TW201909128A - Physiological monitoring system can be applied to safety monitoring, medical institutions, and the like - Google Patents

Abstract

The invention relates to a physiological monitoring system, which comprises a near-end portable monitoring module for generating a first sensing data, an image sensing module for capturing a first image of a user and synchronizing the first sensing data and the first image to form the first combined data, and a near-end information display module capable of searching and connecting the corresponding near-end portable monitoring module and receiving the first sensing data and displaying images corresponding to the first combined data. When the first sensing data contains a warning signal, the first combined data during the first time before the warning and the second time when the warning signal being cleared is transmitted to the Internet through the image sensing module to be stored, and the first combined data of the period of time is provided to the near-end information display module to be displayed. The physiological monitoring system can be applied to safety monitoring, medical institutions, and the like.

Description

Physiological monitoring system

The invention relates to the technical field of physiological monitoring, in particular to a physiological monitoring system for monitoring the physiological state and/or image of a user wearing a portable monitoring module.

The traditional medical care system allows the patient to call a doctor or a caregiver in an active manner, such as pulling a bell; however, this is very inconvenient for the patient, and in other special cases, the patient cannot Proactive calling for help. The same situation also occurs in the environment of home care. Although the condition of the caregiver can be known through the sensing device in the tradition, only the transmission of data is still inconvenient.

In addition, a conventional mechanism of pairing between the sensing device and the monitoring device connected through the network does not automatically or manually search for each other, so a message transmission error occurs between the sensing device and the monitoring device that are traditionally connected through the network. With the problem of disorder.

In view of this, the present invention proposes a physiological monitoring system for improving the conventional physiological signal and image capturing device.

A first aspect of the present invention provides a physiological condition monitoring system including a near-end portable monitoring module and an image sensing module. The image sensing is performed after a user wears the near-portable monitoring module. The module and/or the near-end information display module can monitor the physiological state and/or image of the user by receiving the sensing data transmitted by the near-end portable monitoring module. In addition, the near-end information display The module can be used to search for and connect the corresponding near-end portable monitoring module.

According to the foregoing monitoring system, in addition to the near-end portable monitoring module, the physiological state and/or image of another user can be monitored through another remote portable monitoring module. In order to achieve physiological monitoring and / or image monitoring for single or multiple users.

According to the foregoing monitoring system, the present invention comprises a near-end information display module and/or a remote information display module for displaying the physiological state and/or image of the user for the user or other non-use. The user (such as a caregiver, caregiver, caregiver) can monitor the user through the information display module.

A fourth object of the present invention is the monitoring system according to the foregoing, comprising a warning unit, wherein the warning unit can prompt the user or other non-users when the image and the physiological state are abnormal.

According to the foregoing monitoring system, the near-end portable monitoring module, the image sensing module and the near-end information display module can be unidirectional by using a communication unit conforming to a wired communication or wireless communication specification. Or two-way data transfer for stable and convenient installation in different environments.

The sixth object of the present invention is to store the physiological state and image of the previous set time to the warning signal release time when the warning signal is generated, so that the near-end information display module can trace back the current and current warning signal history and browse to confirm the warning. The actual situation of the signal.

According to the foregoing monitoring system, the monitored physiological state signals and images of the user are synchronized with each other in the image sensing module, and the information corresponding to the disorder and error is not caused.

To achieve the above and other objects, the present invention provides a monitoring system for monitoring a physiological state or a physiological state of a user and a first image, including a near-end portable monitoring module, an image sensing module, and a near-end End information display module. The near-end portable monitoring module includes a first communication unit and a first sensing unit. The proximal portable monitoring module is worn by the user. The first sensing unit senses the physiological state of the user to generate a first sensing material. The first communication unit transmits the sensing data. The image sensing module includes a second communication unit and an image capturing unit. The second communication unit receives the first sensing data, and the image capturing unit captures the first image of the user, and the image capturing unit tracks the user by using the near-end portable monitoring module The first image is captured, and the image sensing module synchronizes the first sensing data with the first image execution time to form a first combined material. The near-end information display module includes a third communication unit and a first display unit. The near-end information display module uses the third communication unit to connect to the Internet to search for and connect the corresponding near-portable monitoring module to receive the first sensing data for display on the first display unit. a screen corresponding to the first combined data transmitted from the image sensing module of the first sensing data, when the first sensing data includes a warning signal, the first time before the warning occurs to the warning signal Discharging the first combination data in the second time period by using the second communication unit to be stored in the Internet, and providing the first combination data from the first time to the second time to the near The information display module displays the first combined data.

Compared with the prior art, the monitoring system provided by the present invention can monitor one or a plurality of users wearing the portable monitoring module, and in addition to receiving the physiological state of the user through the image sensing module, The image of the user can be selectively captured, and the related physiological state and the image are displayed through the display module. In addition, the present invention can also apply automatic pairing monitoring to avoid displaying information of the wrong user, and the present invention can further Storing the sensing data of the correct user in the time period before and after the abnormality, and the image corresponding to the sensing data, so the invention can be applied in more fields, such as security monitoring, pet monitoring, home care or medical treatment. Applications such as institutions.

In order to fully understand the objects, features and advantages of the present invention, the present invention will be described in detail by the following specific embodiments and the accompanying drawings.

Please refer to FIG. 1, which is a block diagram of a physiological monitoring system according to a first embodiment of the present invention. In FIG. 1 , the physiological monitoring system 10 includes a near-portable monitoring module 12 , an image sensing module 14 and a near-end information display module 16 . The physiological monitoring system 10 monitors the physiological state of a user 2 . BIOIFO, or physiological state BIOIFO and first image FIMG.

The near-end portable monitoring module 12 further includes a first communication unit 122 and a first sensing unit 124. The first portable sensing module 12 is configured to be used by the user 2 to sense the physiological state BIOIFO of the user 2 to generate a first sensing data FSD. For example, the first sensing unit 122 is a temperature. At least one of sensing, audio sensing, acoustic sensing, humidity sensing, brightness sensing, motion sensing, vital sign sensing, physiological signal sensing, and distance sensing. The first communication unit 122 can transmit the first sensing data FSD. For example, the near-portable monitoring module 12 can be a watch type and a jewelry type. The first communication unit 122 is configured to comply with at least one of a wireless communication specification and a wired communication specification. Taking the wireless communication specification as an example, the wireless communication specification may include a short-range communication protocol and a long-distance communication protocol. The short-range communication protocol may be a Near Field Communication protocol, a Bluetooth communication protocol, a ZigBee communication protocol, a Digital Enhanced Cordless Telecommunications protocol, or a wireless universal sequence bus. (Wireless Universal Serial Bus) communication protocol; and long-distance communication protocol can be wireless fidelity (Wi-Fi) protocol, municipal wireless communication protocol, general packet radio service (General Packet Radio Service), wireless Broadband (Wireless Broadband) protocol, Worldwide Interoperability for Microwave Access protocol, Time Division Duplexing protocol, High Speed Packet Access protocol, high speed downlink High Speed Downlink Packet Access protocol or Long Term Evolution.

The image sensing module 14 includes a second communication unit 142 and an image capturing unit 144. The second communication unit 142 receives the first sensing data FSD, wherein the second communication unit 142 is the same as the description of the first communication unit 122. The image capturing unit 144 can selectively capture the first image FIMG of the user 2. For example, the image capturing unit 144 can be a CCD component or a CMOS component, and the resolution can be standard image quality (SD) and high. At least one of density image quality (HD). The image capturing unit 144 tracks the user 2 by the near-end portable monitoring module 12 to obtain the first image FIMG.

The near-end information display module 16 includes a third communication unit 162 and a first display unit 164. The third communication unit 162 can receive the first sensing data FSD and the first image FIMG synchronized with the first sensing data FSD. The third communication unit 162 is the same as the description of the first communication unit 122. Furthermore, the first display unit 164 can display a picture FR corresponding to the first sensing data FSD and the first image FIMG synchronized with it. For example, at least one of the physiological feature and the image may be displayed in the screen FR for monitoring by the user 2 or the non-user.

It should be noted that the near-end portable monitoring module 12, the image sensing module 14 and the near-end information display module 16 can perform another transmission direction in addition to the single image transmission. Command/control signal transmission.

Please refer to FIG. 2, which is a block diagram of a physiological monitoring system according to a second embodiment of the present invention. In addition to the near-end portable monitoring module 12, the image sensing module 14 and the near-end information display module 16, the physiological monitoring system 10' includes Netcom unit 18.

The network communication unit 18 is connected to an internet 20. The Netcom unit 18 conforms to a communication specification that also conforms to at least one of the aforementioned wireless communication specifications and wired communication specifications. The first sensing data FSD can be transmitted through the Internet 20 to the near-end portable monitoring module 12, the image sensing module 14 and the near-end information display module 16 through the network unit 18. Pass between. The Internet 20 can be an Internet with network computing and/or network control capabilities such as cloud computing, distributed systems, and servers.

Referring to FIG. 3, the near-end information display module 16 of the physiological monitoring system 10' of the second embodiment of the present invention searches for and connects the corresponding near-end portable monitoring module 12 and the physiological monitoring system 10' to at least store the sense of storage. Schematic diagram of the measured data. The figure indicates that the near-end information display module 16 searches for and connects the corresponding near-portable monitoring module 12 to receive the first sensing data FSD to display the corresponding information in the first display unit 164. A picture of the first sensing data FSD. In detail, the near-end information display module 16 can include a memory unit or a storage unit, such as a flash memory, a hard disk, etc., and the near-end information display module 16 searches for and connects the corresponding near end using the third communication unit 162. The portable monitoring module 12 receives the first sensing data FSD and the physiological monitoring system 10 ′ stores at least the sensing data by first storing the address of the near-portable monitoring module 12 in the memory unit or storing In the unit, as shown in step S401 of FIG.

Specifically, the media access control address (MAC address) of the near-end portable monitoring module 12 can be scanned by using a QR code, and stored in the memory unit of the near-end information display module 16 or In the storage unit, the manner in which the storage medium access control address of the present invention is stored is not limited thereto.

Next, as shown in step S402 of FIG. 4, the near-end information display module 16 searches for and connects the corresponding near-end portable monitoring module 12 through the Internet 20 based on the address. The near-end information display module 16 and the near-end portable monitoring module 12 can be, for example, a mobile phone with a mobile communication capability, a tablet computer, a notebook computer, and the like. In particular, the near-end information display module 16 can utilize the media access control of the near-end portable monitoring module 12 stored in the memory unit or the storage unit when the system is turned on, for example, by automatic input or manual input. The address is searched through the Internet 20 for the near-end portable monitoring module 12 corresponding to the media access control address. Of course, the near-end information display module 16 is also allocated to the memory unit or the storage unit. The unique identification code of the near-end portable monitoring module 12 is connected to the near-end portable monitoring module 12.

Next, as shown in step S403 of FIG. 4, the Internet 20 establishes a connection between the near-end information display module 16 and the near-end portable monitoring module 12. In particular, the cloud computing can find the near-end portable monitoring module 12 that has been paired in advance through the transceiver/transponder, and establish the near-end portable monitoring module 12 and the near-end information through the cloud computing. The connection binding of the module 16 is displayed.

In particular, when the cloud computing binds the paired portable monitoring module 12 and the near-end information display module 16, the transceiver unit of the cloud computing establishes a P2P channel with the near-end information display module 16 or The only communication channel that enables the connection between the pairers, so that the near-end information display module 16 and the portable monitoring module 12 communicate with each other and display related physiological information on the near-end information display module 16 end. Furthermore, as shown in step S404 of FIG. 4, the image sensing module 14 can perform time synchronization between the first sensing data FSD and the first image FIMG to form a first combined data FCD. The first combination data FCD can be transmitted to the second communication unit 142, and it is worth noting that the first combination data FCD can be the first sensing data FSD and the first image FIMG, or can be the first sensing data. The combination of the FSD and the first image FIMG.

Then, as shown in step S405 of FIG. 4, the near-end information display module 16 receives the first sensing data FSD to display the image sense corresponding to the first sensing data FSD at the first display unit 164. The screen FR of the first combined data FCD transmitted by the test module 14 and when the first sensing data FSD includes the warning signal, the first time before the warning occurs and the second time after the warning signal is released The first combined data FCD is transmitted to the Internet 20 by using the second communication unit 142, and provides the first combined data FCD from the first time to the second time to the near-end information display. The module 16 displays the first combined data FCD.

In addition, the near-end information display module 16 displays at least the connection state between the network 12 and the near-end portable monitoring module 12 and the Internet 20. For example, when the near-end information display module 16 is disconnected or disconnected from the Internet 20, the third communication unit 162 of the near-end information display module 16 can cause the near-end information display module 16 to display near The information display module 16 and the Internet 20 are connected or disconnected, and when the near-end information display module 16 is connected to the Internet 20, the Internet 20 can also provide near-end information. The display module 16 displays a connection between the near-end information display module 16 and the Internet 20. When the near-end portable monitoring module 12 is connected or disconnected from the Internet 20, the Internet 20 can cause the near-end information display module 16 to display the near-end portable monitoring module 12 and the Internet. The network 20 is connected or disconnected.

Moreover, as shown in FIG. 3, the Internet 20 can include an Internet storage unit 201 to store at least the first combined data FSD from the first time to the second time. In particular, the transceiver unit of the cloud computing not only transmits the data, but also combines the first sensing data FSD with the first image FIMG and the sound, and is synchronized with each other in time, and the physiological state has a problematic time point. All messages from a certain period of time to the time when the problem has not been resolved will be transferred to the cloud computing storage for future tracking.

As shown in FIG. 5, all devices (such as the near-end portable monitoring module 12, the near-end information display module 16, etc.) are all movable, and under the movement, as long as they are within the transmittable distance, between the devices Both will automatically maintain a search for self-organizing capabilities without causing monitoring interruptions. In FIG. 5, the near-end portable monitoring module 12 worn on the user 2 can be separated from the transceiver unit of the Internet 20, but needs to be maintained at least at the near end. The portable monitoring module 12 can be connected to the Internet. The transceiver unit of the network 20 is under normal communication, and the near-end information display module 16 can also communicate normally with the transceiver unit of the Internet 20, that is, the mobile terminal monitoring module 12' and the near-end information after the mobile terminal The display module 16' can communicate normally with the transceiver unit of the Internet 20. In FIG. 5, because the near-end information display module 16 and the transceiver unit are respectively linked with the cloud computing device, as long as their communication distance is in communication with the 3G/4G/5G or the future development long-distance communication base station, You can link to cloud computing. Of course, wireless mobile communication can also be done by satellite.

Please refer to FIG. 6, which is a block diagram of a physiological monitoring system according to a third embodiment of the present invention. In FIG. 6 , the physiological monitoring system 10 ′′ includes the near-end portable monitoring module 12 , the image sensing module 14 , the near-end information display module 16 , and the Netcom unit 18 in the second embodiment. In addition to the Internet 20, the remote information display module 22 is further included.

The remote information display module 22 includes a fourth communication unit 222 and a second display unit 224. The fourth communication unit 222 receives the first sensing data FSD and the corresponding first image FIMG through the Internet 20 to display the corresponding first sensing data FSD and the second display unit 224 Corresponding to the screen FR of the synchronized first image FIMG. The fourth communication unit 222 also conforms to at least one of the foregoing wireless communication specifications and wired communication specifications.

The remote information display module 22 can receive the first sensing data FSD and the first image FIMG synchronized with the first sensing data FSD through the network communication unit 18 or directly connected to the Internet 20 .

Please refer to FIG. 7, which is a block diagram of a physiological monitoring system according to a fourth embodiment of the present invention. In FIG. 7 , the physiological monitoring system 10′′′ includes the near-portable monitoring module 12 , the image sensing module 14 , the near-end information display module 16 , and the Netcom unit in the second embodiment. In addition to the Internet 20, the remote portable monitoring module 24 and the alert unit 26 are further included. The physiological monitoring system 10"" can monitor the physiological state BIOIFO' of the other user 2' and the second image SIMG in addition to monitoring at least one of the physiological state BIOIFO of the user 2 and the first image FIMG. At least one of them.

The remote portable monitoring module 24 includes a fifth communication unit 242 and a second sensing unit 244. The remote portable monitoring module 24 is worn by the other user 2'. The second sensing unit 244 senses at least one of the physiological state BIOIFO' and the second image SIMG of the other user 2' to generate a second sensing data SSD. The fifth communication unit 242 transmits the second sensing data SSD or the second sensing data SSD and the second image SIMG to the Internet 20 . The second sensing unit 244 is at least one of temperature sensing, audio sensing, sound sensing, humidity sensing, brightness sensing, motion sensing, vital sign sensing, physiological signal sensing, and distance sensing. By.

The alert unit 26 includes a sixth communication unit 262 and a first processing unit 264. The sixth communication unit 262 receives the second sensing data SSD, and the first processing unit 264 selectively generates an alert signal WS according to the second sensing data SSD. The alert signal WS can alert the user 2 and/or the abnormal state of the user 2'.

In the case that the Internet 20 further includes the Internet storage unit 201, the Internet storage unit 201 stores at least the warning signal WS, and further, the Internet storage unit 201 stores at least the time period before and after the warning signal WS. The first sensing data FSD and the first image FIMG synchronized with it.

In the case where the Internet 20 further includes the Internet storage unit 201, the near-end information display module 16 displays a history track of the physiological state of the user 2 and/or the user 2'. And since the Internet 20 has the function of device pairing, the history of the physiological state tracking message transmission can avoid errors and disorders.

Please refer to FIG. 8, which is a block diagram of a physiological monitoring system according to a fifth embodiment of the present invention. In FIG. 8, the physiological monitoring system 10"" except the fourth embodiment of the near-portable monitoring module 12, the image sensing module 14, the near-end information display module 16, Netcom The unit 18, the Internet 20 remote portable monitoring module 24 and the warning unit 26, further includes a servo host 28.

The servo host 28 includes a seventh communication unit 282 and a second host unit 284. The seventh communication unit 282 receives at least one of the first sensing data FSD, the first image FIMG, the second sensing data SSD, and the second image SIMG, and the second host unit 284 is configured according to the first The image FIMG and the second image SIMG generate at least one picture FR. Moreover, the second host unit 284 generates an alert signal WS according to at least one of the first sensing data FSD and the second sensing data SSD.

It should be noted that the near-end information display module 16 of the physiological monitoring system 10' of the second embodiment of the present invention searches for and connects the corresponding near-end portable monitoring module 12 and the physiological monitoring system 10' to store at least the sensing. The manner of the data can be applied to the third to fifth embodiments of the present invention.

The invention has been described above in terms of the preferred embodiments, and it should be understood by those skilled in the art that the present invention is not intended to limit the scope of the 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 the present invention is defined by the scope of the patent application.

2, 2'‧‧‧ users

10, 10', 10'', 10''', 10'''' ‧ ‧ ‧ physiological monitoring system

12, 12'‧‧‧ Near-end portable monitoring module

122‧‧‧First communication unit

124‧‧‧First sensing unit

14‧‧‧Image Sensing Module

142‧‧‧Second communication unit

144‧‧‧Image capture unit

16, 16'‧‧‧ Near-end information display module

162‧‧‧3rd communication unit

164‧‧‧First display unit

18‧‧‧Netcom unit

20‧‧‧Internet

201‧‧‧Internet storage unit

22‧‧‧Remote information display module

222‧‧‧fourth communication unit

224‧‧‧Second display unit

24‧‧‧Remote Portable Monitoring Module

242‧‧‧Fifth Communication Unit

244‧‧‧Second sensing unit

26‧‧‧Warning unit

262‧‧‧6th communication unit

264‧‧‧First Processing Unit

28‧‧‧Servo host

282‧‧‧ seventh communication unit

284‧‧‧Second host unit

BIOIFO, BIOIFO '‧‧‧ physiological state

FIMG‧‧‧ first image

FCD‧‧‧ first combination data

FSD‧‧‧ first sensing data

SIMG‧‧‧Second image

SSD‧‧‧Second Sensing Data

FR‧‧‧ screen

WS‧‧‧ warning signal

S401, S402, S403, S404‧‧‧ steps

1 is a block diagram showing a physiological monitoring system according to a first embodiment of the present invention. 2 is a block diagram showing a physiological monitoring system according to a second embodiment of the present invention. 3 is a schematic diagram of a physiological monitoring system according to a second embodiment of the present invention paired with an Internet and storing at least sensing data. 4 is a flow chart of the physiological monitoring system of the second embodiment of the present invention storing the sensing data by internet pairing and the physiological monitoring system. FIG. 5 is a schematic diagram of a physiological monitoring system according to a second embodiment of the present invention for searching by the Internet and automatically maintaining self-organizing ability. Fig. 6 is a block diagram showing the physiological monitoring system of the third embodiment of the present invention. Figure 7 is a block diagram showing a physiological monitoring system according to a fourth embodiment of the present invention. Figure 8 is a block diagram showing a physiological monitoring system according to a fifth embodiment of the present invention.

Claims (15)

A physiological monitoring system for monitoring a physiological state or a physiological state of a user and a first image, the physiological monitoring system comprising: a proximal portable monitoring module having a first communication unit and a first sensing unit for providing The first sensing unit senses the physiological state of the user to generate a first sensing data, the first communication unit transmits the sensing data, and the image sensing module has a second The communication unit and the image capturing unit, the second communication unit receives the first sensing data, and the image capturing unit captures the first image of the user, and the image capturing unit is configured by the near-end portable The monitoring module tracks the user to capture the first image, wherein the image sensing module synchronizes the first sensing data with the first image execution time to form a first combined data; and the near-end information a display module having a third communication unit and a first display unit, wherein the near-end information display module is connected to the Internet by using the third communication unit to search for and connect to the corresponding near-portable monitoring module to receive The first sensing data is displayed on the first display unit for displaying the first combined data corresponding to the first sensing data transmitted from the image sensing module, when the first sensing data includes the warning signal The first combined data from the first time before the warning occurs to the second time after the warning signal is released is transmitted to the Internet by using the second communication unit, and the first time is provided. The first combination data in the second time is sent to the near-end information display module to display the first combination data. The physiological monitoring system of claim 1, wherein the first sensing unit is temperature sensing, audio sensing, acoustic sensing, humidity sensing, brightness sensing, motion sensing, and vital sign sensing. At least one of physiological signal sensing and distance sensing. The physiological monitoring system of claim 1, further comprising a network communication unit for connecting to the internet, the network communication unit conforming to a communication specification, the first communication unit, the second communication unit, and the first At least one of the three communication units also conforms to the communication specification, and the first sensing data is transmitted through the Internet at the near-end portable monitoring module, the image sensing module, and the near-end information display module. Pass between groups. The physiological monitoring system of claim 3, wherein the near-end information display module comprises a memory unit or a storage unit, and the near-end information display module searches for and connects the corresponding near-end portable monitoring module. The group and the physiological monitoring system at least storing the sensing data includes the following steps: 1) storing the address of the near-end portable monitoring module in the memory unit or the storage unit, and 2) the near-end information display module Searching and connecting the corresponding near-end portable monitoring module through the Internet, and 3) establishing, by the Internet, the connection between the near-end information display module and the near-end portable monitoring module 4) the image sensing module synchronizes the first sensing data and the first image execution time to form a first combined data, and 5) the near-end information display module receives the first sensing data, Displaying, by the first display unit, a screen corresponding to the first combined data transmitted by the image sensing module of the first sensing data, and when the first sensing data includes a warning signal, before the warning occurs The first time to the warning signal The first combination data in the second time period may be transmitted to the Internet by using the second communication unit, and the first combination data from the first time to the second time is provided to the near The information display module displays the first combined data. The physiological monitoring system of claim 3, wherein the internet network comprises an internet storage unit to store at least the first combined data from the first time to the second time. The physiological monitoring system of claim 3, wherein the near-end information display module displays at least between the network and the Internet, and between the near-end portable monitoring module and the Internet. Connection status. The physiological monitoring system of claim 3, further comprising a remote information display module, having a fourth communication unit and a second display unit, the fourth communication unit receiving the first sense through the internet Detecting data to display the screen corresponding to the first sensing material in the second display unit, wherein the fourth communication unit conforms to the communication specification. The physiological monitoring system of claim 3, further comprising a remote portable monitoring module, having a fifth communication unit and a second sensing unit for the user to wear, the second sensing unit Sensing at least one of a physiological state of the other user and the second image to generate a second sensing data, the fifth communication unit transmitting the second sensing data to the Internet. The physiological monitoring system of claim 8, wherein the second sensing unit is temperature sensing, audio sensing, sound sensing, humidity sensing, brightness sensing, motion sensing, and vital sign sensing. At least one of physiological signal sensing and distance sensing. The physiological monitoring system of claim 8, further comprising a warning unit, the warning unit having a sixth communication unit and a first processing unit, the sixth communication unit receiving the second sensing data, the first processing The unit selectively generates an alert signal according to the second sensing data. The physiological monitoring system of claim 10, wherein the internet network further comprises an internet storage unit to store at least the warning signal. The physiological monitoring system of claim 8, wherein the Internet further comprises an internet storage unit, and the near-end information display module displays a historical tracking of the physiological state of the other user. The physiological monitoring system of claim 8, further comprising a servo host, the servo host having a seventh communication unit and a second host unit, wherein the seventh communication unit receives the first sensing data, the first image At least one of the second sensing unit and the second image, the second host unit generates at least one picture according to the first image and the second image, and the second host unit is configured according to the first sensing At least one of the data and the second sensing data generates a warning signal. The physiological monitoring system of claim 1, further comprising a warning unit, the warning unit having a sixth communication unit and a first processing unit, the sixth communication unit receiving the first sensing data, the processing unit is The first sensing data selectively generates a warning signal. The physiological monitoring system of claim 1, further comprising a servo host, the servo host having a seventh communication unit and a second host unit, the seventh communication unit receiving the first sensing data and the image at least The second host unit generates a picture according to the image, and the second host unit generates an alert signal according to at least one of the first sensing data and the image.