Detailed Description
The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.
At present, the phenomenon of body fever often appears in most patients suffering from infectious diseases, for example, the phenomenon of body fever appears in patients infected with viruses such as influenza virus and novel coronavirus, and wearing equipment has the characteristic of facilitating the long-time carrying of a user, so this application is through carrying out corresponding improvement to wearing equipment, in order to realize that wearing equipment can carry out body temperature measurement to the target object in the first preset scope, and upload to information processing equipment and handle, can determine the suspected patient in the first preset scope, and can take corresponding measures to carry out health protection to the user.
Referring to fig. 1, fig. 1 is a schematic structural diagram of an embodiment of a neck massager according to the present application.
As shown in fig. 1, the neck massager 10 includes a middle bracket 100, a left clamping arm 200, a right clamping arm 300, a strip-shaped conductive band 400 and a heating band (not shown). The material of the middle bracket 100 may be silicone to improve the deformability of the middle bracket 100. The strip-shaped conductive tape 400 may be a flexible material, for example, conductive silicone. The heating tape may be a flexible material, for example, graphene.
The middle bracket 100 has a main massage surface 110 facing the neck, and the left clip arm 200 is mounted to the left end of the middle bracket 100, and the right clip arm 300 is mounted to the right end of the middle bracket 100. A plurality of strip-shaped conductive strips 400 are provided on the main massage surface 110 of the middle bracket 100, and each strip-shaped conductive strip 400 extends along the length direction of the middle bracket 100. The heating belt is provided on the main massage surface 110 of the middle support 100, and heats the region to be massaged of the human body through the strip-shaped conductive tape 400. The main massage face 110 may be a flexible material, such as a non-conductive silicone.
Specifically, the middle support 100 is configured in a C-shape corresponding to the shape of the neck of the human body, and the main massage face 110 is a surface of the middle support 100 facing the neck of the human body. The plurality of strip-shaped conductive strips 400 are in contact with the skin of the human body. The plurality of strip-shaped conductive strips 400 includes at least one strip-shaped conductive strip 400 of a positive electrode and at least one strip-shaped conductive strip 400 of a negative electrode. The heating belt may heat the massaged region of the human body through the strip-shaped conductive tape 400, for example, the heating belt generates heat and transfers the heat to the strip-shaped conductive tape 400, so that the strip-shaped conductive tape 400 can be heated while massaging, to improve comfort.
According to the neck massage apparatus 10 of the present embodiment, the strip-shaped conductive band 400 is used instead of the massage head electrodes in the related art, and the strip-shaped conductive band 400 does not need to protrude like the massage head electrodes, thereby reducing the volume of the neck massage apparatus 10. And, through the setting of a plurality of strip conductive band 400, when neck massager 10 during operation, a plurality of strip conductive band 400 can form the return circuit with the human body, reach the effect of massage, and because conductive band 400 sets up to the strip, and every strip conductive band 400 extends along the length direction of middle support 100, the total area of a plurality of strip conductive band 400 and human contact is big, compare the local massage among the correlation technique, large tracts of land continuum region's massage has been realized, massage area has not only been increased, the massage blind spot has been cleared away, user's travelling comfort has been improved, and effectively avoided the production of stabbing pain, guarantee the travelling comfort of massage. In addition, through the arrangement of the heating belt, the neck massage apparatus 10 can provide a heating effect for the human body, further increasing the massage effect and comfort. Thus, the neck massage apparatus 10 according to the present embodiment has advantages of large massage area, high comfort, small size, and the like.
Alternatively, various detection circuits may be provided on the neck massager 10 to collect the physical health data of the user. For example, various communication circuits, detection circuits and detection components may be provided in the middle bracket 100, the left arm 200 or the right arm 300 of the neck massager 10. For example, in the present embodiment, the neck massager 10 may include the body temperature measuring assembly 600. The body temperature measuring assembly 600 is used for measuring the body temperature of the target object within a first preset range and obtaining body temperature data. The body temperature measurement assembly 600 may specifically include a body temperature measurement element (not shown) and a signal processing circuit (not shown), and the body temperature measurement element is electrically connected to the signal processing circuit. In a specific application, the body temperature measurement assembly 600 is an infrared body temperature measurement assembly, and specifically includes a photoelectric detection element and a signal processing circuit, the photoelectric detection element is configured to convert infrared rays radiated by a human body into an electrical signal, and the signal processing circuit is configured to process the converted electrical signal to obtain body temperature data. The body temperature measuring assembly 600 may be disposed on the outer layer of the middle support 100 or the middle support 100, and in order to reduce the influence of heat and other signals generated by the operation of the neck massager 10, the body temperature measuring assembly 600 should be located as far away from the heating band as possible. For example, a positioning circuit (not shown) may be disposed on the neck massager 10 for obtaining the geographic location information of the user; a camera module (not shown) may be further disposed on the neck massager 10 for obtaining image information. In addition, the neck massager 10 may further include a control circuit (not shown) for controlling the operation of the internal circuits and components of the neck massager 10, and/or for data processing and analysis, for example, for implementing the functions implemented by the corresponding wearable device in the system embodiments described below. In a specific application, the control circuit may be a processor, that is, the neck massager 10 further includes a memory (not shown) and a processor (not shown), the memory is used for storing data, and the processor is used for executing the stored data to realize the functions of the system embodiments described below, which are realized corresponding to the wearable device.
Referring to fig. 2, fig. 2 is a schematic structural diagram of an embodiment of a health detection system according to the present application.
As shown in fig. 2, the health detection system of the present embodiment may include a wearable device 1 and an information processing device 2. The information processing device 2 is in communication connection with the wearable device 1.
The wearable device 1 can be used for measuring the body temperature of a target object within a first preset range and acquiring body temperature data.
The wearable device 1 is a general name for applying a wearable technology to intelligently design daily wearing and developing wearable devices, such as glasses, gloves, watches, clothes, massage instruments, shoes and the like. The mainstream product forms of the wearable device 1 include a watch type (including products such as a watch and a wrist strap) using a wrist as a support, a shoes type (including products worn on shoes, socks or other legs in the future) using feet as a support, a Glass type (including glasses, a helmet, a headband and the like) using a head and a neck as a support, and various non-mainstream product forms such as smart clothes, a schoolbag, a crutch and accessories. The wearing apparatus 1 of the present embodiment may be the neck massage apparatus 10 described in the above embodiments.
The target object can be any object with a temperature above absolute zero, including a human, an animal, etc. The first preset range is an area around the position where the neck massager is located. The first preset range comprises the maximum range of body temperature detection of the wearable device 1, so that body temperature measurement can be performed on a target object in the first preset range through the wearable device 1, and body temperature data are obtained. The first preset range may be set by a user. For example, the maximum range of the wearable device 1 capable of detecting body temperature is 0-2 m, and at this time, the user can set the first preset range to be 0-2 m, 0.5-1 m or 1-2 m. Generally, when the first preset range is set to be larger, the body temperature of the target object in a larger range can be measured, and the target object with abnormal body temperature can be monitored and prevented, so that the prevention range of the user can be enlarged, and the health of the user can be effectively guaranteed.
Specifically, the wearable device 1 can measure the body temperature of the target object within a preset range in real time or at preset time intervals, and acquire body temperature data of all the target objects within a first preset range. Wherein, all target objects in the first preset range can be including wearing the user of neck massage appearance to the realization carries out the body temperature to the user of wearing neck massage appearance and detects, and the user of being convenient for knows self body temperature situation. The preset time interval may be set by the user, for example the preset time interval may be 5 minutes, half an hour, etc. Generally, the smaller the preset time interval is, the more the target object within the preset range of the user can be monitored, so that the protection strength to the user can be increased, and particularly, when the user is in a motion state, the smaller preset time interval can more effectively realize the health protection to the user.
The body temperature data measured by the wearable device 1 may be affected by various factors, such as a measurement distance, an air medium, an external environment temperature, and the like, so that the initial body temperature data initially measured by the wearable device 1 is not necessarily the real body temperature data of the person, that is, the initial body temperature data may be out of a first preset body temperature range, and the obtained initial body temperature data may be corrected to obtain the real body temperature data, so that the determination of the step may be performed through the real body temperature data. The obtained initial body temperature data is corrected, influence coefficients of different numerical values can be set according to the influence degrees of different factors on the real body temperature data, and the obtained initial body temperature data and the influence coefficients are correspondingly calculated to obtain the real body temperature data; or corresponding temperature compensation can be carried out according to the influence degree of different factors on the real body temperature data so as to obtain the real body temperature data. Wherein, the temperature compensation may be temperature compensation by a heating member of the wearable device 1. If the wearing apparatus 1 is the neck massager 10 in the above-described embodiment, the heating member may be a heating belt in the neck massager.
The information processing device 2 is in communication connection with the wearable device 1, and is configured to receive target object information sent by the wearable device 1, where the target object information includes body temperature data of a target object, and analyze the target object information to determine whether the target object is a suspected patient.
The information processing apparatus 2 is an apparatus having an information processing function, such as a mobile phone, a computer, or a server. Specifically, the information processing device 2 may receive body temperature data in the target object information sent by the wearable device 1, and perform analysis according to the body temperature data to determine whether the target object is a suspected patient. For example, by analyzing whether the body temperature data is greater than a first body temperature threshold or less than a second body temperature threshold, if so, the target subject is determined to be a suspected patient.
In this embodiment, body temperature measurement is performed on the target object within the first preset range through the wearable device 1, so that when the user uses the wearable device 1, the body temperature of the target object within the first preset range can be monitored by using the wearable device 1, and further the body temperature data is uploaded to the information processing device 2 by using the wearable device 1 for analysis, so that suspected patients within the first preset range can be determined. In addition, target object information is analyzed through the information processing equipment, complex components do not need to be additionally added to the wearing equipment, and the structure of the wearing equipment is prevented from being complicated.
Referring to fig. 3, fig. 3 is a schematic structural diagram of another embodiment of the health detection system of the present application.
In this embodiment, the health detection system may further include at least one mobile terminal 3, where the mobile terminal 3 is in communication connection with the wearable device 1 and/or the information processing device 2, and is configured to receive and display the target object information. The mobile terminal 3 may include a mobile terminal 3 connected to the wearable device 1 and a mobile terminal 3 not connected to the wearable device 1. Specifically, the mobile terminal 3 connected to the wearable device 1 can receive and display the target object information uploaded by the wearable device 1; the mobile terminal 3 which is not connected with the wearable device 1 can be connected with the information processing device 2 which is in communication connection with the wearable device 1 through communication, then the target object information is transferred through the information processing device 2, the target object information is received and displayed, and therefore information sharing can be achieved.
The target object information further includes image information of the target object, wherein the image information is obtained by shooting the wearable device 1 or the mobile terminal 3 connected with the wearable device 1. The image information may include a photograph, video, and the like. In this embodiment, analyzing the target object information to determine whether the target object is a suspected patient may include: identifying the image information, and determining the category of the target object according to the identification result; acquiring a preset body temperature range corresponding to the category of the target object; judging whether the body temperature data of the target object is within a preset body temperature range or not; if not, determining that the target object is a suspected patient.
The category of the target object may include human, animal, and others, among others. Other objects may be inanimate objects. If further subdivided, humans may also include elderly, young, middle aged and young people, animals may also include cats, dogs, chickens, ducks, fish, etc., others may also include candles, gears in friction, etc. The range of normal body temperatures of different classes of target subjects varies, for example, human normal body temperature is typically 36 ℃ to 37.2 ℃, chicken normal body temperature is typically 40 ℃ to 42.5 ℃, and the temperature of the core of a candle flame is typically 200 ℃ to 250 ℃. However, since suspected patients are generally life bodies, such as people and animals, the present embodiment can exclude other target objects from the category by identifying the image information, and does not participate in the subsequent processing steps, so as to reduce the processing complexity of the information processing device 2, thereby improving the health detection efficiency of the target object.
The preset body temperature range can be the normal body temperature range of the target object. The preset body temperature range can also be set by a user. For example, if an infectious disease causes a fever of more than 39 ℃ in an infected person and a fever of more than 40.5 ℃ in an infected dog, the upper limits of the corresponding preset body temperature ranges may be set to 39 ℃ and 40.5 ℃.
In an application scene, a user wears a neck massager, the neck massager acquires body temperature data and image information of a target object within a first preset range of 0-2 m in real time, the acquired target object comprises a child, a dog and a toy which is doing mechanical motion, the body temperature data of the child is 38 ℃ measured through the neck massager, the body temperature data of the dog is 39 ℃, the body temperature data of the toy is 20 ℃, the neck massager uploads the body temperature data and the image information to an information processing device 2, the information processing device 2 identifies the image information, determines the types of the target object to be the child, the dog and the other according to an identification result, excludes the target objects of other types, then respectively acquires preset body temperature ranges of 36-37.2 ℃ and 37.9-39.9 ℃ corresponding to the child and the dog, and finds that the body temperature data of the child is 38 ℃ and is not within the corresponding preset body temperature range of 36-37.2 ℃ through judgment, determining that the child is suspected to be a patient, and determining that the dog is not suspected to be a patient if the body temperature data of the dog is 39 ℃ within the corresponding preset body temperature range of 37.9-39.9 ℃.
The target object information may also include geographic location information of the target object. The geographic location information may be the relative location information of the user and the target object, for example, the target object is located 1.2 meters in front of the right or 0.7 meters behind the left of the user. Or the geographical location information may also be GPS location information, and GPS location can provide more accurate geographical location information for the user, but GPS signals often have uncertainty, and if the GPS signal of the current location of the user is weak and cannot be accurately located or cannot be located, the wearable device 1 may take the relative location information between the user and the target object as the geographical location information by obtaining the relative location information, thereby avoiding the situation that the geographical location information cannot be obtained due to inaccurate GPS location or inability to be located.
The geographic position information may be obtained by positioning the wearable device 1 or the mobile terminal 3 connected to the wearable device 1. Since the user generally carries the mobile terminal 3 with him, when the user uses the wearable device 1, the mobile terminal 3 connected to the wearable device 1 is generally closer to the geographic location of the wearable device 1, and thus can be regarded as the same geographic location, and at this time, the user can arbitrarily select the wearable device 1 or the mobile terminal 3 connected to the wearable device 1 to perform positioning, so as to obtain the geographic location information. When the user does not carry the mobile terminal 3, the mobile terminal 3 of the user is generally far away from the wearable device 1, optionally, the wearable device 1 or the mobile terminal 3 connected with the wearable device 1 can determine the distance between the wearable device 1 and the wearable device 1, and when the distance is far away, the positioning can be performed through the wearable device 1 to obtain the geographical location information.
The information processing device 2 is further configured to send the geographic location information of the target object determined to be suspected of being a patient to the mobile terminal 3. In some embodiments, when the geographic location information may be the relative location information of the user and the target object, since the relative location information only includes the relative location relationship between the user wearing the wearable device 1 and the target object, when the information processing device 2 transmits the geographic location information of the target object determined to be suspected of being sick to the mobile terminal 3, only the user of the mobile terminal 3 in communication connection with the wearable device 1 can obtain the geographic location information of the target object suspected of being sick, so when the obtained geographic location information is the relative location information of the user and the target object, the information processing device 2 only needs to transmit the geographic location information of the target object determined to be suspected of being sick to the mobile terminal 3 in communication connection with the wearable device 1. In other embodiments, when the geographic location information may include real geographic location information of the target object, such as GPS positioning information, the information processing device 2 may send the geographic location information of the target object determined to be suspected of being a patient to the mobile terminal 3 in communication with the wearable device 1 and/or the mobile terminal 3 not in communication with the wearable device 1, and at this time, the mobile terminal 3 in communication with the wearable device 1 and/or the mobile terminal 3 not in communication with the wearable device 1 may obtain the geographic location information of the target object suspected of being a patient.
In addition, the mobile terminal 3 is further configured to receive the geographic position information sent by the information processing device 2, perform a first marking on the map for the target object determined to be suspected of being a patient according to the geographic position information, and perform a second marking on the target object located within a second preset range of the target object determined to be suspected of being a patient. The second preset range can be set by a user. For example, when performing on-site investigation on the target object determined to be a suspected patient, a second preset range may be set by an investigator as the investigation range, and the second preset range may be larger than the first preset range.
For example, the mobile terminal 3 may adopt a triangular mark for the detected target object determined as the suspected patient, adopt a square mark for the target object within the second preset range determined as the suspected patient, and may not mark the target object that is not detected. In this embodiment, by marking the target object, even when the target object determined as a suspected patient and the peripheral target objects thereof are not at the reported geographical positions when the examiner arrives, the current geographical position information or the movement path thereof can be acquired to perform follow-up examination. The movement path of the marked target object can be obtained according to the marked target object, namely, feature information of the marked target object, such as clothing information, face information and the like, can be obtained firstly, then the feature information of the target object in the range can be collected in real time by wearing a neck massage instrument by a roadside camera or other users, and is compared with the feature information of the marked target object one by one, so that the target object with the same feature information can be found out, and further the current geographical position information or the movement path of the marked target object can be obtained.
The information processing device 2 is further configured to send a troubleshooting instruction to the mobile terminal 3 when the target object is determined to be a suspected patient. The mobile terminal 3 in the system includes a mobile terminal 3 of an inspector, and the inspector can be a user wearing the wearable device 1, a nearby medical worker, a community worker, a worker specially responsible for suspected patients, or the like.
The mobile terminal 3 is further configured to prompt the user to perform on-site investigation on the target object determined as the suspected patient when receiving the investigation instruction, and report the investigation result input by the user to the information processing device 2. The investigation result comprises patients and non-patients. And when the investigation result is a disease, the mobile terminal 3 cancels the first mark and the second mark related to the target object determined as the suspected disease, and prompts the user to send the target object corresponding to the disease to the hospital for treatment.
Specifically, the user may input the result after passing the authentication. If the user passes the identity authentication, the user can be determined to have the authority to input the investigation result, after the user inputs the investigation result through the mobile terminal 3, the mobile terminal 3 reports the input result to the information processing device 2, the information processing device 2 downloads the investigation result to each mobile terminal 3 in communication connection with the information processing device 2, and when the investigation result is a non-patient, the mobile terminal 3 cancels the first mark and the second mark related to the target object determined as a suspected patient. Optionally, a third marking may be performed on the target object whose investigation result is non-patient to indicate that the target object is non-patient after the investigation, for example, the target object that is not patient may be marked on the map with blue. And when the investigation result is a patient, prompting the user to send the target object corresponding to the patient to the hospital for treatment. Optionally, a fourth marking may be performed on the target object with successful treatment to indicate that the target object is the target object with successful treatment, for example, the target object with successful treatment may be marked on the map with green color. In general, for example, infectious diseases caused by a novel coronavirus, this type of person can be marked as representing a clear green color since the patient has developed antibodies to the virus after successful treatment and is less likely to be re-infected.
In some embodiments, the mobile terminal 3 may be further specifically configured to, when the examination result is a patient, display a path to a currently available hospital to prompt the user to send a target object corresponding to the patient to the currently available hospital for treatment. The path of the current available hospital is obtained by searching the current available hospital according to a preset search strategy through the mobile terminal 3 or the information processing device 2, and planning to obtain the path going to the current available hospital. The preset search policy may include at least one of: the current bed has available bed positions, the distance is the shortest, the travel time is the shortest, and the current travel time does not pass through a preset crowd dense area. In other embodiments, the mobile terminal 3 is further configured to, if the investigation result is a patient, start the camera to shoot a peripheral target object of a target object corresponding to the patient, and upload the shot peripheral target object to the information processing device 2, where the information processing device 2 performs identity recognition on the peripheral target object, and notifies the peripheral target object to perform isolated observation based on the identity recognition result, and/or monitors the peripheral target object within a preset time period based on the identity recognition result. The preset time period may be set by a user. The informing of the peripheral target object based on the identity recognition result can be that after the identity of the target object is determined, information such as a contact telephone and a current address corresponding to the target object is searched in a database in which information such as a contact telephone and a current address of the target object is prestored, so that the target object can be informed to be subjected to isolated observation through the contact telephone, the condition that the target object is subjected to isolated observation at the current address is monitored within 14 days, and/or image information shot in a public place is obtained within 14 days, whether the peripheral target object exists in the image information is analyzed, and if the peripheral target object exists, an alarm is given and the peripheral target object is reminded to avoid appearing in the public place.
The wearable device 1 is further configured to receive first prompt information that a suspected patient exists in the first preset range sent by the information processing device 2, and remind the user in a first preset reminding manner. The wearable device 1 is further configured to obtain a current distance between the wearable device and the target object determined as the suspected patient in real time or at regular time, and send the current distance to the information processing device 2. The information processing device 2 is further configured to send second prompt information that the suspected patient is approaching to the wearable device 1 when detecting that the change trend of the current distance is decreasing, and the wearable device 1 is further configured to remind the user in a second preset reminding manner when receiving the second prompt information. The information processing device 2 is further configured to weaken the reminding strength of the first preset reminding mode or close the first preset reminding mode when detecting that the change trend of the current distance is increasing. In addition, the information processing device 2 may also send the above prompt information to the mobile terminal 3, and remind the user through the mobile terminal 3, which is not described herein again.
The preset reminding mode can comprise one or more of vibration, sound and light and voice. Optionally, if the suspected patient existing within the first preset range includes a person, the first preset reminding manner may be vibration in order to avoid embarrassment. It should be noted that the user can distinguish between the vibration generated in the vibration warning mode of the neck massage apparatus and the vibration generated when the neck massage apparatus is normally massaged. When the wearable device is a neck massager, in some embodiments, when the neck massager starts the vibration warning mode, if it is detected that the neck massager is performing a massage operation, the massage of the neck massager may be stopped within a preset time interval, so that a user may receive warning information sent by the neck massager. The preset time interval may be set by a user, for example, 0.5s, 1s, or 1 min. In other embodiments, the vibration warning mode of the neck massager corresponds to a vibration frequency different from that of the normal massage, so that the user can distinguish the neck massager from the normal massage according to the difference of the vibration frequency. Optionally, when the change trend of the current distance is detected to be reduced, the second preset reminding mode can be acousto-optic, and not only can surrounding users be reminded of the animals, but also the animals can be driven when the target objects are close to the animals through the acousto-optic, so that the body health of the users can be guaranteed. Wherein this reputation has the effect of driving, optionally, can also adopt to predetermine the sound wave to drive the animal.
Referring to fig. 4, fig. 4 is a schematic flow chart of an embodiment of the health detection method of the present application.
In this embodiment, the health detection method may include the following steps:
step S11: the information processing device receives target object information uploaded by the neck massager, wherein the target object information comprises body temperature data of a target object in a first preset range detected by the neck massager.
Step S12: and analyzing the target object information to determine whether the target object is a suspected patient.
The information processing device in this embodiment of the method may be the information processing device in the system embodiment, and for the description of each step, reference may be made to the description of the information processing device in the health detection system, which is not described herein again.
The present application also provides some embodiments of an electronic device, which may be one of the above health detection systems, such as a wearable device, an information processing device, and a mobile terminal.
Referring to fig. 5, fig. 5 is a schematic structural diagram of an embodiment of an electronic device according to the present application.
The electronic device in this embodiment is the wearable device 1 in the health detection system. Specifically, the electronic device 50 includes a body temperature measuring component 501, a communication circuit 502, and a control circuit 503, and the body temperature measuring component 501 and the communication circuit 502 are respectively connected to the control circuit 503. The body temperature measuring component 501 is configured to measure a body temperature of a target object within a first preset range, and acquire body temperature data. The communication circuit 502 is used to realize communication with an external device such as the above-described signal processing device, mobile terminal, or the like. The communication circuit 502 may specifically be a bluetooth communication circuit, a WIFI communication circuit, a Near field communication (NFC for short) communication circuit, or the like. The control circuit 503 is used for controlling the operations of the internal components of the electronic device 50, such as the body temperature measuring component 501 and the communication circuit 502, and/or for data processing and analysis, in this embodiment, the control circuit 503 is used for receiving the body temperature data of the body temperature measuring component 501, and controlling the communication circuit 502 to transmit the body temperature data to the external device.
Specifically, the control circuit 503 sends a working signal to the body temperature measurement component 501, the body temperature measurement component 501 receives the working signal sent by the control circuit 503, starts to measure the body temperature of the target object within a first preset range, acquires body temperature data, and the control circuit 503 inputs a sending instruction to the communication circuit 502 to upload the body temperature data to the information processing device. The body temperature measuring assembly 501 may include a body temperature detecting element and a signal processing circuit, which may refer to the description related to the embodiment shown in fig. 1, where the body temperature detecting element may be a non-contact temperature sensor such as an infrared body temperature detector. As long as the temperature of an object is higher than absolute zero, infrared rays can be radiated to the periphery ceaselessly, and the infrared body temperature detector detects the body temperature by utilizing the infrared rays radiated by a moving target (such as people, livestock and vehicles). Such detectors do not respond to changes in temperature rise or fall. And the infrared body temperature detector has high sensitivity and is not easy to be damaged. In addition, the infrared body temperature detector also has the following advantages: the method has the advantages that (1) no equipment is required to be installed in a preset area, and long-distance temperature measurement can be realized; due to passive working, no radiation of any type is generated, and the confidentiality is strong; (III) illumination conditions are not required to be considered, the lamp can be used day and night, and is particularly suitable for working at night or in dark conditions; and (IV) because no energy is emitted and no movable part easy to wear exists, the power consumption is low, the structure is firm, the service life is long, the maintenance is simple and convenient, and the reliability is high.
In some embodiments, the wearable device is a neck massager, wherein the specific function and structure of the neck massager may refer, but is not limited, to the embodiment shown in fig. 1 described above.
Referring to fig. 6, fig. 6 is a schematic structural diagram of an electronic device according to another embodiment of the present application.
As shown in fig. 6, in this embodiment, the electronic device 60 may be an information processing device and a mobile terminal in the health detection system. Specifically, the signal processing device may be any device with a certain processing capability, such as a mobile phone, a desktop computer, a tablet computer, and a server. The mobile terminal can be a mobile phone, a tablet computer and other portable devices.
The electronic device 60 in this implementation includes a processor 601 and a communication circuit 602 and a memory 603 each connected to the processor 601. The communication circuit 602 is used to implement communication with an external device. The memory 603 is used to store program instructions. The processor 601 is configured to execute program instructions to implement the functions implemented by the information processing apparatus or the mobile terminal in the above system.
In some embodiments, when the electronic device 60 is an information processing device, the communication circuit 602 of the information processing device may be configured to receive target object information, such as body temperature data, sent by the wearable device, and send the target object information to the processor 601; the processor 601 is configured to analyze the body temperature data to determine whether the target object is suspected to be a patient, and the specific analysis process can be described with reference to the above embodiments of the system.
In other embodiments, when the electronic device 60 is a mobile terminal, the communication circuit 602 of the mobile terminal may be configured to receive the target object information, the body temperature data, the geographic location information of the target object, and/or the like sent by the wearable device, and send the target object information to the processor 601. The electronic device may further include a display screen, and the processor 601 is configured to control the display screen to display a map and display a related target object on the map according to the target object information, and the specific implementation manner may refer to the related description of the above system embodiment.
Processor 601 may also be referred to as a CPU (Central Processing Unit). The processor 601 may also be an integrated circuit chip having signal processing capabilities. The processor 601 may also be a general purpose processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other programmable logic device, discrete gate or transistor logic, discrete hardware components. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like.
The Memory 603 may be a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and the like, which can store program instructions. In order to simplify the structure of the electronic device and save the internal space, a storage medium which is small in size and is easy to mount to the electronic device may be selected as the memory 603.
Referring to fig. 7, fig. 7 is a schematic structural diagram of an embodiment of a device with a storage function according to the present application. The apparatus 70 with storage function stores instructions 701, and the instructions 701 implement the method in any of the above embodiments when executed.
In addition to providing the processor of the electronic device with program instructions to cause the processor to perform the method of the above-mentioned embodiment, the device 70 with storage function may be connected to the wearable device to serve as a control device of the wearable device, and the storage device executes the stored program instructions to instruct the control circuit of the wearable device to perform the method of the above-mentioned embodiment.
The device 70 with a storage function may be a medium that can store program instructions, such as a usb disk, a removable hard disk, a Read-only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk, or may be a server that stores the program instructions, and the server may send the stored program instructions to other devices for operation, or may self-operate the stored program instructions.
The above description is only an example of the present application and is not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings, or which are directly or indirectly applied to other related technical fields, are intended to be included within the scope of the present application.