasons, and the study found that the incidence of chronic diseases has a tendency to increase year by year. Therefore, the early detection of early treatment of preventive medicine has become an important task in the prevention and treatment of chronic diseases. However, the modern social environment and economic pressure make the people ignore regular health checkups and self-care. The symptoms of the early stages of chronic diseases are not obvious. It is often until the body appears abnormally that they rush to the hospital for medical treatment and cannot achieve the purpose of preventive medicine.

In response to the above problems, many medical personnel will set up some simple physiological measuring devices in remote towns and villages, schools at all levels, community groups and even medical institutions to facilitate the measurement of the population, and these basic physiological measurement data are judged by individuals. Important data on health status to achieve preventive medicine.

However, under the concept of preventive medicine, how to transmit personal measurement data to a device to which a person belongs to record a physiological state trajectory, or to collect or analyze a specific unit is a development trend of preventive medicine and a problem to be solved. Now technology is getting better and deeper into people's daily lives, smart phones and tablets The brain is already a mobile communication device used in daily life. How to use such electronic devices as a medium for health management is the subject of creation.

The main purpose of this creation is to provide a portable health measurement management system, which utilizes wireless transmission of the subject's mobile device, identification device and physiological measurement device, and can conveniently perform physiological tests on the subject. Measure and pass this value back to the mobile device or cloud for recording physiological state trajectories or for specific units to collect or analyze.

A health measurement management system provided by the present invention comprises: a mobile device, and a short-distance communication module; at least one identification device, each of the identification devices includes: an identification unit, the identification unit has a short distance a communication module, wirelessly connected to the short-range communication module of the mobile device; at least one measurement device; the identification device and the measurement device can be wirelessly connected; and the portable health measurement management system has a transmission data a mode and a receiving data mode; when the health measurement management system is set to receive the data mode, the identification device can receive the measurement information of the measurement device and transmit the measurement information to the mobile device; the health measurement management system is configured to transmit In the data mode, the measurement device transmits measurement information to other devices.

With the system of the creation, the subject can obtain the physiological information measured by the measuring device through the simple operation of connecting the mobile device and the identification device, and the measured physiological information passes through the measuring device. The transmission device transmits to the mobile device or the backend device to manage the physiological information of the subject.

Preferably, the mobile device has a user identification code; in the transmission data mode, the physiological information transmitted by the measurement device includes the user identification code.

Preferably, the transmission data mode and the received data mode are set in the mobile device or are provided in the identification device. The two modes are switched by an application installed on the mobile device or the identification device.

The health measurement management system provided by this creation can be used and moved in various occasions to improve the use level of physiological testing.

10, 10'‧‧‧Health Measurement Management System

20‧‧‧Mobile equipment

22‧‧‧Mobile App

24‧‧‧Short-range communication module

26‧‧‧Mobile wireless module

30‧‧‧ Identification equipment

31‧‧‧Processing unit

32‧‧‧ Identifying unit

321‧‧‧Short-distance communication module

322‧‧‧Wireless RF Reader Module

34‧‧‧ Front-end wireless module

36‧‧‧Display unit

38‧‧‧Input/output unit

39‧‧‧Power Module

40 (40a to 40g) ‧‧‧measuring equipment

41‧‧‧Connectors

43‧‧‧Measurement wireless module

44, 44’‧‧‧Electronic label

45‧‧‧Measure wireless transmitter

451‧‧‧ plug

50‧‧‧ Back-end equipment

52‧‧‧First Backend Wireless Module

54‧‧‧Second backend wireless module

56‧‧‧Back-end platform

A, B‧‧ path

In order to enable the review board to further understand the purpose, features and efficacies of the present invention, a number of preferred embodiments of the present invention will be described below in detail with reference to the drawings: System diagram of an embodiment.

The second figure is an architectural block diagram of the identification device of the first preferred embodiment of the present invention.

The third figure is a system diagram of a second preferred embodiment of the present creation.

The fourth figure is a schematic diagram of the connection of the measuring device and the measuring wireless transmitter of the second preferred embodiment of the present invention.

Please refer to the first figure, which is a first preferred embodiment of the portable health measurement management system 10 with wireless transmission provided by the present invention, comprising: a mobile device 20, one or more identification devices 30 And the multi-quantity measuring device 40, the identification device 30 and the mobile device 20 of the present invention use the technology of near field communication to transmit information such as a user ID (measurement ID) or measurement data of the subject, and the identification The device 30 and the measuring device 40 use radio frequency identification to pair and transmit data, so as to achieve the purpose of health measurement management for the subject.

The mobile device 20 is a mobile gateway. In this embodiment, it is a mobile communication device such as a smart phone or a tablet (not limited thereto), and has a built-in or download-installed device. The mobile application 22 can set the mobile device 20 to a data transfer mode or a receive data mode. The mobile device 20 also has a short-range communication module 24 and a mobile wireless module 26. The two modules 24 and 26 are connected to the mobile device 20 and can be connected to each other to transmit signals. The short-range communication module In this embodiment, the group 24 uses the technology of Near Field Communication (NFC). The mobile device 20 has a user identification code, which can be a card number of a user identity module (SIM, Subscriber Identity Module, SIM card) of the test subject's mobile phone, or a network operator (for example, Google, Yahoo, Face Book, Twitter, Line), web server, user account registered in the cloud to establish and confirm the identity of the user, as long as the identification code, serial number or identity code of the user identity can be confirmed. Can be used as the user ID of this creation. The mobile wireless module 26 is a Bluetooth (BLE) 4.0 wireless module and/or a 3G, 4G wireless module and/or a WiFi wireless module, which can receive or transmit data, and can be a self-close communication module. The 24 received data is uploaded to the cloud.

Referring to the second figure, each of the identification devices 30 is a card reader (but not limited thereto), and can read information in the mobile device 20 such as a smart phone or a tablet. The processing unit 31 includes an execution core of the identification device 30. The recognition unit 32 includes a short-range communication module 321 and a radio frequency identification (RFID) reading module 322; Front end (nRF) wireless module 34. The short-range communication module In this embodiment, a near field communication (NFC) technology is used, which can be wirelessly connected to the short-range communication module 24 of the mobile device 20 and transmitted in both directions (transmitting and receiving). When the mobile device 20 and the identification device 30 are in a wireless connection state through the short-range communication module 24 and the short-range communication module 321 (hereinafter referred to as NFC connection), the mobile device can transmit the data to the identification device through the NFC connection or The instruction to receive the data is used to transmit the user identification code or the measurement data of the aforementioned measuring device 40. In addition, the radio frequency reading module 322 of the identification unit 32 is for pairing with the measuring device 40 (to be described below). In the embodiment, the front-end (nRF) wireless module 34 is a two-way (transceived) 2.4G nRF wireless module, which can wirelessly transmit a user identification code or receive measurement data. The identification device 30 further includes: a display unit 36, which is an electronic display screen or a liquid crystal display screen (LCD, LED), which can display information or numerical values; an input/output unit 38, which can be a button to control the identification The various functions of the device 30; a power module 39 that provides the power required by the identification device 30. Each of the above modules and units is connected to the processing unit 31 to perform related operations.

The multi-quantity measuring device 40, for example, three sphygmomanometer devices 40a, 40b, 40c, three blood glucose meter devices 40d, 40e, 40f and a weight device 40g, etc., may also measure the pulse, blood oxygen, etc. Various measuring equipment. The measuring device 40 can perform various physiological measurements on the subject and generate measurement data. In the present specification, the component symbol 40 is a collective symbol of the measuring device, and the component symbols 40a to 40g are symbols of a specific measuring device. Each measurement device 40 has a built-in measurement (nRF) wireless module 43 and an electronic tag 44 therein. The measurement radio module 43 is a 2.4G nRF radio module in the embodiment, and can be wirelessly transmitted. The electronic tag 44 is a radio frequency tag (RFID tag) in the embodiment, and the measurement device is recorded. Device information, such as a device identification code (ID number of the device), the device identification code is the exclusive number and/or device information of the matching measurement device 40 for identification The specific measurement device, for example, the electronic tag 44 of the first sphygmomanometer device 40a, records the identification code of the sphygmomanometer 40a. The electronic tag 44 also records the communication protocol of the measurement wireless module 43. It should be noted that the electronic tag 44 is not limited to being built in the measuring device 40, and may be externally attached to the measuring device 40, for example, attached to the outer casing of the measuring device 40.

The following describes the state of use of the present creation. Referring to the first figure, the user selects a measuring device 40 for physiological measurement, and can select the result of the measurement to be transmitted back to the mobile device 20 or transmitted to the backend device by other paths. Or the cloud.

The blood pressure is measured by the subject with the first sphygmomanometer device 40a, and the result of the measurement is to be transmitted back to his mobile device (for example, a mobile phone) 20 as an example. When the mobile device 20 receives the measurement result, the mobile device 20 is switched to the received data mode by the mobile application 22, and the identification device 30 is paired with the first sphygmomanometer device 40a. When pairing, the radio frequency reading module 322 of the identification unit 32 of the identification device 30 senses the electronic tag 44 of the first sphygmomanometer device 40a to obtain the device identification code of the sphygmomanometer 40a and the sphygmomanometer. The communication protocol of the wireless module 43 is measured by the 40a, and the communication protocol is transmitted to the front-end wireless module 34 via the identification unit 32, so that the front-end wireless module 34 has the same or the same communication with the measurement wireless module 43. It is agreed that the identification device 30 and the sphygmomanometer 40a directly complete the wireless connection, and the identification device 30 also obtains the device identification code of the sphygmomanometer 40a, and completes pairing with the sphygmomanometer 40a to perform wireless transmission of information.

The user brings the mobile device 20 close to the identification device 30, so that the short-range communication module 24 and the short-range communication module 321 complete the NFC connection. In the receiving data mode, the mobile device 20 issues a command to the identification device 30 to accept the data, so that the identification device receives the measurement result. In detail, the subject measures blood pressure by the sphygmomanometer 40a, and the measured physiological value is transmitted to the measurement wireless module 43 via an internal circuit. After receiving the instruction to receive the data, the identification device 30 passes through the front end without The line module 34 and the measurement path A of the measurement wireless module 43 receive the measured data, and transmit the measurement data to the short-distance communication module 321 of the identification unit 32 via the internal line, and transmit the data through the NFC connection. Give the mobile device 20. The subject can store the measurement result in the mobile device 20. In this way, the subject understands the physiological condition of the mobile device 20 to determine the health management plan; the test subject can also use the mobile wireless module 26 of the mobile device 20 to upload the measurement result to the cloud, so that the other The platform can obtain test information of the subject for evaluation and analysis.

If the user wants to transmit the physiological measurement result to the backend device 50 or the cloud, the mobile device 20 is set to the transmission data mode by the mobile application 22, and at this time, the mobile device 20 is paired with the identification device 30. Under the command of transmitting data, the user identification code (UID) of the mobile device 20 is transmitted to the identification unit 32 of the identification device 30 via the NFC connection, and the front-end wireless module 34 transmits the user identification code to the measurement. The device (sphygmomanometer 40a), after the sphygmomanometer 40a completes the measurement, the command to transmit the data drives the measuring device (the sphygmomanometer 40a) to pass the measurement result together with the user identification code (UID) through the measurement wireless module 43. Path B is transmitted to the backend device 50. The user identification code of the subject and its physiological measurement information are transmitted together, so there is no confusion.

The user identification code (UID) can be transmitted to the identification device through the NFC after the mobile device 20 and the identification device 30 are NFC-connected. Alternatively, after the NFC is connected to the mobile device 20, the two devices 20 and 30 perform an instruction to transmit the user identification code to the identification device 30. The transmission timing and protection of the UID code can be varied, and is not limited to the description herein.

When the mobile device 20 is set to the transfer data mode, the measurement information and the user identification code measuring device 40 are transmitted to a backend device 50, such as a gateway or a set-top box. The backend device 50 can also be used to upload the measurement data to the cloud or to the mobile device 20. The back end of this embodiment The device 50 has a first backend (nRF) wireless module 52 (eg, a 2.4G nRF wireless module) and a second backend (BLE/WiFi) wireless module 54 (eg, Bluetooth 4.0 or WiFi wireless module). And a back-end platform 56; the first back-end wireless module 52 can receive and manage the user identification code and measurement data of the subject from the measurement device 40, and can further transmit the data to the back-end platform 56. Or receiver. The back end platform 56 is, for example, a customer, a framework, a database, a storage medium, a hardware device, or a driver that can initiate a certain function. The network system may be a network platform set up by a specific institution, such as a medical institution, a health management company, a sports and leisure center, a community, a school, a public institution, or an enterprise, for collecting, analyzing, and managing measurement. The second back end (BLE/WiFi) wireless module 54 can also receive the user identification code and the measurement data of the subject from the back end platform 56, and transmit the information to the mobile device 20, so that Subjects can view and understand their own physiological conditions.

The first back-end wireless module 52 of the back-end device 50 can simultaneously receive data transmitted by the plurality of measurement wireless modules 43 to achieve the purpose of multiple people simultaneously using different measuring devices 40 for physiological measurement. , not due to multiple data transmission at the same time, resulting in data transmission delay or waiting.

Please refer to the third and fourth figures, which are the second preferred embodiment of the health measurement management system 10' provided by the present invention. The same components follow the same symbols, and the difference in this embodiment is: a multi-quantity measuring device 40, each The measuring device 40 is provided with an external measuring wireless module. Each measuring device 40 has a connector 41; the external measuring wireless module is a measuring wireless transmitter 45, which is a 2.4G nRF Dongle in this embodiment, can provide wireless transmission, and has an electronic built-in The tag 44' records the device identification code of the measuring device and the communication protocol of the transmitter 45. One end of the measurement wireless transmitter 45 has a plug 451, and the plug 451 is plugged into the associated After the connector 41 of the measuring device 40 is plugged in, the measurement wireless transmitter 45 and the measuring device 40 transmit data by using a non-synchronous transmission (UART) interface, so that the measurement information of the measuring device can be transmitted to The wireless transmitter 45.

Each measurement device 40 is plugged into a dedicated measurement wireless transmitter 45. The identification device 30 senses the device identification code recorded by the electronic tag 44' and the communication protocol of the measurement wireless transmitter via the radio frequency reading module 322 of the identification unit 32, thereby enabling the front end wireless module 34. The wireless connection is directly completed with the measurement wireless transmitter 45, and the identification device 30 is paired with the measurement device 40, such as the sphygmomanometer 40a.

When the user performs physiological measurement, when the mobile device 20 is set in the receiving data mode, the measured data of the test subject transmits the measured data to the wireless transmitter 45 through the measuring device 40 via the path A to the measurement device 40. The front end wireless module 34 transmits the measurement data to the short-range communication module 321 through the internal circuit, and transmits the measurement data to the mobile device 20 by using the NFC connection. The subject is informed about his or her physiological condition and can be uploaded to the cloud for collection or analysis by a specific unit. When the mobile device 20 is set in the transmission data mode, the user identification code of the subject is transmitted to the measurement wireless transmitter 45 through the front wireless module 34 of the identification device 30. When the blood pressure meter performs measurement, The measured physiological values are transmitted to the measurement wireless transmitter 45. The measurement wireless transmitter 45 receives the user identification code of the test subject and the measurement value of the measurement device 40, and then wirelessly transmits the measurement result to the first back end wireless module 52 of the back end device 50 via the path B, so that the measurement The backend device 50 manages the physiological information of the subject, and can upload relevant information to the cloud or to the mobile device 20.

The creation of the health measurement management system can be applied to various occasions and environments, such as collective health check, which is for the elderly or high-risk rickets, through the basic physiological test data, can monitor its health, and will Data It is transmitted to medical personnel in the cloud to judge or monitor whether the physiological state of the subject is different or not, and achieve the purpose of preventive medicine.

This creation can also be applied to community health checks, community care functions, and regular physiological measurements in rehabilitation and fitness settings. Taking the community as an example, today's mobile devices 20 (such as mobile phones or tablets) are becoming more and more popular. When the community is performing physiological measurements, the mobile device 20 and the identification device 30 can be used for user identification. After the measurement is completed, The measurement data is transmitted back to each of the mobile devices 20, or a back-end device 50 is used. The first back-end wireless module 52 of the back-end device 50 is a multiplexed module, and the measurement can be performed. The device 40 simultaneously measures most of the subjects to speed up the overall measurement speed; the school's health room, medical institution, and company can also use this creation to measure most of the objects at the same time, and measure the physiology for each object. The values are immediately transmitted to the mobile device 20 or the backend platform 56. The identification device and measuring device of the creation are movable, which improves the convenience of measurement. After obtaining the measurement data, it can be used for regular management and analysis of health management. The specific institution knows the physiological condition of the subject, and can immediately judge whether the physiological state of the subject is within the safe range or beyond the normal range. If further examination is required, then go to the medical institution for further testing. People who do not need a boat trip to and from the hospital can enjoy simple regular health checks and improve the effectiveness of preventive medicine.

Under the technology of the first or second preferred embodiment, the author can also set the mobile application (APP) to the identification device 30 so that the identification device can switch to the transmission data mode or the receiving data mode. After the mobile device 20 and the identification device 30 are connected to the NFC, the identification device 30 is set to a transmission data mode, and the user identification code and the measurement data are measured by the measurement device 40 or the external device. The measurement wireless module (measurement wireless transmitter 45) transmits to the backend device 50; in the received data mode, the identification device 30 receives the measurement data of the measurement device 40 and transmits it back to the mobile device 20.

Furthermore, the short-range communication module and the short-range communication module can also be a wireless radio frequency module capable of bidirectional transmission.

The above embodiments are merely illustrative of the spirit of the present invention and not limiting. The health measurement management system provided by this creation can easily complete the daily management of users, regular tracking and even the health measurement management of medical services through the mobile devices used in life. It is the first technology in this technology field. And with the improvement of practical effects, 提出 apply in accordance with the law.

10‧‧‧Health Measurement Management System

20‧‧‧Mobile equipment

22‧‧‧Mobile App

24‧‧‧Short-range communication module

26‧‧‧Mobile wireless module

30‧‧‧ Identification equipment

32‧‧‧ Identifying unit

321‧‧‧Short-distance communication module

322‧‧‧radio frequency identification reading module

34‧‧‧ Front-end wireless module

40 (40a to 40g) ‧‧‧measuring equipment

43‧‧‧Measurement wireless module

44‧‧‧Electronic label

A, B‧‧ path

Claims (12)

A portable health measurement management system with wireless transmission includes: a mobile device, a short-range communication module; one or more identification devices, each of the identification devices includes: an identification unit and a front end a wireless module; the identification unit has a short-distance communication module, and is wirelessly connected with the short-range communication module of the mobile device; the identification unit and the front-end wireless module can transmit information; one or more measurements The device, each measuring device comprises: a measuring wireless module; the wireless module of the front end of the identifying device is wirelessly connected with the measuring wireless module of the measuring device; and the portable health measurement management The system has a transmission data mode and a receiving data mode; when the health measurement management system is set to receive the data mode, the identification device can receive the measurement information of the measurement device and transmit the measurement information to the mobile device; the health measurement When the management system is set to transmit data mode, the measurement device transmits measurement information to other devices. The health measurement management system of claim 1, wherein: the mobile device has a user identification code; and when the portable health measurement management system is configured to transmit a data mode, the user identification code is The mobile device transmits to the identification device and transmits the measurement device to the measurement device; the measurement device transmits the measurement information and the user identification code to other devices. The health measurement management system of claim 1, wherein: the transmission data mode and the received data mode are set in the mobile device or the identification device. The health measurement management system of claim 2, wherein the transmission data mode and the received data mode are set in the mobile device or the identification device. The health measurement management system of claim 2, wherein: the user identification code is transmitted by the short-range communication module of the mobile device to the identification device. The distance communication module is transmitted by the front end wireless module to the measurement wireless module. The health measurement management system according to any one of claims 1 to 5, wherein the health measurement management system switches the transmission data mode and the reception data mode by an application. The health measurement management system according to any one of claims 1 to 5, wherein the short-range communication module of the mobile device and the short-range communication module of the identification unit are technologies for near field communication. The health measurement management system according to any one of claims 1 to 5, wherein the short-distance communication module of the mobile device and the short-range communication module of the identification unit are two-way wireless radio frequency modules. The health measurement management system according to any one of claims 1 to 5, wherein each of the measurement devices comprises: an electronic tag, a communication protocol of the measurement wireless module is recorded; and the identification unit of the identification device The communication protocol recorded by the electronic tag can be obtained, so that the identification device and the measuring device can be wirelessly connected. The health measurement management system of claim 9, wherein the electronic tag is an electronic tag for radio frequency identification; the identification unit comprises a radio frequency identification reading module, and the electronic tag is wirelessly sensed. The health measurement management system according to any one of claims 1 to 5, further comprising: a back-end device having at least a first back-end wireless module for performing data transmission with the measurement wireless module. The health measurement management system of claim 11, wherein the mobile device further comprises a mobile wireless module.