TWI592133B - Remote care system - Google Patents

Description

Remote care system

The present invention relates to a remote care system, and more particularly to a remote care system that uses data comparison to determine whether a physiological signal is abnormal.

With the gradual rise of health awareness, the importance of self-health management is increasing day by day. In self-health management, the most important thing is to observe the physical state of the day, and to find the location of the lesion in time when the body is slightly weak, to avoid the disease. deterioration.

In order to observe the physical state of the day, the user usually uses a health management device. Generally, the health management device usually includes a display and a physiological sensor. When the user wears the physiological sensor to a specific part of the body, the physiological sensor can instantly sense the physiological signal of the user. And transmitting the physiological signal to the display, so that the user can understand various physiological conditions, such as body temperature, pulse or blood pressure, through the display.

The conventional health management device usually does not have the function of determining whether the physiological signal is abnormal, and is not able to remind the user when the physiological signal is abnormal, even if the user can understand his or her body temperature, pulse or blood pressure through the health management device. It is still impossible to judge whether the physical state of the moment is abnormal; in addition, since the physiological signals presented by different users in a healthy state are not consistent, even if the conventional health management device can determine whether the physiological signal of the user is abnormal, In the case where the conventional health management device uses a single reference data as the comparison standard, the comparison result cannot accurately determine whether the user's physical state is abnormal, and the conventional health management device has poor health management performance. .

In view of this, the present invention provides a remote care system to solve the conventional health The problem of poor management of health management of management devices.

The object of the present invention is to provide a remote care system that can compare reference waveform data of a current state of the same subject with a reference waveform data of a healthy state, and the reference waveform data and the reference waveform. When the data has a large difference, the corresponding driving signal is issued, thereby improving the health management effectiveness.

In order to achieve the foregoing object, a remote care system of the present invention comprises: a cloud database for storing a reference waveform data and an abnormal record data; and a physiological sensor for the physiological sensor Inducing a portion to be tested and generating a physiological sensing signal; and a processor electrically connecting the cloud database to read the reference waveform data, and electrically connecting the physiological sensor to receive the physiological sensing a signal, wherein the processor converts the physiological sensing signal into a reference waveform data, and compares the reference waveform data and the reference waveform data with a frequency error amount and a peak error amount, and the error amount is not less than one When the frequency threshold is not less than a peak threshold, the processor generates a driving signal and transmits the reference waveform data to the cloud database as the abnormal recording data. Thereby, since the processor can compare the reference waveform data of the current state of the same subject and the reference waveform data of the healthy state, and the processor can have a large difference between the reference waveform data and the reference waveform data. The corresponding driving signal is issued, and the relevant personnel are informed of the comparison result, which has the effect of improving the health management effect.

The frequency threshold is 10% of the frequency value of the reference waveform data. Thereby, the processor can issue the corresponding driving signal when the reference waveform data and the reference waveform data have a specific difference, and the related personnel can understand the comparison result, and have the effect of improving health management effectiveness.

Wherein, the peak threshold value is 10% of the peak value of the reference waveform data. Thereby, the processor can send when the reference waveform data and the reference waveform data have a specific difference Corresponding to the driving signal, and for the relevant personnel to understand the comparison results, the effect of improving health management results.

Wherein, the physiological sensor is a resistive sensor. Thereby, the physiological sensor can transmit the physiological sensing signal through the sensing resistance value, and has the effect of smoothly generating the physiological sensing signal.

The resistive inductor includes a resistive substrate and a metal nanowire array, the resistive substrate has a sensing surface, and the metal nanowire array is disposed on the sensing surface of the resistive substrate, and the The metal nanowire array is configured to sense a resistance value of the portion to be tested, and generate the physiological sensing signal according to the resistance value. Thereby, the physiological sensor can transmit the physiological sensing signal through the sensing resistance value, and has the effect of smoothly generating the physiological sensing signal.

Wherein, the physiological sensor is a photoelectric sensor. Thereby, the physiological sensor can transmit the physiological sensing signal through light sensing, and has the effect of smoothly generating the physiological sensing signal.

The photoelectric sensor comprises a photoelectric substrate, a light-emitting component and a light detector. The surface of the photoelectric substrate is divided into an emission area and a receiving area. The light-emitting component is disposed in the emission area and is used for The portion to be tested emits at least one light, and the photodetector is disposed in the receiving area and configured to receive at least one reflected light reflected by the portion to be tested, and generate the physiological sensing signal according to the at least one reflected light. Thereby, the physiological sensor can transmit the physiological sensing signal through light sensing, and has the effect of smoothly generating the physiological sensing signal.

The light-emitting component has a plurality of light-emitting segments, and the plurality of light-emitting segments are arranged at intervals in the array, and the light emitted by each of the plurality of light-emitting segments has different wavelengths. Thereby, the light-emitting component can emit light having a plurality of different wavelengths, and when the light-emitting component emits light having several different wavelengths toward the portion to be tested of the subject, even if some of the light is characterized by its own wavelength However, it is impossible to smoothly pass through the human tissue, and some of the light can be smoothly irradiated to the part to be tested according to the characteristics of its own wavelength, thereby smoothly generating the physiological sensing signal. No., has the effect of smoothly generating the physiological sensing signal.

The controller is electrically connected to the illuminating component, and the controller is configured to control the plurality of illuminating segments to sequentially emit light of different wavelengths along the arranging direction. Therefore, when the plurality of light exiting segments sequentially emit light of different wavelengths toward the portion to be tested, the photodetector can sequentially receive the reflected light reflected by the portion to be tested, so that the photodetector can be appropriately The physiological sensing signal is generated according to the reflected light, and has the effect of improving the measurement accuracy.

The controller further has a controller electrically connected to the illuminating component, and the controller is configured to control the plurality of illuminating segments to randomly emit light of different wavelengths. Therefore, when the plurality of light exiting segments sequentially emit light of different wavelengths toward the portion to be tested, the photodetector can sequentially receive the reflected light reflected by the portion to be tested, so that the photodetector can be appropriately The physiological sensing signal is generated according to the reflected light, and has the effect of improving the measurement accuracy.

The number of the plurality of light exiting segments is three, and is respectively a red light exiting section, a green light emitting section, and a blue light emitting section. Thereby, the light-emitting component can emit light having a plurality of different wavelengths, and when the light-emitting component emits light having several different wavelengths toward the portion to be tested of the subject, even if some of the light is characterized by its own wavelength However, it is impossible to smoothly pass through the human tissue, and some of the light can be smoothly irradiated to the part to be tested according to the characteristics of its own wavelength, thereby smoothly generating the physiological sensing signal, and has the effect of smoothly generating the physiological sensing signal.

The plurality of light-emitting diodes each have at least one micro-light-emitting diode, and the micro-light-emitting diode has a size length of 20 μm×20 μm. Thereby, not only the light-emitting component can be reduced in energy consumption, but also the overall volume of the light-emitting component can be reduced, and the finer light can be accurately irradiated to accurately irradiate the portion to be tested, thereby improving the sensing accuracy.

The physiology sensor has a wireless transmission module, and the processor has a wireless transceiver module. The wireless transmission module of the physiological sensor is electrically connected to the wireless transceiver module of the processor. Thereby, the processor can be electrically connected to the physiological sensor through the wireless transceiver module, which has the effect of improving data transmission convenience.

The wireless transmission module and the wireless transceiver module are a wifi communication architecture, a zigbee communication architecture or a Bluetooth communication architecture. Thereby, the processor can be electrically connected to the physiological sensor through the wireless transceiver module, which has the effect of improving data transmission convenience.

The reference waveform data and the reference waveform data have the same one sensing condition. Thereby, the processor can compare the reference waveform data of the current state of the same subject and the reference waveform data of the health state, and the processor can issue when the reference waveform data and the reference waveform data have a large difference Corresponding to the driving signal, and for the relevant personnel to understand the comparison result, it has the effect of improving the health management effect.

The reference waveform data and the reference waveform data are both an electrocardiogram waveform and an electromyogram waveform. Thereby, the processor can compare the reference waveform data of the current state of the same subject and the reference waveform data of the health state, and the processor can issue when the reference waveform data and the reference waveform data have a large difference Corresponding to the driving signal, and for the relevant personnel to understand the comparison result, it has the effect of improving the health management effect.

The electronic device is electrically connected to the processor to receive the driving signal. The electronic device has an alarm, and the warning device sends a warning message after receiving the driving signal. Thereby, the warning device of the electronic device can issue a warning message when the reference waveform data and the reference waveform data have a large difference, and the related personnel can understand the comparison result, and have the effect of improving health management effectiveness.

There is another electronic device, the electronic device is electrically connected to the processor to receive the reference waveform data, and the electronic device has a display for displaying the reference waveform data. Thereby, the display of the electronic device can be used to display the reference waveform data, and the relevant person can view the sensing result of the physiological sensor through the display, thereby improving the health management effect.

The electronic device is a mobile communication device. Thereby, when the electronic device has the alarm or the display, the relevant person can directly understand the comparison knot through the electronic device. If you look at the sensory results, you can improve your health management results.

The physiological sensor is a three-lead heart rate signal sensor. Thereby, the three-lead heart rate signal sensor can directly detect the change of the state of the signal when the heart rate is normal or abnormal, and has the effect of smoothly generating the physiological sensing signal.

〔this invention〕

1‧‧‧Cloud database

2‧‧‧ Physiological sensor

21‧‧‧Wireless Transmission Module

22‧‧‧Resistive substrate

22a‧‧‧Sense surface

23‧‧‧Metal nanowire array

22'‧‧‧Photoelectric substrate

22a’‧‧‧ Launch Area

22b’‧‧‧ receiving area

23’‧‧‧Lighting components

231’‧‧‧Lighting section

231a’‧‧‧Red light exit section

231b’‧‧‧Green light section

231c’‧‧‧Blu-ray section

24'‧‧‧Photodetector

3‧‧‧ Processor

31‧‧‧Wireless transceiver module

4‧‧‧ Controller

5‧‧‧Electronic equipment

51‧‧‧ Warning device

52‧‧‧ display

Figure 1: Block diagram of the remote care system of the present invention.

Figure 2: Schematic diagram of the physiological sensor of the remote care system of the present invention.

Figure 3: Schematic diagram of the physiological sensor of the remote care system of the present invention.

The above and other objects, features, and advantages of the present invention will become more apparent from the aspects of the appended claims. The remote care system of the present invention comprises a cloud database 1, a physiological sensor 2 and a processor 3. The processor 3 is electrically connected to the cloud database 1 and the physiological sensor 2.

The cloud database 1 is for storing a reference waveform data. The cloud database 1 may be a remote database for accessing data through a wired network or a wireless network, such as Dropbox. Moreover, the manner of establishing the reference waveform data is not limited herein. For example, when the physical state of a subject to be tested is good, the physiological sensor 2 can sense a part to be tested of the subject to generate a a reference physiological signal, and the reference physiological signal is converted into the reference waveform data by the processor 3, and the processor 3 transmits and stores the reference waveform data in the cloud database 1 to make the cloud database 1 The stored reference waveform data can be used as a subsequent comparison. Moreover, the cloud database 1 can also store a plurality of reference waveform data, and the plurality of reference waveform data can respectively represent the reference physiological signals of different subjects.

The physiological sensor 2 is used to sense the part to be tested and generate a physiological induction Signal. The physiological sensor 2 can be a resistive sensor, a photoelectric sensor or a three-lead heart rate signal sensor for directly detecting normal and abnormal heart rate through the three-lead heart rate signal sensor. The condition of the signal changes, and the physiological sensor 2 can also be combined with a wearable device for the wearer to perform, and is not limited herein. Moreover, the physiological sensor 2 preferably has a wireless transmission module 21, and the wireless transmission module 21 can be a wifi communication architecture, a zigbee communication architecture or a Bluetooth communication architecture, whereby the physiological sensor 2 The processor 3 can be electrically connected through the wireless transmission module 21, which has the effect of improving data transmission convenience.

Referring to FIG. 2 , for example, when the physiological sensor 2 is the resistive sensor, the physiological sensor 2 further includes a resistive substrate 22 and a metal sheath in addition to the wireless transmission module 21 . The rice-wire array 23 has a sensing surface 22a. The metal nanowire array 23 is disposed on the sensing surface 22a of the resistive substrate 22, and the metal nanowire array 23 is used for sensing. The resistance value of one of the parts to be tested, and the physiological induction signal is generated according to the resistance value. Thereby, the physiological sensor 2 can transmit the physiological sensing signal through the sensing resistance value, and has the effect of smoothly generating the physiological sensing signal.

As shown in FIG. 3 , for example, when the physiological sensor 2 is the photoelectric sensor, the physiological sensor 2 further includes a photoelectric substrate 22 ′ and a light-emitting component. 23' and a photodetector 24', the surface of the optoelectronic substrate 22' is divided into an emitting area 22a' and a receiving area 22b', and the light emitting component 23' is disposed in the emitting area 22a' The at least one light is emitted from the portion to be tested, and the photodetector 24' is disposed at the receiving portion 22b' to receive at least one reflected light reflected by the portion to be tested, and generates the physiological sensing signal according to the at least one reflected light. . Thereby, the physiological sensor 2 can transmit the physiological sensing signal through the light sensing, and has the effect of smoothly generating the physiological sensing signal.

Wherein, when the physiological sensor 2 is the photoelectric sensor, the light-emitting component 23' has a plurality of light-emitting segments 231' arranged at intervals in the array region D in the emitter region 22a. ', the alignment direction D may be parallel to the surface of the photovoltaic substrate 22', And the light emitted by each of the plurality of light exiting segments 231' has a different wavelength. The number of the plurality of light exiting segments 231' is not limited thereto. In this embodiment, the number of the plurality of light exiting segments 231' is three, and each is a red light emitting segment 231a', a green The light exiting section 231b' and a blue light exiting section 231c'. Thereby, the light-emitting component 23' can emit light having several different wavelengths, and when the light-emitting component 23' emits light having several different wavelengths toward the portion to be tested of the subject, even if some light is caused The characteristics of the self-wavelength cannot pass through the human body smoothly, and some of the light can be smoothly irradiated to the part to be tested according to the characteristics of its own wavelength, thereby smoothly generating the physiological sensing signal, and the effect of smoothly generating the physiological sensing signal is obtained.

Moreover, the plurality of light-emitting segments 231' each have at least one micro-light-emitting diode (μLED), and the size of the micro-light-emitting diode is 20 μm×20 μm, and the micro-light-emitting diode can be disposed not only by the micro-light emitting diode. The light-emitting component 23' has a lower energy consumption, and can reduce the overall volume of the light-emitting component 23', and can also accurately illuminate the portion to be tested by transmitting finer light, which has the effect of improving the sensing accuracy.

Referring to FIG. 1 again, the processor 3 is electrically connected to the cloud database 1 to read the reference waveform data, and is electrically connected to the physiological sensor 2 to receive the physiological sensing signal. The processor 3 Converting the physiological sensing signal into a reference waveform data, and comparing the reference waveform data and the reference waveform data to a frequency error amount and a peak error amount, and the frequency error amount is not less than a frequency threshold value and the When the peak error amount is not less than a peak threshold, a driving signal is generated. The processor 3 can be any processor with logical operation and statistical analysis, and the processor 3 can execute a signal processing program, and the signal processing program can convert the physiological sensing signal into a related waveform signal. It is well known to those skilled in the art and will not be described herein.

Moreover, the processor 3 preferably has a wireless transceiver module 31. The wireless transceiver module 31 of the processor 3 is electrically connected to the wireless transmission module 21 of the physiological sensor 2, and the wireless transceiver module 31 may be the wifi communication architecture, the zigbee communication architecture or the Bluetooth Communication architecture. Therefore, the processor 3 can be electrically connected to the physiological sensor 2 through the wireless transceiver module 31, which has the effect of improving data transmission convenience.

The reference waveform data and the reference waveform data may be any physiologically related waveform data. In this embodiment, the reference waveform data and the reference waveform data may all be an electrocardiogram (ECG); or both An electromyogram (EMG); in addition, the reference waveform data and the reference waveform data are preferably used to have the same sensing condition. In this embodiment, the sensing condition includes the When the reference waveform data and the reference waveform data have the same sensing condition, the reference waveform data and the reference waveform data are both from the same side of the test subject. Part sensing is produced. Thereby, the processor 3 can compare the reference waveform data of the current state of the same subject with the reference waveform data of the health state, and the processor 3 can have a large difference between the reference waveform data and the reference waveform data. The corresponding driving signal is issued and the relevant personnel are informed of the comparison result, which has the effect of improving the health management effect.

In more detail, since the cloud database 1 has stored the reference waveform data, and the physiological sensor 2 can instantly sense the portion to be tested of the subject and generate the physiological sensing signal, when the processor 3 When receiving the physiological sensing signal and converting the physiological sensing signal into the reference waveform data, the processor 3 can read the reference waveform data of the same side of the same subject in the cloud database 1 And whether there is a difference between the reference waveform data and the reference waveform data. In the process of comparison, the processor 3 can compare the frequency error amount of the reference waveform data and the reference waveform data with the peak error amount, and the frequency error amount is not less than the frequency threshold value and the peak error amount When the threshold value is not less than the peak threshold value, the driving signal is generated to actuate the related electronic device, and the effect of the message prompting is achieved through the electronic device. Thereby, the processor 3 can compare the reference waveform data of the current state of the same test subject with the reference waveform data of the health state, and the processor 3 can have a larger reference data and the reference waveform data. Corresponding to the driving signal when the difference is made, and for the relevant personnel (for example, the waiting The tester or medical staff) understands the results of the comparison and has the effect of improving the effectiveness of health management.

Wherein, the frequency threshold value can be set to 10% of the frequency value of the reference waveform data; the peak threshold value can be set to 10% of the peak value of the reference waveform data. Therefore, when the frequency threshold value and the peak threshold value are set to the foregoing value, the processor 3 may issue the corresponding driving signal when the reference waveform data and the reference waveform data have a specific difference, and provide the relevant driver ( For example, the test subject or medical staff) understands the results of the comparison and has the effect of improving the health management effectiveness.

Moreover, when the frequency error amount is not less than the frequency threshold and the peak error amount is not less than the peak threshold, the processor 3 may also transmit the reference waveform data to the cloud database 1 as an abnormal record. data. Thereby, the processor 3 can compare the reference waveform data of the current state of the same subject with the reference waveform data of the health state, and the processing is different when the reference waveform data and the reference waveform data have a large difference. The device 3 can transmit the reference waveform data to the cloud database 1 as the abnormal record data for the relevant person (for example, the test subject or the medical staff) to understand the comparison result, and has the effect of improving the health management effect.

Referring to FIG. 1 and FIG. 3 again, the remote care system of the present invention may further have a controller 4 electrically connected to the lighting component 23'. The controller 4 is used to control the plurality of controllers. The light exiting section 231' sequentially emits light of different wavelengths along the array direction D. In this embodiment, the plurality of light exiting segments 231' are respectively the red light exiting section 231a', the green light emitting section 231b', and the blue light exiting section 231c', and the controller 4 can control the red light emitting light. The segment 231a', the green light exiting segment 231b', and the blue light exiting segment 231c' are sequentially emitted. In this way, when the plurality of light exiting segments 231' sequentially emit light of different wavelengths toward the portion to be tested, the photodetector 24' can sequentially receive the reflected light reflected by the portion to be tested, so that the light detecting The detector 24' can generate the physiological sensing signal according to the reflected light (for example, only the reflected light of a specific wavelength is captured, or the physiological sensing signal is generated according to the order of the reflected light), and the measurement accuracy is improved. effect.

Or, in the remote care system of the present invention having the controller 4, The controller 4 is electrically connected to the light-emitting component 23', and the controller 4 is configured to control the plurality of light-emitting segments 231' to randomly emit light of different wavelengths. In this embodiment, the plurality of light exiting segments 231' are respectively the red light exiting section 231a', the green light emitting section 231b', and the blue light exiting section 231c', and the controller 4 can control the red light emitting light. The segment 231a', the green light exiting segment 231b', and the blue light exiting segment 231c' are randomly emitted. Therefore, when the plurality of light-emitting segments 231' randomly emit light of different wavelengths toward the portion to be tested, the photodetector 24' can randomly receive the reflected light reflected by the portion to be tested, so that the photodetector 24' can appropriately generate the physiological sensing signal according to the reflected light (for example, only capturing the reflected light of a specific wavelength, or generating the physiological sensing signal according to the randomness of the reflected light), and has the effect of improving the measurement accuracy.

Referring to FIG. 1 again, the remote care system of the present invention may further have an electronic device 5 electrically connected to the processor 3 to receive the driving signal. The electronic device 5 has a warning device 51. The alerter 51 sends a warning message after receiving the driving signal. The alerter 51 can be a broadcast device, and the broadcast device can sound a warning sound after receiving the drive signal. Thereby, the alerter 51 of the electronic device 5 can send a warning message when the reference waveform data and the reference waveform data have a large difference, and the relevant personnel (for example, the test subject or the medical staff) can understand the comparison result. It has the effect of improving the effectiveness of health management.

Moreover, in the remote care system of the present invention having the electronic device 5, the electronic device 5 is electrically connected to the processor 3 to receive the reference waveform data, and the electronic device 5 has a display 52. To display the reference waveform data. Thereby, the display 52 of the electronic device 5 can be used to display the reference waveform data, and the relevant personnel (for example, the test subject or the medical staff) can view the sensing result of the physiological sensor 2 through the display 52, and have improved health management. The effect of the results.

Furthermore, the electronic device 5 can be a mobile communication device such as a mobile phone or a tablet computer. Therefore, when the electronic device 5 has the alerter 51 or the display 52, the relevant person (for example, the test subject or the medical staff) can directly pass the alerter 51 of the electronic device 5. Knowing the comparison result, or viewing the sensing result through the display 52 of the electronic device 5, has the effect of improving health management effectiveness.

In summary, the remote care system of the present invention can compare the reference waveform data of the current state of the same test subject with the reference waveform data of the health state through the processor 3, and in the reference waveform data and the When the reference waveform data has a large difference, the corresponding driving signal is issued, and the relevant personnel (for example, the test subject or the medical staff) understand the comparison result, and the effect of improving the health management effect is improved.

While the invention has been described in connection with the preferred embodiments described above, it is not intended to limit the scope of the invention. The technical scope of the invention is protected, and therefore the scope of the invention is defined by the scope of the appended claims.

1‧‧‧Cloud database

2‧‧‧ Physiological sensor

21‧‧‧Wireless Transmission Module

3‧‧‧ Processor

31‧‧‧Wireless transceiver module

4‧‧‧ Controller

5‧‧‧Electronic equipment

51‧‧‧ Warning device

52‧‧‧ display

Claims (20)

A remote care system includes: a cloud database for storing a reference waveform data and an abnormal record data; a physiological sensor for sensing a portion to be tested and generating a a physiological sensing signal; and a processor electrically connected to the cloud database to read the reference waveform data, and electrically connected to the physiological sensor to receive the physiological sensing signal, the processor is the physiological The sensing signal is converted into a reference waveform data, and the frequency error amount and the peak error amount of the reference waveform data and the reference waveform data are compared, and the error amount is not less than a frequency threshold value and the peak error amount is not When less than a peak threshold, the processor generates a driving signal and transmits the reference waveform data to the cloud database as the abnormal recording data. The remote care system of claim 1, wherein the frequency threshold is 10% of a frequency value of the reference waveform data. The remote care system of claim 1, wherein the peak threshold value is 10% of a peak value of the reference waveform data. The remote care system of claim 1, wherein the physiological sensor is a resistive sensor. The remote care system of claim 4, wherein the resistive inductor comprises a resistive substrate and a metal nanowire array, the resistive substrate having a sensing surface, the metal nanowire array The sensing surface of the resistive substrate is disposed, and the metal nanowire array is configured to sense a resistance value of the portion to be tested, and generate the physiological sensing signal according to the resistance value. The remote care system of claim 1, wherein the physiological sensor is A photoelectric sensor. The remote care system of claim 6, wherein the photoelectric sensor comprises a photoelectric substrate, a light emitting component and a light detector, the surface of the photoelectric substrate is divided into a transmitting area and a receiving The light emitting component is disposed in the emitting area and configured to emit at least one light toward the detecting portion, the photodetector is disposed in the receiving area and configured to receive at least one reflected light reflected by the portion to be tested, and The physiological sensing signal is generated according to the at least one reflected light. The remote care system of claim 7, wherein the light-emitting component has a plurality of light-emitting segments, and the plurality of light-emitting segments are arranged in the array in an arrangement direction, and each of the plurality of light-emitting segments A emitted light has a different wavelength. The remote care system of claim 8 , further comprising a controller electrically connected to the light emitting component, wherein the controller is configured to control the plurality of light exit segments in the aligned direction Light from different wavelengths. The remote care system of claim 8, wherein the controller further electrically connects the light-emitting component, and the controller is configured to control the plurality of light-emitting segments to randomly emit light of different wavelengths. . The remote care system of claim 8, wherein the number of the plurality of light exit segments is three, and is a red light exit section, a green light exit section, and a blue light exit section. The remote care system of claim 8, wherein the plurality of light-emitting segments each have at least one micro-light-emitting diode, and the micro-light-emitting diode has a size length of 20 μm×20 μm. The remote care system of claim 1, wherein the physiological sensor has a wireless transmission module, the processor has a wireless transceiver module, and the wireless transmission module of the physiological sensor is electrically connected to the The wireless transceiver module of the processor. The remote care system of claim 13, wherein the wireless transmission module And the wireless transceiver module is a wifi communication architecture, a zigbee communication architecture or a Bluetooth communication architecture. The remote care system of claim 1, wherein the reference waveform data and the reference waveform data have the same one sensing condition. The remote care system of claim 1, wherein the reference waveform data and the reference waveform data are an electrocardiogram waveform or an electromyogram waveform. The remote care system of claim 1, further comprising an electronic device electrically connected to the processor to receive the driving signal, the electronic device having an alarm, the warning device being attached to A warning message is sent after receiving the drive signal. The remote care system of claim 1, further comprising an electronic device electrically connected to the processor to receive the reference waveform data, the electronic device having a display for displaying This reference waveform data. The remote care system of claim 17 or 18, wherein the electronic device is a mobile communication device. The remote care system of claim 1, wherein the physiological sensor is a three-lead heart rate signal sensor.