TW202123255A - Health management system using non-contact imaging-based physiological measurement technology - Google Patents

Abstract

The present invention discloses a health management system using non-contact imaging-based physiological measurement technology, comprising an image capturing unit, a core calculation module having a face detecting unit, a physiological parameter calculating unit and an activity parameter calculating unit. The face detecting unit is configured for detecting a face region from a user image, such that the physiological parameter calculating unit is able to obtain at least one physiological signal from the face region, thereby calculating a plurality of physiological parameters based on the physiological signal. Consequently, the activity parameter calculating unit is able to calculate a plurality of activity parameters based on the physiological parameters. Particularly, besides displaying the user’s current activity parameters and/or physiological parameters by a form of at least one graph or diagram, the display unit can also show the user’s statistical graphic activity parameters and/or statistical graphic physiological parameters in a specific time interval, such that it is facilitated to evaluate the health state of the user.

Description

Health management system using non-contact imaging physiological detection technology

The present invention relates to the technical field of physiological signal detection, in particular to a health management system using non-contact image-based physiological detection technology, which further completes multiple physiological indexes of the user by capturing a user’s face image. Calculation of multiple vitality indexes; at the same time, a long-term health report of the user can be created and displayed on a display screen, thereby effectively managing the user's physical and vital health status.

Physiological information such as blood oxygen concentration and heartbeat are important indicators for judging a person's health status. With the vigorous development of wearable device technology, the usage rate of wearable electronic products such as smart bracelets or smart watches is increasing year by year. In addition to pairing with the user’s own smartphone and/or tablet, the most important function provided by wearable electronic products is health monitoring, including: sleep recording, heart rate measurement, blood pressure measurement, fatigue management, and Stress management, etc. In addition, with the use of specially designed applications (App), the wearable electronic product can also be used as a health management system to manage the user's physical health status. For example, Taiwan Model Patent No. TW M578864 discloses a health management system for wearable devices. Unfortunately, if the user forgets to wear a smart bracelet or smart watch equipped with the app of the health management system, the health management system cannot collect the user’s physiological data through the smart bracelet or smart watch. At the same time, user health management cannot be performed. In addition, user feedback points out that long-term wearing of wearable devices such as smart bracelets or smart watches will cause many inconveniences, such as skin allergies for users with sensitive skin.

Therefore, unlike the health management system described above, a wearable device must be used. Taiwan Invention Patent No. TW I653601 proposes a health management system including a host and one or more physiological measuring instruments, which are usually placed in a public space. For example: hospitals or supermarkets. When using the health management system, the user can input personal data including height, weight, and age through a human-machine interface of the host, and then use the physiological measuring instrument to complete the measurement of other physiological parameters, so that the host can complete all the measurements. The production of the user’s personal health scale. It is a pity that the health management system provided by the prior art includes a host computer and multiple physiological measuring instruments, resulting in a high cost of equipment construction. Therefore, it is usually used for public use and cannot be used by individual users at home.

Therefore, unlike the health management system for public use described above, Taiwan Invention Publication No. TW 201143712 A proposes a handheld health management device that measures the physiological value of the user through at least one contact measurement unit. Including blood pressure, blood sugar, body temperature, weight, body fat, etc. The handheld health management device also includes a warning element for selectively sending a warning signal according to the measurement result of the user's physiological value, so as to warn the user that a certain physiological value exceeds a standard value. Unfortunately, when using the handheld health management device provided by the conventional technology, the user still needs to use the contact measurement unit to be able to complete the measurement of various physiological parameters. Cause a certain degree of inconvenience.

It can be seen from the foregoing description that although the prior art has provided various types of health management systems, these health management systems have shown their own shortcomings and deficiencies in practical use. On the other hand, the personal health scales produced by these health management systems usually only integrate and list all physiological measurement values. Therefore, after reading the personal health scale, it is difficult for general users to intuitively (in a short period of time) feel their physical and/or psychological health status.

In view of this, the inventor of this case tried his best to research and invent, and finally developed a health management system using non-contact imaging physiological detection technology of the present invention.

The main purpose of the present invention is to provide a health management system using non-contact imaging physiological detection technology, which mainly includes: an image capture unit, a face detection unit, a physiological index calculation unit, and a vitality index calculation unit A core computing module and a display unit. The face detection unit is used to detect a face part from an image of a subject, so that the physiological index calculation unit can obtain at least one physiological signal from the face part, so that the at least one physiological signal The signal performs at least one signal processing to obtain multiple physiological indices of the subject. Further, the vitality index calculation unit calculates multiple vitality indices of the subject according to the multiple physiological indices. In particular, in addition to real-time display of the subject’s current physiological index and vitality index through a chart, the display unit can also display the subject’s physiological index chart and vitality index chart over a period of time, so that it is easy to evaluate Whether the health status of the testee does not deviate from the normal standard.

To achieve the above objective, the present invention proposes an embodiment of the health management system using non-contact imaging physiological detection technology, which includes: An image capturing unit for facing a subject to capture an image of the subject; A core computing module, coupled to the image capturing unit, and including: A face detection unit for receiving the subject image transmitted by the image capturing unit, so as to detect a face part from the subject image; A physiological index calculation unit, coupled to the face detection unit, for obtaining at least one physiological signal from the face part, so as to perform at least one signal processing on the at least one physiological signal to obtain the measured Multiple physiological indexes of the person; and A vitality index calculation unit, coupled to the physiological index calculation unit, for calculating multiple vitality indices of the subject according to the multiple physiological indices; and A display unit, coupled to the core computing module, is used to display the multiple vitality indexes, at least one graphical vitality index data, the multiple physiological indexes, and/or at least one graphical physiological index data.

In the foregoing embodiment of the health management system using the non-contact imaging physiological detection technology of the present invention, the multiple physiological indexes include: heart rate, heart rhythm variability, respiration rate, blood volume, blood oxygen, blood pressure, blood vessel viscosity (Blood vessel viscosity), venous function, venous return, ankle pressure, genital responses, and Cardiac output.

In the foregoing embodiment of the health management system using the non-contact imaging physiological detection technology of the present invention, the multiple vitality indexes include: health, activity, stability, stress relief, metabolism, and balance.

In a feasible embodiment of the aforementioned health management system using non-contact imaging physiological detection technology of the present invention, the image capturing unit is a stand-alone camera, and the core computing module is integrated in an electronic host device; Among them, the electronic host device can be any of the following: cloud server, desktop computer, All-In-One computer, embedded system, notebook computer, tablet computer, smart phone, smart phone Watches, smart glasses, smart TVs, smart display devices, smart home door phones, or home care system hosts.

In another feasible embodiment of the health management system using non-contact imaging physiological detection technology of the present invention, the image capturing unit and the core computing module are integrated in the same electronic product, and the electronic product may be Any of the following: All-In-One computers, embedded systems, laptops, tablets, smart phones, smart watches, smart glasses, smart TVs, smart display devices, smart Camera, smart home door phone, or home care system host.

In a feasible embodiment of the aforementioned health management system using non-contact imaging physiological detection technology of the present invention, the display unit is a stand-alone display, and the core computing module is integrated in an electronic host device; wherein, The stand-alone display can be any one of the following: a television, a desktop display, a portable display, a projection display, a smart display, or a touch display. And, the electronic host device can be any of the following: cloud server, desktop computer, all-in-one computer, notebook computer, tablet computer, smart phone, smart watch, smart glasses, smart TV, smart Home door phone, smart camera, or home care system host.

In another feasible embodiment of the aforementioned health management system of the present invention using non-contact imaging physiological detection technology, the display unit and the core computing module are integrated in the same electronic product, and the electronic product can be any of the following One: All-in-one computer, notebook computer, tablet computer, smart phone, smart watch, smart glasses, smart TV, smart display device, smart home door phone, or home care system host.

In a feasible embodiment, the health management system using non-contact imaging physiological detection technology of the present invention may further include: A storage unit, coupled to the core computing module, for storing the plurality of vitality indexes and the plurality of physiological indexes; and A main control unit, coupled to the storage unit, the image capturing unit, the core computing module, and the display unit, for controlling the operation of the image capturing unit and the core computing module, and controlling the display unit The multiple vitality indexes, the multiple physiological indexes, the graphical vitality index data, and/or the graphical physiological index data are displayed.

In a feasible embodiment, a face recognition unit can be further provided in the core computing module of the health management system using non-contact imaging physiological detection technology of the present invention, which is coupled to the face detection unit, And it is used to obtain a face feature information from the face part, and then perform a feature matching process based on the face feature information and a face feature template stored in the storage unit to complete the test of the subject Body discernment.

In the foregoing embodiment of the health management system using non-contact imaging physiological detection technology of the present invention, the storage unit includes: A user identity database for storing a plurality of the facial feature templates and a plurality of user personal data, wherein each of the facial feature templates is recorded according to the corresponding subject 2 and is associated with each of the users Correspondence of personal data; An index database for storing the plurality of vitality indexes and the plurality of physiological indexes according to the personal data of each user; and A chart database for storing the at least one charted vitality index data and the at least one charted physiological index data according to each of the user personal data; Wherein, the graphed vitality index data and the graphed physiological index data both include a real-time data part and a historical data part.

In a feasible embodiment, a health status evaluation unit may be further provided in the core computing module of the health management system using the non-contact imaging physiological detection technology of the present invention, which is coupled to the physiological index computing unit and The vitality index calculation unit is used to evaluate a health condition of the subject according to the at least one graphical vitality index data and the at least one graphical physiological index data, and when the health condition does not meet the standard Next, the health assessment unit transmits a warning signal to the main control unit, so that the main control unit controls the display unit to display a warning message.

In a possible embodiment, the health management system using non-contact imaging physiological detection technology of the present invention further includes a communication unit coupled to the main control unit to enable the main control unit to communicate with an external electronic device Mutual communication; wherein, the communication unit includes a wired transmission interface and/or a wireless transmission interface.

In order to be able to more clearly describe the health management system using non-contact imaging physiological detection technology proposed by the present invention, the preferred embodiments of the present invention will be described in detail below in conjunction with the diagrams.

Figure 1 shows a first schematic perspective view of the first embodiment of a health management system using non-contact imaging physiological detection technology of the present invention, and Figure 2 shows the health management system of the present invention using non-contact imaging physiological detection technology The second schematic perspective view of the first embodiment, and FIG. 3 shows the block diagram of the first embodiment of the health management system using the non-contact imaging physiological detection technology of the present invention. As shown in FIGS. 1 and 3, the health management system 1 (hereinafter referred to as "health management system") using non-contact imaging physiological detection technology of the present invention mainly includes: an image capture unit 11 and a core computing module 12 And a display unit 13. It is worth noting that, FIG. 1 shows that the core computing module 12 is integrated in an electronic device 3 in the form of an electronic chip, and the electronic device 3 has the display unit 13. Although FIG. 1 shows that the electronic device 3 is a home care system host, in a feasible embodiment, the electronic device 3 may also be: an All-In-One computer, a notebook computer, a tablet computer, Electronic products with displays such as smart phones, smart watches, smart glasses, smart TVs, smart display devices, or smart home door phones.

On the other hand, FIG. 2 shows that the core computing module 12 is integrated in an electronic device 3 in the form of an electronic chip, and the display unit 13 is a stand-alone display. Although FIG. 2 shows that the display unit 13 is a flat panel display, in feasible embodiments, the display unit 13 may also be a television, a desktop display, a portable display, a projection display, and a touch display. Simply put, the present invention does not limit whether the core computing module 12 and the display unit 13 are integrated in the same electronic device 3. For example, the core computing module 12 may be set in a cloud computing server, or may be set in a local host electronic device.

In the first embodiment of the health management system 1 of the present invention, the image capturing unit 11 is used to face a subject 2 to capture an image of the subject. It should be understood that, in a feasible embodiment, the image capturing unit 11 and the core computing module 12 can be integrated in the same electronic device 3. For example, the electronic device 3 is a smart phone or a notebook. Electronic products such as computers, tablets, embedded devices, smart TVs, etc. When the core computing module 12 is set in a local electronic host or a cloud server, the image capturing unit 11 is a stand-alone camera (as shown in FIG. 2).

In more detail, the core computing module 12 is coupled to the image capturing unit 11, and has a face detection unit 121, a physiological index computing unit 122, and a vitality index computing unit 123. It should be understood that since the core computing module 12 is integrated in the electronic device 3 in the form of an electronic chip, the face detection unit 121, the physiological index computing unit 122, and the vitality index computing unit 123 can be transmitted through The form of a function library, a variable or an operand is edited into at least one application program, which is then built in the core computing module 12. According to the design of the present invention, the face detecting unit 121 is used to receive the subject image transmitted by the image capturing unit 11, so as to detect a face part from the subject image.

In accordance with the above description, the physiological index calculation unit 122 is coupled to the face detection unit 121 to obtain at least one physiological signal from the face part, so as to perform at least one signal processing on the at least one physiological signal. To obtain multiple physiological indexes of the subject 2. Moreover, the vitality index calculation unit 123 is coupled to the physiological index calculation unit 122 to calculate multiple vitality indices of the subject 2 according to the multiple physiological indices. In a feasible embodiment, the multiple physiological indexes include: heart rate, heart rhythm variability, respiratory rate, blood volume, blood oxygen, blood pressure, blood vessel viscosity, venous function, venous return, ankle pressure, genital response (Genital responses), and Cardiac output. On the other hand, the multiple vitality indexes include: health, activity, stability, stress relief, metabolism, and balance.

As shown in FIGS. 1 and 2, the health management system 1 of the present invention further includes a storage unit 14 and a main control unit 10. Wherein, the storage unit 14 is coupled to the core computing module 12 for storing the plurality of vitality indexes and the plurality of physiological indexes. In one embodiment, the physiological index calculation unit 122 may be designed to further generate at least one graphical physiological index data based on the multiple physiological indexes, and the vitality index calculation unit 123 may further based on the multiple vitality indexes. Generate at least one graphical vitality index data. Of course, the main control unit 10 or a dedicated chart generating unit (not shown) can also be used to retrieve the multiple physiological indices and/or multiple vitality indices from the storage unit 14, thereby producing at least one of the graphical charts. Physiological index data and/or at least one of said graphical vitality index data. On the other hand, the main control unit 10 is coupled to the storage unit 14, the image capturing unit 11, the core computing module 12, and the display unit 13, for controlling the image capturing unit 11 and the core computing module Group 12, and transmit the graphical vitality index data and the graphical physiological index data stored in the storage unit 14 to the display unit 13, so that the display unit 13 displays the multiple vitality indexes, at least one The graphed vitality index data, the multiple physiological indexes, and/or at least one of the graphed physiological index data.

FIG. 4A shows a six-force diagram of a graphical vitality index data, and FIG. 4B shows a six-force diagram of another graphical vitality index data. The six forces chart in Fig. 4A shows that subject 2 has a higher value in all vitality indexes, which means that subject 2’s current mental, psychological, and/or physical health conditions are very ideal and even lively. On the contrary, it can be found from the six forces chart in Fig. 4B that the values of the vitality indices of the subject 2 are all low, which means that the current mental, psychological, and/or physical health conditions of the subject 2 tend to be subdued. To put it simply, the health management system 1 of the present invention can convert multiple physiological indexes of the subject 2 into multiple vitality indexes, and present the multiple vitality indexes in the form of graphs, so that the subject 2 can read the graph data, Able to intuitively (in a short period of time) feel the changes in their physical and/or mental health.

In addition, for example, in the case where the six-force diagram shows that the testee 2 has high health and activity and low balance, it can be inferred that the testee 2 is in a concentrated, tense and stressful situation. Or, for example, when the six-force diagram shows that the balance and metabolism of the subject 2 are high, but the activity and health are low, it means that the subject 2 is in a state of mental relaxation. Therefore, in order to further analyze the plurality of vitality indexes, at least one of the graphical vitality index data, the plurality of physiological indexes, and/or at least one of the graphical physiological index data to complete a test for the subject 2 For real-time health evaluation, the present invention completes the second embodiment of the health management system 1 of the present invention using non-contact imaging physiological detection technology by adding a health evaluation unit 125 in the core computing module 12 .

FIG. 5 shows a block diagram of a second embodiment of the health management system using non-contact imaging physiological detection technology of the present invention. As shown in FIGS. 1 and 5, the storage unit 14 is internally planned to include an index database 141 and a chart database 142; wherein, the index database 141 is used to store the plurality of vitality indexes and the plurality of physiological indexes. Index, and the graph database 142 is used to store the at least one graphed vitality index data and the at least one graphed physiological index data. Moreover, it can be seen from FIG. 5 that the core computing module 12 further has a health evaluation unit 125, which is coupled to the physiological index computing unit 122 and the vitality index computing unit 123.

It must be noted that after receiving the non-contact measurement of the health management system 1 of the present invention at different times, the values of the vitality indices displayed by the same subject 2 may not be the same (as shown in Figure 4A And shown in Figure 4B). Therefore, after the health management system 1 of the present invention completes the measurement operation, the physiological index calculation unit 122 and the vitality index calculation unit 123 store the multiple physiological indexes and the multiple vitality indexes in the index database of the storage unit 14 141 among. At the same time, the physiological index calculation unit 122 and the vitality index calculation unit 123 will also store the at least one graphical physiological index data and the at least one graphical vitality index data into the chart database 142 of the storage unit 14. Finally, the health status evaluation unit 125 can display the graphical vitality index data and/or the graphical physiological index data including both the real-time data part and the historical data part through the display unit 13, as shown in FIG. In the graph of each vitality refers to the quantity value. After watching the change curve of the vitality index (or the change curve of physiological index) of the subject 2 within a period of time as shown in Figure 6, the subject 2 can also immediately know his physiological or physiological index during this period of time. The degree of ups and downs of the psychological condition.

Further, the health evaluation unit 125 of the core computing module 12 can evaluate the health status according to at least one graphical vitality index data (or at least one graphical physiological index data) as shown in FIGS. 4A and 4B. The health status of Subject 2. Alternatively, the health status evaluation unit 125 may also analyze the graph of time relative to the value of each vitality index (or the value of each physiological index) as shown in FIG. 6, so as to evaluate the subject 2’s State of health. Moreover, in the case where it is determined that the health status of the subject 2 does not meet the normal standard, the health status evaluation unit 125 transmits a warning signal to the main control unit 10, so that the main control unit 10 controls the display unit 13 to display a Warning information. For example. After analyzing the graphed vitality index data and the graphed physiological index data, if the health status assessment unit 125 finds that the subject 2 may be at risk of suffering from a specific disease, the relevant warning information can be displayed on the display unit 13. This reminds the subject 2 to seek professional medical assistance as soon as possible.

It can be inferred that the health management system 1 using the non-contact imaging physiological detection technology of the present invention can be further applied as a home health management system or a cloud health management system. In this case, a face recognition unit should be added to the core computing module 12. FIG. 7 shows a block diagram of the third embodiment of the health management system using non-contact imaging physiological detection technology of the present invention. As shown in FIGS. 1 and 7, the core computing module 12 further has a face recognition unit 124, and the storage unit 14 is planned to include an index database 141, a chart database 142, and a user identity data. Library 140. In the third embodiment, the user identity database 140 is used to store a plurality of personal facial feature templates and a plurality of user personal data, wherein each of the facial feature templates is recorded according to the corresponding subject 2 and is consistent with The personal data of each user corresponds to each other. On the other hand, the added face recognition unit 124 is coupled to the face detection unit 121 to obtain facial feature information from the face parts, and then according to the facial feature information and stored in the face A facial feature template in the storage unit 14 performs a feature matching process to complete the identification of the subject 2.

In normal operation, after the image capturing unit 11 captures an image of a subject, the face recognition unit 124 is based on the face parts detected by the face detection unit 121 and pre-stored in the user identity database 140 A plurality of pieces of the facial feature information among them are used to identify the identity of the subject 2. Subsequently, after the physiological index calculation unit 122 and the vitality index calculation unit 123 complete their work, the index database 141 will store the plurality of vitality indexes and the plurality of physiological indexes according to the identified personal data of the user, and the The graph database 142 also stores the at least one graphed vitality index data and the at least one graphed physiological index data according to the identified user personal data. Finally, the display unit 13 will display the multiple vitality indexes, at least one of the graphical vitality index data, the multiple physiological indexes, and/or at least one of the graphical physiological index data corresponding to the subject 2’s identity in real time. display.

Further, the present invention also proposes a fourth embodiment of the health management system 1 using the non-contact imaging physiological detection technology. FIG. 8 shows a schematic perspective view of the fourth embodiment of the health management system using non-contact imaging physiological detection technology of the present invention, and FIG. 9 shows the fourth embodiment of the health management system using non-contact imaging physiological detection technology of the present invention Block diagram of the embodiment. As shown in FIGS. 8 and 9, the health management system 1 of the present invention further includes a communication unit 15 which is coupled to the main control unit 10 and includes a wired transmission interface and/or a wireless transmission interface. It should be understood that the communication unit 15 is used to enable the main control unit 10 to communicate with an external electronic device 4, wherein the electronic device 4 is preferably an electronic product carried by the subject 2, such as a smart type Watches, smart phones, tablets, or laptops.

In this way, the above system has completely and clearly described all the embodiments and features of a health management system using non-contact imaging physiological detection technology of the present invention. It must be emphasized that the foregoing disclosures in this case are preferred embodiments, and any partial changes or modifications that are derived from the technical ideas of this case and are easily inferred by those who are familiar with the art will not deviate from the patent of this case. Right category.

>The invention> 1: Health management system using non-contact imaging physiological detection technology 10: Main control unit 11: Image capture unit 12: Core computing module 121: Face detection unit 122: Physiological Index Operation Unit 123: Vitality Index Operation Unit 124: Face Recognition Unit 125: Health Assessment Unit 13: display unit 14: storage unit 140: User Identity Database 141: Index Database 142: Chart Database 15: Communication unit 2: Subject 3: electronic device 4: External electronic device

>Learning> no

Fig. 1 shows a first schematic perspective view of a first embodiment of a health management system using non-contact imaging physiological detection technology according to the present invention; 2 shows a second schematic perspective view of the first embodiment of the health management system using non-contact imaging physiological detection technology of the present invention; 3 shows a block diagram of the first embodiment of the health management system using non-contact imaging physiological detection technology of the present invention; Figure 4A shows a six-force diagram of graphical vitality index data; Figure 4B shows another six-force graph showing vitality index data; 5 shows a block diagram of a second embodiment of the health management system using non-contact imaging physiological detection technology of the present invention; Figure 6 shows the curve diagram of time relative to the quantity value of each vitality index; FIG. 7 shows a block diagram of the third embodiment of the health management system using non-contact imaging physiological detection technology of the present invention; FIG. 8 shows a schematic perspective view of the fourth embodiment of the health management system using non-contact imaging physiological detection technology of the present invention; and FIG. 9 shows a block diagram of a fourth embodiment of the health management system using non-contact imaging physiological detection technology of the present invention.

1: Health management system using non-contact imaging physiological detection technology

10: Main control unit

11: Image capture unit

12: Core computing module

121: Face detection unit

122: Physiological Index Operation Unit

123: Vitality Index Operation Unit

13: display unit

14: storage unit

2: Subject

3: electronic device

Claims (17)

A health management system using non-contact imaging physiological detection technology, including: An image capturing unit for facing a subject to capture an image of the subject; A core computing module, coupled to the image capturing unit, and having: A face detection unit for receiving the subject image transmitted by the image capturing unit, so as to detect a face part from the subject image; A physiological index calculation unit, coupled to the face detection unit, for obtaining at least one physiological signal from the face part, so as to perform at least one signal processing on the at least one physiological signal to obtain the measured Multiple physiological indexes of the person; and A vitality index calculation unit, coupled to the physiological index calculation unit, for calculating multiple vitality indices of the subject according to the multiple physiological indices; and A display unit, coupled to the core computing module, is used to display the multiple vitality indexes, at least one graphical vitality index data, the multiple physiological indexes, and/or at least one graphical physiological index data. The non-contact physiological signal detection device described in the first item of the scope of patent application, wherein the multiple physiological indexes include: heart rate, heart rhythm variability, respiration rate, blood volume, blood oxygen, blood pressure, blood vessel viscosity, venous function , Venous return, ankle pressure, genital response, and cardiac output. As described in item 1 of the scope of patent application, the health management system using non-contact imaging physiological detection technology, wherein the multiple vitality indexes include: health, activity, stability, stress, metabolism, and balance . The health management system using non-contact imaging physiological detection technology as described in the scope of patent application 1, wherein the image capturing unit is a stand-alone camera, and the core computing module is integrated in an electronic host device . For example, the health management system using non-contact imaging physiological detection technology described in item 4 of the scope of patent application, wherein the electronic host device can be any of the following: cloud server, desktop computer, all-in-one In-One) computers, laptops, tablets, smart phones, smart watches, smart glasses, smart display devices, smart TVs, smart home door phones, or home care system hosts. The health management system using non-contact imaging physiological detection technology as described in the first item of the scope of patent application, wherein the image capturing unit and the core computing module are integrated in the same electronic product, and the electronic product can be Any of the following: All-In-One computer, embedded computer, notebook computer, tablet computer, smart phone, smart watch, smart glasses, smart TV, smart home door phone, or home Take care of the host of the system. The health management system using non-contact imaging physiological detection technology as described in the first item of the patent application, wherein the display unit is a stand-alone display, and the core computing module is integrated in an electronic host device. For example, the health management system using non-contact imaging physiological detection technology as described in item 7 of the scope of patent application, wherein the stand-alone display can be any of the following: TV, desktop display, portable display, projection Display, or touch display. For example, the health management system using non-contact image-based physiological detection technology described in item 7 of the scope of patent application, wherein the electronic host device can be any of the following: cloud server, desktop computer, all-in-one (All- In-One) computer, embedded computer, notebook computer, tablet computer, smart phone, smart watch, smart glasses, smart TV, smart display device, smart home door phone, or home care system host. As described in item 7 of the scope of patent application, the health management system using non-contact imaging physiological detection technology, wherein the display unit and the core computing module are integrated in the same electronic product, and the electronic product can be any of the following One: All-In-One computers, laptops, tablets, smart phones, smart watches, smart glasses, smart TVs, smart display devices, smart home door phones, or home care System host. The health management system using non-contact imaging physiological detection technology as described in item 1 of the scope of patent application, further includes: A storage unit, coupled to the core computing module, for storing the plurality of vitality indexes and the plurality of physiological indexes; and A main control unit, coupled to the storage unit, the image capturing unit, the core computing module, and the display unit, for controlling the operation of the image capturing unit and the core computing module, and controlling the display unit The multiple vitality indexes, the multiple physiological indexes, the graphical vitality index data, and/or the graphical physiological index data are displayed. For example, the health management system using non-contact imaging physiological detection technology described in the scope of patent application, wherein the core computing module further has a face recognition unit, which is coupled to the face detection unit and is used for A face feature information is obtained from the face parts, and then a feature matching process is performed according to the face feature information and a face feature template stored in the storage unit to complete the identification of the subject's body. As described in item 11 of the scope of patent application, the health management system using non-contact imaging physiological detection technology further includes a communication unit coupled to the main control unit to enable the main control unit to communicate with an external electronic device Communicate with each other. As described in item 12 of the scope of patent application, the health management system using non-contact imaging physiological detection technology, wherein the storage unit includes: A user identity database for storing a plurality of the facial feature templates and a plurality of user personal data, wherein each of the facial feature templates is recorded according to the corresponding subject, and is associated with each individual user The data correspond to each other; An index database for storing the plurality of vitality indexes and the plurality of physiological indexes according to the personal data of each user; and A chart database for storing the at least one charted vitality index data and the at least one charted physiological index data according to each of the user personal data. The health management system using non-contact imaging physiological detection technology as described in the scope of patent application, wherein the communication unit includes a wired transmission interface and/or a wireless transmission interface. For example, in the health management system using non-contact imaging physiological detection technology described in the scope of patent application, the graphic vitality index data and the graphic physiological index data both include a real-time data part and a historical data part. As described in item 16 of the scope of patent application, the health management system using non-contact imaging physiological detection technology, wherein the core computing module further has a health evaluation unit, which is coupled to the physiological index computing unit and the vitality index The arithmetic unit is used to evaluate a health condition of the subject according to the at least one graphed vitality index data and the at least one graphed physiological index data, and when the health condition does not meet the standard, the The health assessment unit transmits a warning signal to the main control unit, so that the main control unit controls the display unit to display a warning message.

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