TW201922166A - Physiological parameter acquiring device and physiological parameter monitoring device - Google Patents

Abstract

A physiological parameter acquiring device and a physiological parameter monitoring device are provided. The physiological parameter acquiring device includes a number of acquiring units configured to be selected to be attached to user's body to acquire physiological parameters. The selected acquiring units are attached to different positions of the user's body to acquire the physiological parameters of the user. The acquiring units further transmit the physiological parameters to the physiological parameter monitoring device via a wireless communication network. The physiological parameter monitoring device analyzes the physiological parameters and generates a monitor report.

Description

Physiological parameter collecting device and physiological parameter monitoring device

The invention relates to the field of medical equipment, in particular to a physiological parameter collecting device and a physiological parameter monitoring device for monitoring physiological parameters of a user.

With the development of medical technology, doctors can monitor the physiological parameters of patients through various physiological parameter monitoring devices to understand the patient's condition. However, the existing physiological parameter monitoring device is easy to make the patient feel uncomfortable due to the limitation of the hardware structure, thereby affecting the accuracy of the physiological parameter signal acquisition, and the measurement content is relatively fixed, and cannot be adjusted according to the detection needs. For example, dynamic electrocardiograph is widely used for the diagnosis and diagnosis of arrhythmia and myocardial ischemia in cardiovascular diseases. The dynamic electrocardiograph is also called a HOLTER recorder. The conventional HOLTER includes a mobile phone-sized recorder that is usually worn on the waist of the patient and a plurality of conductive sheets for attaching to the surface of the human body. The recorder is connected to continuously monitor the 12-lead ECG signal. However, the recorder and the lead wire cause great interference to the daily life of the patient, and there are often displacements in the work and rest to generate noise and adverse signal analysis and interpretation; at the same time, the number of conductive sheets and the lead position of the existing electrocardiograph are fixed, and the monitoring content is hard by the instrument. The limitation of the body makes it impossible to flexibly adjust the measurement content, which is inconvenient in use and wastes resources.

In view of this, it is necessary to propose a novel physiological parameter collecting device and a physiological parameter monitoring device to solve the above problems.

A physiological parameter collecting device comprises: a plurality of signal collecting units, wherein the user selects different numbers of signal collecting units to be attached to different positions on the body surface of the user according to different detection requirements to collect the physiological parameter signals of the user. And a wireless communication unit, disposed in each signal acquisition unit, configured to establish a wireless communication connection between the signal acquisition unit and a physiological parameter monitoring device, and send the physiological parameters collected by the signal acquisition unit to the user The physiological parameter monitoring device is configured to perform analysis and processing on the physiological parameter by the physiological parameter monitoring device to generate a physiological parameter monitoring report.

Preferably, the physiological parameter collecting device further includes a detecting unit disposed in each of the signal collecting units, wherein the detecting unit is configured to detect whether an abnormality occurs in the process of attaching the signal collecting unit to the surface of the user's body. And detecting an abnormal condition to be sent to the physiological parameter monitoring device by the first wireless communication unit when detecting that the signal acquisition unit is abnormal.

Preferably, the user physiological parameters collected by the signal acquisition unit include one or more of the following signals: an electrocardiogram signal, an electroencephalogram signal, a blood pressure signal, a blood oxygen saturation, and a respiratory signal.

A physiological parameter monitoring device is configured to perform wireless communication with a physiological parameter collecting device, wherein the physiological parameter collecting device comprises a plurality of information collecting units for the user to select different numbers of signal acquisitions according to different detection requirements. The unit is attached to different positions on the surface of the user's body to collect physiological parameters of the user. The physiological parameter monitoring device includes: a wireless communication unit configured to establish a wireless communication connection with a signal acquisition unit attached to a surface of the user body of the physiological parameter collection device, and receive a physiological parameter of the user collected by the signal acquisition unit; a processor, wherein the memory stores a plurality of program modules, the plurality of program modules are executed by the processor, and the plurality of program modules include: a data acquisition module, configured to acquire The user physiological parameter sent by the signal acquisition unit attached to the surface of the user's body; and the data analysis processing module for analyzing the signal acquisition unit attached to the surface of the user's body according to the received physiological parameter of the user The quantity and the physiological parameter values collected by each signal acquisition unit generate a corresponding monitoring report.

Preferably, the physiological parameter monitoring device is a wristband electronic device.

Preferably, the data acquisition module is further configured to receive an abnormal situation sent by the physiological parameter collection device, and the output module is further configured to output the abnormal condition to a user, thereby issuing a reminder to the user.

Preferably, the physiological parameter monitoring device further includes an input unit for inputting an alarm signal when the user feels physical discomfort, and the data acquisition module is further configured to acquire an alarm signal input by the user through the input unit. And record the time when the user inputs the alarm signal.

Preferably, the physiological parameter monitoring device further establishes a wireless communication connection with the at least one terminal device through the wireless communication unit, and transmits the received user physiological parameter to the terminal device, and the terminal device according to the physiological parameter Generate a monitoring report and output it to the user.

Preferably, the physiological parameter monitoring device immediately transmits the received user physiological parameter or monitoring report to the terminal device through the wireless communication unit; when the physiological parameter monitoring device and the terminal device network When the connection is interrupted, the physiological parameter monitoring device can temporarily store the physiological parameters of the user. In the case of network recovery, when the parameter to be generated is monitored and the user needs to upload physiological parameters and monitoring reports, the physiological parameter monitoring device Sending the physiological parameter and monitoring report to the terminal device.

In the physiological parameter monitoring system of the present invention, the electrode patch and the physiological parameter monitoring device communicate in a wireless manner, and the physiological parameters of the user can be detected by selecting different patch numbers and bonding positions according to different detection requirements. The detection of physiological parameters is not limited by hardware, and the use is more convenient, flexible, and resource-saving.

Please refer to FIG. 1 , which is a schematic diagram of a hardware architecture of a preferred embodiment of a physiological parameter monitoring system of the present invention. In the present embodiment, the physiological parameter monitoring system 100 includes a physiological parameter collecting device 10 and a physiological parameter monitoring device 20. The physiological parameter collecting device 10 includes a plurality of signal collecting units 101 for attaching to the surface of the user's body to collect physiological parameters of the user. Each signal acquisition unit 101 is capable of establishing a wireless communication connection with the physiological parameter monitoring device 20. When monitoring the physiological parameters of the user, the physiological parameter collecting device 10 detects the physiological parameters of the user by using different numbers of signal collecting units 101 to be attached to different positions on the surface of the user body for different monitoring needs. For example, when the physiological parameter monitoring system 100 is used to monitor a user's electrocardiogram signal, if the user needs to measure a three-lead electrocardiogram, the physiological parameter collecting device 10 is pasted by four signal collecting units 101 according to user requirements. The user's body signal is collected to the user's body surface. If the user needs to monitor the 10-lead ECG signal, the physiological parameter acquisition device 10 measures the ten-lead ECG signal through ten signal acquisition units 101 attached to the corresponding position on the user's body surface. Each signal acquisition unit 101 transmits the collected physiological parameter signals to the physiological parameter collection device 20 in a wireless manner. The physiological parameter monitoring device 20 analyzes and processes the received physiological parameters of the user to generate a physiological parameter monitoring report. The physiological parameters may include, but are not limited to, an electrocardiography (ECG) signal, an electroencephalogram signal, a blood pressure value, a blood oxygen saturation, a body temperature, a respiratory signal, and the like.

In the present embodiment, the physiological parameter monitoring device 20 is a wrist-worn electronic device that can be worn on a patient's wrist, such as shown in FIG. 2. In other embodiments, the physiological parameter monitoring device 20 can also be other types of wearable electronic devices, for example, can be worn on the patient's head in the form of smart glasses, and can be worn on the patient's neck in the form of a necklace. It is in the form of a belt worn on the waist of the patient, and can also be worn on the patient's clothes in the form of a brooch, etc., all of which are within the scope of the present invention, but are not limited thereto. In other embodiments, the physiological parameter monitoring device 20 can also be a portable electronic device without being worn on a patient.

The physiological parameter monitoring system 100 of the present invention will be described in detail below.

The physiological parameter collecting device 10 includes a plurality of signal collecting units 101 and a first wireless communication unit 102.

The plurality of signal acquisition units 101 are configured to allow the user to select a required number of signal acquisition units 101 to be attached to different positions on the body surface of the user according to the detection requirement to collect the physiological parameter signals of the user. Each of the signal acquisition units 101 is a wireless electrode patch for attaching to the surface of the user's body to collect physiological parameters of the user. In an embodiment of the invention, the physiological parameter monitoring system 100 is an electrocardiographic monitoring system, and the plurality of signal acquisition units 101 are configured to be attached to different positions on the surface of the user's body to collect a potential signal of the surface of the user's body. These potential signals measure changes in potential when the heart contracts and relaxes. The muscles of the heart are the only muscles in the human muscle that have spontaneous beating and rhythmic contractions. Since the heart's conduction system emits electric waves that stimulate the entire muscle fibers to contract, when the waves are generated and transmitted, the muscles produce a weak current distribution throughout the body. If the electrode patch is connected to different parts of the body, the potential signal can be measured, so that the user's electrocardiogram signal can be generated according to the potential signal. In this embodiment, the user can select the number of the signal acquisition unit 101 and the bonding position according to the requirements of the monitoring content to measure the potential signals of different parts, thereby obtaining ECG monitoring of different lead/lead. In this embodiment, the number of the signal collection units 101 may be ten, but is not limited thereto. For example, when the user needs to monitor the three-lead ECG signal, the four signal acquisition units 101 can be selected to be attached to the surface of the user's body as shown in FIG. 2 to collect the potential signal. The electrode patches are named A, B, C, and D, respectively, and the four electrode patches AD respectively collect potential signals of corresponding parts of the user's body surface. Wherein, the electrode patch A is used as a reference potential point, the first lead is formed between the electrode patches A and B, the second lead is formed between the electrode patches A and C, and the third electrode is formed between the electrode patches A and D. Lead. It can be understood that when the user needs to monitor the single-lead electrocardiogram, the two signal acquisition units 101 are selected to be attached to the body surface of the subject to collect the user's ECG signal. If the user needs to monitor the 12-lead ECG, Then, ten signal acquisition units 101 are selected to be attached to the corresponding position on the body surface of the subject to collect the user's ECG signal. The physiological parameter acquisition unit 10 can also measure single-lead, 5-lead, and more lead ECG signals by using different numbers of signal acquisition units 101. In other embodiments, the electrode patch in the signal acquisition unit 101 can also be used to attach to the user's chest to detect the user's breathing signal. The electrode patch in the signal acquisition unit 101 may also be an electrode patch for the patient to fit on the head for collecting the EEG signal of the user. In some embodiments, the signal acquisition unit 101 may also be a clip-type blood oxygen saturation acquisition device for collecting blood oxygen saturation and the like of the user, but is not limited thereto.

In the present embodiment, each of the signal acquisition units 101 is provided with a first wireless communication unit 102, and each of the signal acquisition units 101 can establish a wireless relationship with the physiological parameter monitoring device 20 through the first wireless communication unit 102. The communication connection sends the collected physiological parameters of the user to the physiological parameter monitoring device 20.

In this embodiment, the network establishing the wireless communication connection may be any type of conventional wireless communication, such as radio, Wireless Fidelity (WIFI), cellular, satellite, broadcast, and the like. Wireless communication technologies may include, but are not limited to, Global System for Mobile Communications (GSM), General Packet Radio Service (GPRS), Bluetooth, Code Division Multiple (Code Division Multiple) Access, CDMA), Wideband Code Division Multiple Access (W-CDMA), CDMA2000, IMT Single Carrier (IMT Single Carrier), Enhanced Data Rates for GSM Evolution (EDGE), Long Term Evolution (Long- Term Evolution, LTE), Advanced Long Term Evolution (LTE), Time-Division LTE (TD-LTE), High Performance Radio Local Area Network (Herper LAN), High Performance Radio Wide Area Network (High Performance) Radio Wide Area Network, HiperWAN), Local Multipoint Distribution Service (LMDS), Worldwide Interoperability for Microwave Access (WiMAX), ZigBee, Orthogonal Frequency Division Using technology (Flash Orthogon Al Frequency-Division Multiplexing (Flash-OFDM), High Capacity Spatial Division Multiple Access (HC-SDMA), Universal Mobile Telecommunications System (UMTS), Universal Mobile Telecommunications System UMTS Time-Division Duplexing (UMTS-TDD), Evolved High Speed Packet Access (HSPA+), Time Division Synchronous Code Division Multiple Access (TD-SCDMA) ), Evolution-Data Optimized (EV-DO), Digital Enhanced Cordless Telecommunications (DECT) and others.

In the embodiment of the present invention, the physiological parameter collecting device 10 may further include a detecting unit 103, configured to detect whether an abnormality occurs in the process of attaching the signal collecting unit 101 to the surface of the user's body, such as looseness and power consumption. When the abnormality is detected, the abnormal condition is sent to the physiological parameter monitoring device 20 through the first wireless communication unit 102, so that the user can timely pass the physiological parameter monitoring device 20 Understand the abnormal situation. In this embodiment, the detecting unit 103 is disposed in each of the signal collecting units 101 for detecting whether an abnormality occurs in the corresponding signal collecting unit 101. For example, the detecting unit 103 may include a pressure sensor disposed on each of the signal collecting units 101. When the signal collecting unit 101 is attached to the surface of the patient's body, the signal collecting unit 101 and the patient's body The pressure sensor can detect a certain amount of pressure, and the pressure sensor detects whether the signal acquisition unit 101 is loose by detecting the pressure value, and generates when the signal acquisition unit 101 is detected to be loose. The release unit 103 sends the release prompt signal to the physiological parameter monitoring device 20 through the first wireless communication unit 102. It can be understood that the detecting unit 103 can detect whether the signal collecting unit 101 is loose or not by using an infrared sensor or a physiological ECG signal, but is not limited thereto. The detecting unit 103 can also detect the remaining power of the signal collecting unit 101 by using a voltage measuring circuit (not shown), and generate a low-power warning signal when the power is lower than the preset value, and the power is generated. A low warning signal is sent to the physiological parameter monitoring device 20 through the first wireless communication unit 102.

The physiological parameter monitoring device 20 includes a second wireless communication unit 201, a processor 202, a memory 203, an output unit 204, and an input unit 205.

The second wireless communication unit 201 is configured to establish a wireless communication connection with the first wireless communication unit 102, and receive the data sent by the signal collection unit 101 in the physiological parameter collection device 10. The data received by the signal collecting unit 101 by the second wireless communication unit 201 includes the physiological parameters collected by the signal collecting unit 101, and may also include the abnormality of the signal collecting unit 101 being loose, low battery, and the like. Prompt information.

The processor 202 is configured to execute software code and perform data analysis and operations. In this embodiment, the processor 202 can be a central processing unit (CPU), a microprocessor or other data processing chip. The memory 203 is configured to store software code and data such as user physiological parameters received by the physiological parameter collection device 10. In the present embodiment, the memory 203 may be an internal storage unit of the physiological parameter monitoring device 20, such as a hard disk or a memory. In other embodiments, the memory 203 may also be an external storage device of the physiological parameter monitoring device 20, such as a plug-in hard disk, a smart memory card (SMC), and a secure digital (Secure Digital, SD). ) card, flash memory card (Flash Card), etc. The output unit 204 is configured to output the data in the physiological parameter monitoring device 20. In this embodiment, the output unit 204 may be, but is not limited to, one or more of a display, an LED lamp, a speaker, and the like. The input unit 205 is used for a user to input a control operation. In this embodiment, the input unit 205 can be a button, a touch screen, or the like.

Please refer to FIG. 3 , which is a schematic diagram of functional modules of the data processing system 30 in an embodiment. The data processing system 30 operates in the physiological parameter monitoring device 20. In other embodiments of the present invention, the data processing system 30 may also run in other terminal devices such as a cloud server. The data processing system 30 includes one or more modules that are stored in the memory 203 and executed by the processor 202. The module referred to in the present invention refers to a series of computer program instruction segments capable of performing a specific function, and is more suitable for describing the execution process of the software in the physiological parameter monitoring device 20 than the program. In the embodiment, the data processing system 30 includes a data acquisition module 301, a data analysis processing module 302, an output module 303, and a setting module 304.

The data acquisition module 301 is configured to acquire a user physiological parameter sent by the physiological parameter collection device 10. In this embodiment, the data acquisition module 301 acquires a potential signal of the surface of the user's body transmitted by each of the signal acquisition units 101 attached to the surface of the user's body.

The data analysis processing module 302 is configured to analyze the number of signal acquisition units attached to the surface of the user body and the physiological parameter values collected by each signal acquisition unit according to the received physiological parameters of the user, and generate a corresponding monitoring report. In this embodiment, the data analysis processing module 302 determines the lead number of the electrocardiogram signal according to the potential signal sent by the received signal acquisition unit 101, and generates a corresponding lead according to the lead number and the potential signal value. ECG signal. For example, after receiving the potential signals of the surface of the user's body collected by the electrode patches A, B, C, and D as described in FIG. 2, the data analysis processing module 302 is based on the four electrode patches A, The potential signals collected by B, C, and D generate ECG signals of three leads of AB, AC, and AD, and then generate an ECG monitoring report.

In other embodiments of the present invention, the data analysis processing module 302 may also analyze and process the acquired EEG signals to generate an EEG monitoring report, and analyze and process the acquired respiratory signals to generate a respiratory monitoring report. The acquired blood oxygen saturation signal can be analyzed and processed to generate a blood oxygen saturation monitoring report. Since the technology for generating the above physiological parameter monitoring report is prior art, it will not be described herein.

The output module 304 is configured to output the monitoring report generated by the data analysis processing module 302 to the user. In the present embodiment, the output module 304 stores the monitoring report and physiological parameter values and the like in the memory 202 for storage.

In this embodiment, the output unit 204 is a display, and the output module 304 displays the monitoring report to the user through the display. In other embodiments, the output module 304 can be connected to an external printer to output the monitoring report to the printer, and the monitoring report is printed by the printer.

Referring to FIG. 4, in an embodiment of the present invention, the physiological parameter monitoring device 20 can further communicate with one or more external terminal devices 200 through the second wireless communication unit 201, and collect the physiological parameters. The user's physiological parameters collected by the device 10 are sent to the terminal setting 200, and the terminal device 200 analyzes and processes the physiological parameter to generate the physiological parameter monitoring report. When the user wants to obtain the physiological parameter monitoring report, It is acquired by the terminal device 200. The terminal device 200 may include, but is not limited to, a terminal device such as a cloud server, a web server, a personal computer, or the like (for example, a computer of a doctor's office). In some embodiments, the physiological parameter monitoring device may directly send the monitoring report to the cloud server or other terminal device through the second wireless communication unit 201.

In some embodiments of the present invention, the physiological parameter monitoring device 20 immediately transmits user physiological parameters to the terminal device through the second wireless communication unit 201. When the network connection between the physiological parameter monitoring device 20 and the terminal device 200 is interrupted, the physiological parameter monitoring device 20 may temporarily store the physiological parameters of the user, and in the case of network recovery, the parameters to be generated are generated. When the monitoring is completed and the user needs to upload data such as physiological parameters and monitoring reports, the physiological parameter monitoring device 20 transmits the physiological parameters and the like to the terminal device 200.

In some embodiments of the present invention, the terminal device 200 may further obtain a corresponding treatment suggestion or health knowledge or the like according to the physiological parameter value or the monitoring report result, and send the treatment suggestion or health knowledge to the physiological parameter monitoring. The device 20, the output module 304 displays the treatment suggestion or health care knowledge to the user through the output unit 204. For example, when the ECG monitoring report of the user indicates that the user has an arrhythmia, the physiological parameter monitoring device 20 may display a treatment suggestion such as medication guidance through the output unit 204 according to the treatment suggestion sent by the cloud server, and prompt the user to press Health care knowledge such as work and rest, maintaining a stable mood.

In some embodiments, the data acquisition module 301 is further configured to receive an abnormal situation sent by the physiological parameter collection device 10, and the output module 303 is further configured to output the abnormal condition by using the output unit 205. Give the user a reminder to the user. For example, the abnormal condition may include, but is not limited to, the electrode patch is loose, the battery is low, and the like. When the data acquisition module 301 receives the abnormal condition, the output module 303 can issue a prompt to the user through a speaker or a flash in the output unit 204.

In some embodiments, when the user wearing the physiological parameter monitoring device 20 feels uncomfortable, an alarm signal may be input through the input unit 205, and the data acquisition module 301 is further configured to acquire a user by using the The alarm signal input by the input unit 205 is recorded, and the time when the user inputs the alarm signal is recorded for reference by the medical staff to diagnose the condition.

While the preferred embodiment of the invention has been shown and described, it will be understood Therefore, it is intended that the invention not be limited to the embodiments disclosed herein,

100‧‧‧ physiological parameter monitoring system

10‧‧‧ physiological parameter acquisition device

101‧‧‧Signal acquisition unit

102‧‧‧First wireless communication unit

103‧‧‧Detection unit

20‧‧‧ physiological parameter monitoring device

201‧‧‧Second wireless communication unit

202‧‧‧ processor

203‧‧‧ memory

204‧‧‧Output unit

205‧‧‧ input unit

30‧‧‧Data Processing System

301‧‧‧ Data Acquisition Module

302‧‧‧Data Analysis Processing Module

303‧‧‧Output module

200‧‧‧ Terminals

FIG. 1 is a schematic diagram of a hardware architecture of a physiological parameter monitoring system according to an embodiment of the present invention. 2 is a schematic diagram of a physiological parameter measurement performed by a user wearing the physiological parameter monitoring system shown in FIG. 1 according to an embodiment of the present invention. FIG. 3 is a schematic diagram of functional modules of a data analysis system according to an embodiment of the present invention. 4 is a schematic diagram of an application environment of a physiological parameter monitoring system according to an embodiment of the present invention.

Claims (10)

A physiological parameter collecting device comprises: a plurality of signal collecting units, wherein the user selects different numbers of signal collecting units to be attached to different positions on the body surface of the user according to different detection requirements to collect the physiological parameter signals of the user. And a wireless communication unit, disposed in each signal acquisition unit, configured to establish a wireless communication connection between the signal acquisition unit and a physiological parameter monitoring device, and send the physiological parameters collected by the signal acquisition unit to the user The physiological parameter monitoring device is configured to perform analysis and processing on the physiological parameter by the physiological parameter monitoring device to generate a physiological parameter monitoring report. The physiological parameter collecting device according to claim 1 is characterized in that each of the signal collecting units is a wireless electrode patch. The physiological parameter collecting device according to claim 2, wherein the physiological parameter collecting device further comprises a detecting unit disposed in each signal collecting unit, wherein the detecting unit is configured to detect Whether an abnormality occurs in the process of attaching the signal acquisition unit to the surface of the user's body, and when an abnormality is detected in the signal acquisition unit, the abnormal condition is sent to the physiological parameter monitoring device through the wireless communication unit. . The physiological parameter collecting device according to claim 1, wherein the physiological parameter collected by the signal collecting unit comprises one or more of the following signals: an electrocardiogram signal, an electroencephalogram signal, and a blood pressure signal. , blood oxygen saturation, respiratory signals. A physiological parameter monitoring device is configured to perform wireless communication with a physiological parameter collecting device, wherein the physiological parameter collecting device comprises a plurality of information collecting units for the user to select different numbers of signal acquisitions according to different detection requirements. The unit is attached to different positions on the surface of the user's body to collect the physiological parameter signal of the user. The improvement is that the physiological parameter monitoring device comprises: a wireless communication unit for attaching to the surface of the user body with the physiological parameter collecting device. The signal acquisition unit establishes a wireless communication connection and receives the physiological parameters of the user collected by the signal acquisition unit; the processor; the memory, wherein the memory stores a plurality of program modules, and the plurality of program modules are configured by Executing by the processor, the plurality of program modules include: a data acquisition module, configured to acquire the user physiological parameter sent by the signal collection unit attached to the surface of the user body; and a data analysis processing module, For collecting signal collected to the surface of the user's body based on the received physiological parameters of the user The number of signal elements and each acquisition unit to the physiological parameter values, generating a corresponding monitoring reports. The physiological parameter monitoring device according to claim 5, wherein the physiological parameter monitoring device is a wristband electronic device. The improvement of the physiological parameter monitoring device according to the fifth aspect of the invention, wherein the plurality of program modules further comprise an output module, wherein the data acquisition module is further configured to receive the sending by the physiological parameter collection device In an abnormal situation, the output module is configured to output the abnormal condition to the user, thereby issuing a reminder to the user. The physiological parameter monitoring device according to claim 5, wherein the physiological parameter monitoring device further comprises an input unit for inputting an alarm signal when the user feels uncomfortable, the data acquisition mode The group is also used to obtain an alarm signal input by the user through the input unit, and record the time when the user inputs the alarm signal. The physiological parameter monitoring device according to claim 5, wherein the physiological parameter monitoring device further establishes a wireless communication connection with the at least one terminal device through the wireless communication unit, and the received physiological parameters of the user Sending to the terminal device, the terminal device generates a monitoring report according to the physiological parameter and outputs the monitoring report to the user. The physiological parameter monitoring device according to claim 9, wherein the physiological parameter monitoring device sends the received physiological parameter or monitoring report to the terminal device through the wireless communication unit; When the network connection between the physiological parameter monitoring device and the terminal device is interrupted, the physiological parameter monitoring device may temporarily store the physiological parameters of the user, and in the case of network recovery, the parameter to be generated is monitored and used. When the physiological parameter and the monitoring report need to be uploaded, the physiological parameter monitoring device transmits the physiological parameter and the monitoring report to the terminal device.