TWM562102U - Cloud physiological data collection system - Google Patents

Abstract

The present invention is a cloud physiological data collection system that collects a physiological data of a user in an area, and includes an identification module, a receiving module and a remote module. The identification module is worn by the user for transmitting the physiological data and the first module code. The receiving module provides a communication range to cover at least a part of the area, receives the physiological data and the first module code in the communication range, and transmits a data including the physiological data, the first module code and the second module code. Packet. The remote module receives the data packet and the analysis data packet to determine the identity and location of the user according to the first module code and the second module code, and uses the physiological data to confirm the physiological state of the user.

Description

Cloud physiological data collection system

This creation is about the technical field of big data, especially a cloud physiological data collection system that judges the physiological state of a user in a range.

Traditionally, the collection of physiological data is only at the user end, for example, data is collected in mobile devices, and only statistics and presentation of simple data.

With the popularity of the Internet, the aforementioned data is also transmitted to the cloud, but only used across platforms or devices.

In view of this, this creation proposes a cloud physiological data collection system to innovate a new data collection system.

The first object of the present invention provides a cloud physiological data collection system, comprising an identification module, a receiving module and a remote module, which are capable of collecting physiological data of a user in an area to manage the user. Physiological state.

The second object of the present invention provides the aforementioned cloud physiological data collection system, which can further adjust the judgment threshold of physiological data according to a specific region to avoid misjudgment.

The third object of the present invention provides the aforementioned cloud physiological data collection system, which can expand the range of the detection area by the bridge module to achieve rapid deployment and low power consumption.

The fourth object of the present invention provides the aforementioned cloud physiological data collection system, wherein the receiving module can be embedded in an object to use the original power supply loop of the object to reduce or eliminate the complexity of the configuration line cost and construction.

The fifth object of the present invention provides the aforementioned cloud physiological data collection system, wherein the remote module can transmit a feedback signal to drive the identification module for prompting the user.

For the above purposes and other purposes, the present invention provides a cloud physiological data collection system for collecting a physiological data of a user in an area. The cloud physiological data collection system includes an identification module, a receiving module and a remote End module. The identification module is intended to be worn by the user. The identification module includes a detecting unit and a first communication unit. The identification module has a unique first module code. The detecting unit is configured to detect physiological data of the user, and the first communication unit transmits the physiological data and the first module code. The receiving module includes a second communication unit. The receiving module has a unique second module code. The second communication unit forms a communication range to cover at least a portion of the area. The physiological data and the first module code are received within the communication range, and the second communication unit transmits a data packet including the physiological data, the first module code, and the second module code. The remote module includes a third communication unit and a processing unit. The third communication list receives the data packet. The processing unit analyzes the data packet to determine the identity and location of the user according to the first module code and the second module code, and uses the physiological data to confirm the physiological state of the user.

In order to fully understand the purpose, features and effects of this creation, the following specific examples, together with the attached drawings, provide a detailed description of the creation, as explained below:

Please refer to FIG. 1 , which is a block diagram of a cloud physiological data collection system according to a first embodiment of the present invention. In FIG. 1, the cloud physiological data collection system 10 collects a physiological data BD of a user 2 in a region A. The physiological data BD may include, for example, body temperature, heart rate, ambient temperature, humidity, blood pressure, number of steps, and the like, and the area A may be an indoor field or an outdoor field, such as a kindergarten, a campus, a store, a hospital, and the like.

The cloud physiological data collection system 10 includes an identification module 12, a receiving module 14 and a remote module 16.

The identification module 12 can be, for example, a wristband, a watch, an accessory, a badge, a pin, or a jewelry. The identification module 12 can be worn on a body part of the user 2, such as a hand, a neck or a foot. The identification module 12 has a detecting unit 122 and a first communication unit 124. The identification module 12 has a unique first module code FMC, such as a MAC code, a custom code, and the like. The detecting unit 122 can detect the physiological data BD of the user 2, and the detecting unit 122 can be, for example, a temperature sensor, a light source sensor, a gyroscope, etc., for detecting (or sensing) the physiology of the user 2. data,. The first communication unit 124 transmits the physiological data BD and the first module code FMC.

The receiving module 14 includes a second communication unit 142. For example, the receiving module 14 is embedded in a light fixture, a light bulb, a light tube, a fan, a broadcaster, a blackboard, and the like. The receiving module 14 also has a unique second module code SMC. The second communication unit 142 has a communication range CR to cover at least a portion of the area A. The physiological data BD and the first module code FMC are received in the communication range CR. The second communication unit 142 transmits a data packet DP including the physiological data BD, the first module code FMC, and the second module code SMC.

The remote module 16 includes a third communication unit 162 and a processing unit 164. The third communication list 162 receives the data packet DP. The processing unit 164 analyzes the data packet DP to determine the identity of the user 2 and the area A in which it is located based on the first module code FMC and the second module code SMC, and confirms the physiological state of the user 2 using the physiological data BD. Among them, the physiological state can be normal, abnormal or to be determined. For example, whether the blood pressure is normal, whether the heartbeat is normal, whether the mood/mood is normal, and the like. In another embodiment, the remote module 16 further includes a storage unit (not shown). The storage unit may store a threshold associated with the second module code SMC, and cause the processing unit 164 to compare the value and the threshold of the physiological data BD to generate a normal signal, an abnormal signal or a to-be-observed signal. The equal signal can indicate the physiological state of the user 2. Wherein, the physiological data BD may be one or plural. If the physiological data BD is plural, the equal values may be respectively compared with the threshold, or the equivalent values may be calculated into a single integrated value (or index) and a valve. Value comparison.

The first communication unit 124, the second communication unit 142 and the third communication unit 162 are compatible with at least one of a wireless communication specification and a wired communication specification. The wireless communication specification may be, for example, Wireless Fidelity, Bluetooth, Zigbee, mobile communication (3G, 4G, LTE).

For example, in the kindergarten (formerly referred to as the area A), each child is wearing a bracelet (ie, the identification module 12), and the cloud physiological data collection system 10 (hereinafter referred to as the system) can pass through the bracelet. The detection unit detects the physiological data BD of each child in real time or periodically. Since the identification module 12 has a unique first module code FMC. Therefore, the system 10 can accurately know the identity of each child, that is, the system 10 can link the corresponding physiological data BD through the first module code FMC. Kindergartens may have many indoor or outdoor fields, such as indoor classrooms, toilets, health rooms, etc., or outdoor runways, cool areas, gates, etc. The kindergarten can be provided with a receiving module 14 in an indoor or outdoor field, which can be set, for example, in a light fixture, a blackboard, a walkway, a game facility/equipment, and the like. The receiving module 14 establishes (or forms) a communication range CR through the second communication unit 142, so that when the child's identification module 12 falls within the communication range CR, at least one of the physiological data and the first module code FMC will Received by the receiving module 14. It is worth noting that the receiving module 14 also has a unique second module code SMC. Therefore, the system 10 can accurately know the receiving module 14 at which place, that is, the system 10 can confirm the communication range A of each child through the second module code SMC, and in the communication range A. The physiological data of each child is BD. The receiving module 14 combines/combines/calculates the physiological data BD, the first module code FMC and the second module code SMC into a data packet DP, and further transmits the data packet DP to the remote module 16, such as a server. , monitoring terminal, server, etc. The remote module 16 receives the data packet DP by the third communication unit 162 and analyzes the data packet DP by the processing unit 164. According to the first module code FMC and the second module code SMC in the data packet DP, the child's identity and the area A can be determined, and the child's physiological data BD is obtained to confirm each child in the communication range CR. Physiological state.

It should be noted that the remote module 16 is aware of the location of each of the receiving modules 14 in the area A. Therefore, for the physiological state judgment of different communication range A, different threshold values can be provided to determine whether the physiological state is normal, abnormal or to be determined. For example, if the child is outdoors, it may be due to factors such as running and hot weather, so that the child's temperature and blood pressure should be higher than the temperature and blood pressure of the child who is active indoors. If the conditions are judged by the same conditions, There may be many misjudgments; however, through the creation of the system 10, different thresholds can be selected for different factors such as off-site and different time to accurately determine the physiological state of the child.

Please refer to FIG. 2, which is a block diagram of a cloud physiological data collection system according to a second embodiment of the present invention. In FIG. 2, the cloud physiological data collection system 10' includes a positioning unit 18 in addition to the identification module 12, the receiving module 14, and the remote module 16 of the first embodiment.

The positioning unit 18 can be disposed in the identification module 12, the receiving module 14, or both. The positioning unit 18 is illustrated as being disposed in the receiving module 14. The positioning unit 18 is capable of generating a location data PD, such as data of longitude, latitude, altitude, etc., and combining the data packets DP. The location data DP is related to the location of the identification module 12 or the receiving module 14. The remote module 16 can know, for example, the location of the identification module 12 or the receiving module 14 based on the location data DP in the data packet DP. The utility model has the advantages that when the receiving module 14 is installed, the definition of the receiving module 14 is not required in advance, and the actual position of the receiving module 14 can be determined by matching the image at the remote end, for example, the definition and setting can be saved. time.

Please refer to FIG. 3, which is a block diagram of a cloud physiological data collection system according to a third embodiment of the present invention. In FIG. 3, the cloud physiological data collection system 10'' includes a bridge unit 20 in addition to the identification module 12, the receiving module 14, and the remote module 16 of the first embodiment.

The bridging unit 20 is disposed between the receiving module 14 and the remote module 16 . The bridging unit 20 has a fourth communication unit 202, and the communication protocol can refer to the descriptions of the foregoing first to third communication units. The fourth communication unit 202 receives the data packet DP from the second communication unit 142 and transmits the data packet DP to the third communication unit 162. The purpose is to repeatedly transmit the data packet DP, thereby saving and speeding up the deployment of the line, and expanding the communication range CR (or area A).

Please refer to FIG. 4, which is a block diagram of a cloud physiological data collection system according to a fourth embodiment of the present invention. In FIG. 4, the cloud physiological data collection system 10''' includes the feedback unit 22 in addition to the identification module 12, the receiving module 14, and the remote module 16 of the first embodiment.

The feedback unit 22 can receive a feedback signal FS from the remote module 16 for prompting the user 2, for example, the feedback unit 22 can prompt the user 2 by means of sound, light, mechanical motion, vibration, etc., the purpose of which can be Interact with User 2. The feedback unit 22 can be set independently or embedded in the identification module 12 or the receiving module 14.

For example, if the remote module 16 determines the physiological state of the child, for example, the emotion is unstable, the remote module 16 can send a feedback signal FS from a distance, activate/drive the identification module 12 worn by the child, and issue, for example, Music, light, transform children's attention and mood.

The present invention has been disclosed in the above preferred embodiments, and it should be understood by those skilled in the art that the present invention is only intended to depict the present invention and should not be construed as limiting the scope of the present invention. It should be noted that variations and permutations equivalent to those of the embodiments are intended to be included within the scope of the present invention. Therefore, the scope of protection of this creation is subject to the definition of the scope of patent application.

2‧‧‧Users
10, 10', 10'', 10'''‧‧‧ Cloud Physiological Data Collection System
12‧‧‧ Identification module
122‧‧‧Detection unit
124‧‧‧First communication unit
14‧‧‧ receiving module
142‧‧‧Second communication unit
16‧‧‧ Remote Module
162‧‧‧3rd communication unit
164‧‧‧Processing unit
18‧‧‧ Positioning unit
20‧‧‧Bridge unit
202‧‧‧fourth communication unit
22‧‧‧Return unit
A‧‧‧ area
BD‧‧‧ Physiological data
FMC‧‧‧ first module code
SMC‧‧‧Second module code
CR‧‧‧Communication range
DP‧‧‧ data packet
PD‧‧‧Location Information
FS‧‧‧ feedback signal

FIG. 1 is a block diagram showing a cloud physiological data collection system according to a first embodiment of the present invention. 2 is a block diagram showing the cloud physiological data collection system of the second embodiment of the present invention. 3 is a block diagram showing a cloud physiological data collection system according to a third embodiment of the present invention. 4 is a block diagram showing a cloud physiological data collection system according to a fourth embodiment of the present invention.

Claims (10)

A cloud physiological data collecting system collects a physiological data of a user in an area. The cloud physiological data collecting system comprises: an identification module for being worn by the user, the identification module having a detecting unit and a first communication unit, the identification module has a unique first module code, the detecting unit is configured to detect the physiological data of the user, and the first communication unit transmits the physiological data and the first module a receiving module having a second communication unit, the receiving module having a unique second module code, the second communication unit having a communication range to cover at least a portion of the area, Receiving the physiological data and the first module code in the communication range, and the second communication unit transmitting a data packet including the physiological data, the first module code and the second module code; and a remote end The module has a third communication unit and a processing unit, the third communication unit receives the data packet, and the processing unit analyzes the data packet to determine according to the first module code and the second module code. User's identity with the region is located, and confirming the physiological state of the user by using the physiological data. The cloud physiological data collection system of claim 1, further comprising a positioning unit, wherein the positioning unit generates a location data, and the data packet is combined, wherein the location data is related to the identification module and the Receive the location of the module. The cloud physiological data collection system of claim 1, wherein the first communication unit, the second communication unit, and the third communication unit conform to at least one of a wireless communication specification and a wired communication specification. . The application Drive physiological data collection system according to item 3 of patentable scope, wherein the wireless communication standard as wireless fidelity (Wireless Fidelity), Bluetooth (the Bluetooth), Zigbee (Zigbee) communication with the at least one action. The cloud physiological data collection system of claim 1, wherein the receiving module is embedded in a light fixture, a light bulb, a light tube, a fan, a broadcaster or a blackboard, and the type of the identification module. The state is a hand ring, a watch, an accessory, a identification card, a pin or a piece of jewelry. The cloud physiological data collection system of claim 1, further comprising a bridge unit disposed between the receiving module and the remote module, the bridge unit having a fourth communication unit, the The fourth communication unit receives the data packet from the second communication unit and transmits the data packet to the third communication unit. The cloud physiological data collection system of claim 1, wherein the remote module further comprises a storage unit, wherein the storage unit stores a threshold associated with the second module code. The cloud physiological data collection system of claim 7, wherein the processing unit compares the value of the physiological data with the threshold to generate a normal signal, an abnormal signal or a to-be-observed signal for indication. The physiological state of the user, wherein the physiological data is one or plural. If the physiological data is plural, the values may be respectively compared with the threshold, or the values may be calculated into a single one. The combined value is compared to the threshold. The cloud physiological data collection system of claim 1, wherein the processing unit generates a normal signal, an abnormal signal or a to-be-observed signal according to the value of the physiological data for indicating the physiological condition of the user. status. The cloud physiological data collection system of claim 1, further comprising a feedback unit, wherein the feedback unit receives a feedback signal transmitted from the remote module for prompting the user.