TWM562100U - Intelligent testing equipment - Google Patents

Abstract

An intelligent detecting device includes a processor, an electrode device, and a stereoscopic image capturing device. The electrode device is electrically connected to the processor, and the electrode device comprises a first electrode and a second electrode. When the detection circuit is formed between the first electrode and the second electrode, the measurement information is generated and transmitted to the processor. The stereoscopic image capturing device captures the biological appearance stereoscopic image and transmits it to the processor, and the processor obtains the biological appearance information according to the biological appearance stereoscopic image, and the processor calculates the physiological information according to the biological appearance information and the measurement information. The cooperation of the intelligent detecting device combined with the electrode device and the stereoscopic image capturing device may achieve the efficacy of multiple detecting devices through a simple mechanism. In this way, the equipment cost of the medical unit and the time of the subject can be saved, and the immediate symptoms can be provided for immediate symptoms.

Description

Intelligent testing equipment

The novel creation relates to the field of health detection, and in particular to an intelligent detection device.

Traditionally, general physical health examinations, for medical units, such as hospitals, clinics, etc., in order to assist the subject to perform a physical examination, it is necessary to purchase a plurality of devices to test the various parts of the body of the subject. In addition, it is also necessary to hire people who assist in testing, and the cost of manpower and equipment is relatively expensive. However, many physical examinations are currently used in conjunction with schooling, employment, licenses, and insurance, so that the purchase of equipment cannot be fully utilized. Therefore, the burden of depreciation on medical units is relatively heavy.

For the subject, special time is required to go to the hospital or clinic for inspection. In general, it takes about half a day to check, and actually spends more time queuing between projects. In addition, after the examination is completed, an additional appointment with the doctor is required to diagnose the results of the examination. For today's business community, this method is time consuming and not economical, and it also reduces the willingness of the subjects to check, which makes many diseases difficult to find early.

In order to solve the problems in the conventional technology, an intelligent detecting device is provided herein. The intelligent detecting device comprises a processor, an electrode device, and a stereo image capturing device. The electrode device is electrically connected to the processor, and the electrode device comprises a first electrode and a second electrode. When the detection circuit is formed between the first electrode and the second electrode, the measurement information is generated and transmitted to the processor. The stereoscopic image capturing device is electrically connected to the processor, the stereoscopic image capturing device captures the biological appearance stereoscopic image and transmits the same to the processor, and the processor obtains the biological appearance information according to the biological appearance stereoscopic image, and the processor according to the biological appearance information and the measurement information Calculate physiological information.

In some embodiments, the smart detection device further includes a light source device, the light source device generates light, and the stereo image capture device extracts the feedback image from the illumination of the light and transmits the image to the processor, and the processor further calculates the feedback information according to the feedback image. The processor calculates physiological information based on feedback information, measurement information, and biological appearance information.

In some embodiments, the smart detection device further includes a housing, the processor is mounted in the housing, and the electrode device and the stereoscopic image capturing device are mounted on the housing. Further, the electrode device is mounted on a surface of the housing.

In some embodiments, the housing can be a wearable item. The processor is disposed in the housing, and the electrode device and the stereoscopic image capturing device are detachably assembled to the housing. Further, the wearable article is a vest, a jacket, a hat, or a combination thereof.

In some embodiments, the smart detection device further includes a communication device. The communication device is electrically connected to the processor, receives the physiological information and sends out.

In some embodiments, the smart detection device further includes a first communication device and a second communication device. The first communication device, the processor, and the stereoscopic image capturing device are grouped as intelligent processing devices, and the second communication device and the electrode device are grouped as measuring devices, and the intelligent processing device and the measuring device are transmitted through the first communication device and the second communication device. Intercommunication connection.

Further, the intelligent processing device is a smart phone, a tablet, a car body, or a combination thereof. In addition, the measuring device is a body fat meter, a cardiac power measuring unit, an electroencephalogram measuring unit, or a combination thereof.

In some embodiments, the stereoscopic image capturing device includes at least two imaging lenses, and the imaging lens respectively captures images and transmits the images to a processor, and the processor synthesizes the images to generate a biological appearance stereoscopic image.

In some embodiments, the stereoscopic image capturing device further includes an infrared imaging unit that captures the temperature distribution image and transmits the image to the processor. The processor calculates the temperature feedback information based on the temperature distribution image, and the processor returns the information based on the temperature. , measurement information, and biological appearance information to calculate physiological information.

In some embodiments, the electrode device further includes a plurality of pairs of electrode sheets electrically connected to the processor, and when the pair of electrode sheets form a detection loop, generating monitoring information to the processor. The processor calculates physiological information based on biological appearance information, measurement information, and monitoring information.

In the above various embodiments, the intelligent detecting device cooperates with the electrode device and the stereoscopic image capturing device to jointly assist the judgment of the physiological information, and can achieve the efficacy of the plurality of detecting devices through a simple mechanism. In this way, the equipment cost of the medical unit and the time of the subject can be saved, and the potential symptoms, or possible acute symptoms can be provided with immediate warnings, and the application can be used for notification, so as to facilitate early detection and early treatment.

FIG. 1 is a schematic diagram of a unit of an intelligent detecting device. As shown in FIG. 1, the smart detecting device 1 includes a processor 10, an electrode device 20, and a stereoscopic image capturing device 30. The processor 10 is electrically connected between the electrode device 20 and the stereoscopic image capturing device 30.

The electrode device 20 includes a first electrode 21 and a second electrode 23. When the first electrode 21 and the second electrode 23 are in contact with the human body, the first electrode 21 and the second electrode 23 are electrically connected to each other to constitute a detection circuit. The first electrode 21 and the second electrode 23 generate the measurement information D1 via the detection circuit. The electrode device 20 then transmits the measurement information D1 to the processor 10.

The stereoscopic image capture device 30 captures the bio-appearance stereoscopic image I and transmits it to the processor 10. The processor 10 can calculate and convert the biological appearance information according to the biological appearance stereoscopic image I, and calculate the physiological information D2 according to the measurement information D1 and the biological appearance information.

Here, the measurement information D1 may be a voltage signal corresponding to the bioelectric resistance, or a current signal. In other words, after receiving the voltage signal or the current signal corresponding to the bio-resistance, the processor 10 can generate the measurement information D1 according to the voltage signal or the current signal. In an embodiment, the measurement information D1 may be a numerical value, but the present creation is not limited thereto.

The biological appearance stereoscopic image I is a three-dimensional stereoscopic image corresponding to the subject, and may be a single three-dimensional stereoscopic image or a plurality of consecutive three-dimensional stereoscopic images.

The bio-appearance information is a value calculated by the processor 10 from the corresponding bio-appearance stereoscopic image I.

Physiological information D2 can be physiological condition information or potential risk information. In this way, when the side is detected by the smart detecting device 1, the detection circuit formed between the first electrode 21 and the second electrode 23 can be measured, and the biological image captured by the stereoscopic image capturing device 30 can be supplemented. Appearance stereoscopic image, you can quickly get physiological information D2. That is to say, through the assistance of the biological appearance stereoscopic image I, the intelligent detecting device 1 can accurately interpret the human body to further issue a possible symptom warning to the body of the subject, and can solve the traditional measurement information. D1 can't solve the problem of local underlying symptoms.

Various embodiments of the smart detecting device 1 will be described below through different embodiments. 2 is a perspective view of a first embodiment of an intelligent detecting device. As shown in FIG. 2, the smart detecting device 1 includes a housing 40 and a telescopic rod 45 in addition to the processor 10, the electrode device 20, and the stereoscopic image capturing device 30. The processor 10 is mounted in the housing 40. The first electrode 21 and the second electrode 23 of the electrode device 20 are mounted on the surface of the housing 40, and are separated from each other and electrically connected to the processor 10. The stereoscopic image capturing device 30 is mounted on the telescopic rod 45 and electrically connected to the processor 10 . The telescopic rods 45 can be assembled to the housing 40, so that the telescopic rods 45 can be adjusted to further enable the stereoscopic image capturing device 30 to adjust the position and direction with the human body 500 to capture a suitable bio-appearance stereoscopic image I.

In an embodiment, the first electrode 21 and the second electrode 23 may be electrode plates. When the legs of the human body 500 are respectively stepped on the first electrode 21 and the second electrode 23, the first electrode 21 and the second electrode 23 can be electrically connected via the human body 500, thereby electrically connecting to form a detection circuit, and according to the human body 500. The bioresistance produces measurement information D1. The measurement information D1 can be a voltage signal or a current signal. The processor 10 receives the measurement information D1, and can calculate the breathing, heartbeat, pulse, body weight, fat mass, fat removal amount, body fat percentage, muscle mass, and bone ratio corresponding to the bio-resistance of the human body 500 according to the measurement information D1. Body composition information such as skeletal muscle mass, muscle mass, visceral fat ratio, water volume, water ratio, and protein ratio.

The stereoscopic image capturing device 30 includes at least two lenses 31. In FIG. 2, the two lenses 31 are taken as an example, and are not limited thereto. The second lens 31 captures the human body and captures the images I1 and I2, respectively. The stereoscopic image capturing device 30 may be a separate imaging device that can combine the images I1 and I2 into a three-dimensional biological appearance stereoscopic image I. The stereoscopic image capturing device 30 may be only a lens device, and the captured images I1 and I2 are transmitted to the processor 10, and the processor 10 images I1 and I2 are combined into a three-dimensional biological appearance stereoscopic image I. The processor 10 can calculate the biological appearance information according to the biological appearance stereoscopic image I. The biological appearance information may include the height, chest circumference, waist circumference, arm circumference, gender, center of gravity, body volume, and the like of the human body 500. Here, the biological appearance stereoscopic image I is not limited to the whole body image of the human body 500, and may be a half body image or a partial image. In addition, the processor 10 can further receive a continuous biological appearance stereoscopic image I, and determine biological appearance information according to corresponding continuous changes in the biological appearance stereoscopic images I, for example, gait performance, walking speed, joint angle, and the like. . For example, the second lens 31 can take a half-length photograph of the human body to obtain a biological appearance image I about the half body of the human body 500.

Next, the processor 10 recognizes the bio-appearance image I to determine various data such as the size and area of the human body 500 in the bio-appearance image I. The processor 10 can then use various data of the biological appearance image I to further estimate various biological appearance information such as the height and gender of the human body 500. In addition, in FIG. 2, the stereoscopic image capturing device 30 captures the human body 500 in a standing position to obtain biological appearance information, for example, height, etc., but in reality, the human body 500 can also be in a sitting posture and a lying posture, and can be processed through The device 10 pushes the corresponding biological appearance information according to the biological appearance image I.

Next, the processor 10 can calculate the physiological information D2 according to the measurement information D1, the body composition information corresponding to the measurement information D1, and the related value of the biological appearance information. Physiological information D2 can also include information on physiological conditions such as basal metabolic rate, metabolic age, BMI value, obesity, muscle evaluation, muscle strength, and posture. Physiological information D2 can also be based on the relevant threshold value and calculate the potential risk information of the relevant symptoms, for example, the risk index of symptoms such as sarcopenia, obesity, metabolic syndrome, chronic disease, hypertension, and hip joint injury.

For example, the processor 10 can derive information such as gender, age, height, and the like through the bio-appearance information, and the weight of the subject can be known through the measurement information D1. Therefore, the processor 10 can calculate the physiological information D2 of the BMI value and the risk information of the related symptoms by combining the biological appearance information and the measurement information D1. Therefore, the test subject can be conveniently used to perform the detection by the smart detecting device 1 without any other input behavior, which greatly simplifies the detection process. The other physiological information D2 is also obtained in the same way, that is, the physiological information D2 is derived through the biological appearance information and the measurement information D1, and will not be described here.

3 is a perspective view of a second embodiment of the smart detection device. As shown in FIG. 3, the second embodiment differs from the first embodiment in that the smart detecting device 1 further includes a handlebar 50. The first electrode 21 and the second electrode 23 of the electrode device 20 are mounted on the surface of the handle 50. The handle 50 is assembled with the housing 40. When the human body 500 grasps the handle 50, the first electrode 21 and the second electrode 23 are electrically connected to each other through the human body 500, and electrically connected to form a detection circuit, thereby generating measurement information D1. The electrode device 20 of Figs. 2 and 3 is merely an example and is not limited thereto.

The embodiment of Figures 2 and 3 can be applied to a general health check room or room. Further, the smart detecting device 1 can be connected to a printer or a display (not shown) to print or present the physiological information D2. In this way, the medical practitioner or the testee can immediately obtain the relevant physiological information D2, and if the medical practitioner judges that there is a higher risk according to the potential risk information of the relevant symptom, or determines that there is an acute symptom, the medical practitioner can immediately The subject is recommended to perform further testing or treatment. In addition, because the cost of the testing equipment can be reduced, the subject can also purchase and place it at home to track his or her health status through continuous measurement and long-term records.

4 is a perspective view of a third embodiment of the smart detecting device. As shown in FIG. 4, the smart detecting device 1 can be mounted in the vehicle body 600. The processor 10 can be mounted on the vehicle body 600 or as part of the vehicle body 600. For example, the processor 10 can be an application-specific integrated circuit (ASIC) in the microcomputer of the vehicle body 600. The first electrode 21 and the second electrode 23 of the electrode device 20 may be mounted on the seat 610, and the stereoscopic image capturing device 30 may be mounted on the pillar 620. Therefore, when the human body 500 enters the vehicle body 600 to ride or drive, the health check can be performed, and thus, the inspection time can be greatly saved. Moreover, the illustrations are merely examples and are not limited thereto. The position of the electrode device 20 can be arbitrarily mounted, for example, mounted on a steering wheel or a foot pad. The electrode device 20 can also be pulled out and mounted in the vehicle body 600. After the human body 500 enters the vehicle body, it can be pulled out and contacted with the human body 500 to form a detection circuit. In addition, the stereoscopic image capturing device 30 only needs to be installed at a position that is easy to capture.

Further, the smart detecting device 1 can transmit the physiological information D2 to the cloud server (not shown) or the smart phone in conjunction with the communication device associated with the vehicle body 600, and can receive the alert information. For example, when it is determined that the specific index of the physiological information D2 exceeds the standard value and the patient may have an acute symptom, the cloud server sends a warning message to the mobile phone or the body 600 to generate a warning to remind the subject to seek medical treatment immediately. Avoid traffic accidents due to sudden physical conditions.

FIG. 5 is a perspective view of a fourth embodiment of an intelligent detecting device. As shown in FIG. 5, the electrode device 20 of the smart detecting device 1 may further include a plurality of pairs of electrode pads 25. The pair of electrode sheets 25 are electrically connected to the processor 10, respectively. The electrode sheet 25 can be attached to a plurality of areas of the human body 500, for example, attached to the sides of the shoulder, the two arms, the two legs, the back, the sides of the head, and the like in pairs, and a plurality of detection circuits can be formed. When the pair of electrode sheets 25 are turned on to generate a detection loop, the monitoring information D3 is generated and transmitted to the processor 10. The monitoring information D3 may be a potential change value or a current change value based on an electrocardiographic resistance or an electroencephalogram resistance, which may correspond to an electrocardiogram value, an electromyogram value, an electroencephalogram value, etc., and may be measured with different angles or leads. . Further, the smart detecting device 1 can also view the monitoring information D3 in conjunction with a monitor (not shown) for the physician to interpret.

In addition, the processor 10 of the smart detecting device 1 can further calculate more physiological information D2 based on the measurement information D1, the biological appearance information, and the monitoring information D3, for example, a heart rhythm rule, a heart beat state, a brain nerve activation state, Brain neurocognitive function status, etc., as well as risk index of dementia, Parkinson's disease, and nervous system diseases. The fourth embodiment can provide simple and rapid inspection for institutions and medical institutions that require long-term medical care. The intelligent detection device 1 can further integrate a cloud server or a mobile application to warn of potential symptoms and assist the subject. Seek medical attention as soon as possible for further testing and treatment.

The above manner is only an example. The smart detecting device 1 also uses only the first electrode 21 and the second electrode 23 to perform different driving signal control through the processor 10 to generate monitoring information D3 corresponding to the electrocardiographic resistance or brain wave resistance. Here, the electrical resistance or brain wave resistance is different from the bioelectrical resistance. Alternatively, the assisted subject can also obtain the monitoring information D3 corresponding to the electrocardiographic resistance or the electroencephalogram resistance by adjusting the position where the first electrode 21 and the second electrode 23 are in contact with the human body 500 through a plurality of measurements.

Referring again to FIG. 1, the smart detection device 1 includes a processor 10 that further includes a light source device 60. The stereoscopic image capturing device 30 captures the biological appearance image I, and may also be a stereoscopic image or a continuous stereoscopic image of the human body 500. The lens 31 of the stereoscopic image capturing device 30 can also be a high magnification, microscopic lens. For example, the light source device 60 can illuminate the finger of the human body 500, and the stereoscopic image capturing device 30 focuses on the finger of the human body 500. Further, the light source device 60 and the stereoscopic image capturing device 30 can be aligned with the position of the finger by a jig (not shown). The light source device 60 generates light, for example, light in the infrared light band, and is irradiated to a part of the finger of the human body 500. The stereoscopic image capture device 30 captures the feedback image of the finger illumination and transmits it to the processor 10. The processor 10 analyzes the feedback image and calculates a light absorption band as feedback information. For example, oxygen-carrying red blood cells can absorb light in the 850 to 1000 nm band, while oxygen-free red blood cells absorb in the band of 600 to 750 nm. Thus, the ratio of the light absorption band can calculate the ratio of the oxygen-bearing to the oxygen-free red blood cells, and the processor 10 can calculate the hemorrhage oxygen saturation based on the feedback information. The processor 10 further calculates the physiological information D2 according to the feedback information, the measurement information D1, and the biological appearance information. For example, hypoxic index, asthma index, cardiopulmonary disease risk index, chronic obstructive pulmonary disease risk index, and the like.

In other embodiments, the light source device 60 can also emit light of a specific wavelength band, and the contrast of the feedback image captured by the stereoscopic image capturing device 30 can be improved by the illumination, and the accuracy of the interpretation of the processor 10 can be improved. For example, with the aid of the light source device 60, the feedback image captured by the stereoscopic image capturing device 30 is a stereoscopic image of a blood vessel in a specific region, for example, a stereoscopic image of a blood vessel of the face and a blood vessel of the neck. The processor 10 can calculate the physiological information D2 such as the pulse, the heartbeat, the cardiopulmonary disease risk index, and the like based on the time of the photographing and the continuous change of the blood vessel position and volume in the feedback image. However, the above is merely an example and is not limited thereto.

For example, the specific light source device 60 is used to illuminate the blood vessel of a specific part of the human body 500 to increase the contrast, and the stereoscopic image capturing device 30 captures a plurality of feedback images. The processor 10 can calculate the continuous change of the blood vessel based on the multiple feedback images. Feedback information such as expansion and contraction of blood vessels. The processor 10 can further calculate the physiological information D2 such as the heartbeat, the pulse, the estimated age of the blood vessel, and the cardiovascular disease risk index according to the previously taken biological appearance image I, the measurement information D1, and the feedback information. However, the above is merely an example and is not limited thereto.

Referring again to FIG. 1, the stereoscopic image capturing device 30 further includes an infrared imaging unit 33. The infrared imaging unit 33 generates a temperature distribution image IR and transmits it to the processor 10. The processor 10 calculates temperature feedback information based on the temperature distribution image IR, and the processor 10 calculates the temperature feedback information, the measurement information D1, and the biological appearance information. Physiological information D2. In this embodiment, the feedback information may correspond to temperature values of a plurality of parts of the human body 100. Therefore, the smart detecting device 1 can assist the determination of whether the human body 500 has a fever or local inflammation through the infrared imaging unit 33. The infrared imaging unit 33 can be an independent unit or can be implemented as a filter attached to the lens 31. The above is only an example and is not limited to this.

In addition, in some embodiments, the smart detection device 1 further includes a communication device 70. The communication device 70 is electrically connected to the processor 10, receives the physiological information D2, and transmits the information. The communication device 70 can be a wireless signal transceiver or a wired signal transceiver, for example, a USB port, a Mirco USB port, an HDMI port, a wifi signal transceiver, a microwave signal transceiver, a Bluetooth signal transceiver, a ZeeBee signal transceiver, etc. . Taking the wifi signal transceiver as an example, the communication device 70 can transmit the physiological information D2 calculated by the processing 10 to the workstation server or the cloud server (not shown), and then the relevant medical personnel or programs. Preliminary judgment. For example, when the health check is completed, all the physiological information D2 can be transmitted to the doctor's computer by the cloud server, so that the doctor can diagnose the diagnosis based on the physiological information D2 in advance, thereby reducing the medical practitioner and the subject. Detection time.

6 is a perspective view of a fifth embodiment of an intelligent detecting device. As shown in FIG. 6, the housing 40 of the smart detecting device 1 may be a vest-type wearable article, that is, the housing 40 may be soft or flexible. The processor 10 can be mounted in the housing 40 by embedding, embedding, or the like. In addition, the electrode device 20 and the stereoscopic image capturing device 30 are detachably assembled to the casing 40. For example, the electrode device 20 and the stereoscopic image capturing device 30 are connected to the casing 40 in a wired manner. When not in use, the electrode device 20 and the stereoscopic image capturing device 30 may be housed in the housing 40, for example, in a pocket. When the measurement and shooting are to be performed, the electrode device 20 and the stereoscopic image capturing device 30 are pulled out from the casing. In this way, it is convenient for the medical practitioner or the long-term care practitioner to wear, so as to be able to quickly and test the subject, and obtain the physiological information D2 to make a preliminary judgment.

As shown in FIG. 6, in other embodiments, the smart detecting device 1 in which the housing 40 is a wearable article may also include a communication device 70. For example, the processor 10 and the wireless transmission type communication device 70 are assembled as a wafer in a vest-type housing 40. Thus, after the processor 10 calculates the physiological information D2 of the subject, the communication device 70 can receive the physiological information D2 and quickly upload the physiological information D2 to the workstation server or the cloud server (not shown). . The smart detecting device 1 of this embodiment is suitable for medical practitioners or assists the subject to use, which can reduce the workload of medical practitioners, reduce the shift time, and reduce the loss caused by improper handover. Here, the vest is merely an example, and in fact the housing 40 may also be a jacket, a hat, or other wearable article.

For example, a long-term care practitioner can wear the vest-type smart detecting device 1 and, when facing the subject during the patrol, extract the electrode device 20 and make contact with the subject to obtain the measurement information D1. The stereoscopic image capturing device 30 is extracted to extract the biological appearance image I, and then the processor 10 can calculate the physiological information D2 and send it to the workstation server or the cloud server (not shown) through the communication device 70. Such related medical institutions can record long-term tracking of physiological information D2 of long-term rehabilitation, or subjects who need long-term observation, such as cancer health management indicators, hip rehabilitation indicators, and the like.

7 is a schematic block diagram of another embodiment of a smart detection device. As shown in FIG. 7, the smart detecting device 1 includes a first communication device 71 and a second communication device 73. The first communication device 71, the processor 10, and the stereoscopic image capturing device 30 are assembled as the intelligent processing device 100. The second communication device 73 and the electrode device 20 are assembled as the measurement device 200. The intelligent processing device 100 and the measuring device 200 are communicably connected to each other through the first communication device 71 and the second communication device 73. The measurement information D1 can be transmitted to the processor 10 through the first communication device 71 and the second communication device 73. The first communication device 71 and the second communication device 73 may be paired wireless signal transceivers or wired signal transceivers, for example, a USB port, a Mirco USB port, an HDMI port, a wifi signal transceiver, and a microwave signal transceiver. , Bluetooth signal transceiver, ZeeBee signal transceiver, etc.

Further, in some embodiments, the foregoing intelligent processing device 100 may be a smart mobile device, such as a smart phone, a tablet, etc., and the stereoscopic image capturing device 30 can be achieved through a lens of a mobile phone or a tablet. . Therefore, the smart detecting device 1 can be completed in combination with the existing device, and the cost of the related device can be reduced, and the functions of personalization, privacy, and customization can be achieved.

Further, the intelligent processing device 100 can also send the physiological information D2 to the workstation server or the cloud server (not shown) through the first communication device 71, and can also receive the warning message from the workstation server or the cloud server. For example, the workstation server or the cloud server may determine that there is a symptom of an acute disease based on whether the specific value of the physiological information D2 exceeds the standard, and issue a warning to the intelligent processing device 100. However, this is only an example, and is not limited to this. It is also possible to inform the subject or assist the medical practitioner to be tested through the newsletter or voice to assist the subject to seek medical treatment and early treatment.

In addition, referring to the foregoing embodiment, the intelligent processing device 100 may also be the vehicle body 600. The measuring device 200 may be a wearable article, a fingerprint sensor, a body fat meter, a cardiac power measuring unit, a brain wave measuring unit, or a vehicle body 600. For example, taking FIG. 4 as an example, the subject in the vehicle body 600 uses the smart phone 600 as the intelligent processing device 100, and uses the communication device of the electrode device 200 and the vehicle body 600 in the vehicle body 600 as the amount. Measuring device 200. Alternatively, the microcomputer of the vehicle body 600, the communication device, and the lens connected to the vehicle body 600 may be used as the intelligent processing device 100, and the body device of the communication device 70 may be used as the measuring device 200. In addition, taking FIG. 6 as an example, the smart phone can be used as the smart processing device 100, and the vest with the electrode device 20 and the communication device 70 can be used as the measuring device 200.

For example, the subject can use the mobile phone as the intelligent processing device 100, and the stereoscopic image capturing device 30 that controls the mobile phone captures the biological appearance image I of the full body or the half body. Further, the subject's hands are in contact with the first electrode 21 and the second electrode 23 of the wireless communication device 70 body fat meter. The first electrode 21 and the second electrode 23 form a detection loop, and after generating the measurement information D1, the measurement information D1 is transmitted to the mobile phone. The processor 10 of the mobile phone receives the measurement information D1 and calculates the biological appearance information according to the biological appearance image I, for example, gender, height, weight, and the like. Then, the processor 10 of the mobile phone calculates the body composition information according to the measurement information D1, and then calculates the physiological information D2 such as BMI, muscle mass, bone specific gravity, and potential disease risk according to the body composition information and the biological appearance information. The above is only an example and is not limited to this.

In still another embodiment, the first electrode 21 may be disposed on the mobile phone, and the subject contacts the first electrode 21 with one hand. Then, the subject stands on the second electrode 23 (or the second electrode 23 is attached to the hand or the foot), whereby the first electrode 21 and the second electrode 23 can also form a detection circuit. To further let the processor 10 estimate the physiological information D2 of the subject.

As described in the foregoing embodiments, the smart detecting device 1 cooperates with the electrode device 20 and the stereoscopic image capturing device 30 to assist the determination of the physiological information D2, and can achieve the effects of multiple detecting devices through a simple mechanism. In this way, the equipment cost of the medical unit and the time of the subject can be saved. Further, it can be combined with a cloud server, an application program, etc., to initially analyze the symptoms, provide immediate warnings of potential symptoms and possible acute symptoms, and enable the subject to seek medical treatment and early treatment.

The preferred embodiment is disclosed above, but it is not intended to limit the creation of the novel, and any skilled person can make some modifications and refinements without departing from the scope of the novel creation. The scope of protection shall be subject to the definition of the scope of the patent application attached to this specification.

1‧‧‧Intelligent testing equipment
10‧‧‧ processor
20‧‧‧electrode device
21‧‧‧First electrode
23‧‧‧second electrode
25‧‧‧electrode
30‧‧‧3D image capture device
31‧‧‧ lens
33‧‧‧Infrared camera unit
40‧‧‧shell
45‧‧‧ Telescopic rod
50‧‧‧handle
60‧‧‧Light source device
70‧‧‧Communication device
71‧‧‧First communication device
73‧‧‧Second communication device
100‧‧‧Intelligent processing device
200‧‧‧Measurement device
500‧‧‧ human body
600‧‧‧ body
610‧‧‧ seats
620‧‧ ‧ pillar
D1‧‧‧Measurement information
D2‧‧‧ Physiological information
D3‧‧‧Monitoring information
I1‧‧‧ images
I2‧‧‧ images
I‧‧‧Biological appearance image
IR‧‧‧temperature distribution image

1 is a schematic diagram of a unit of an intelligent detection device; FIG. 2 is a perspective view of a first embodiment of the intelligent detection device; FIG. 3 is a perspective view of a second embodiment of the intelligent detection device; Figure 5 is a perspective view of a fourth embodiment of the intelligent detecting device; Figure 6 is a perspective view of a fifth embodiment of the smart detecting device; and Figure 7 is a schematic block diagram of another embodiment of the smart detecting device.

Claims (13)

An intelligent detecting device comprising: a processor; an electrode device electrically connected to the processor, the electrode device comprising a first electrode and a second electrode, wherein a first electrode and the second electrode form a When the loop is detected, a measurement information is generated and transmitted to the processor; and a stereoscopic image capture device is electrically connected to the processor, and the stereoscopic image capture device captures a biometric stereoscopic image and transmits the image to the processor. The processor obtains a biological appearance information according to the biological appearance stereoscopic image, and the processor calculates a physiological information according to the biological appearance information and the measurement information. The smart detecting device of claim 1, further comprising a light source device, wherein the light source device generates a light, and the stereoscopic image capturing device captures a feedback image of the light and transmits the image to the processor. The device further calculates a feedback information according to the feedback image, and the processor calculates the physiological information based on the feedback information, the measurement information, and the biological appearance information. The smart detection device of claim 1, further comprising a housing, the processor being mounted in the housing, the electrode device and the stereoscopic image capturing device being mounted on the housing. The smart detecting device of claim 3, wherein the electrode device is mounted on a surface of the housing. The smart detection device of claim 3, wherein the housing is a wearable object, the processor is disposed in the housing, and the electrode device and the stereoscopic image capturing device are pullably assembled to the case. The smart detecting device of claim 5, wherein the wearable article is a vest, a jacket, a hat, or a combination thereof. The smart detection device of claim 1, further comprising a communication device, the communication device being electrically connected to the processor, receiving the physiological information and transmitting the information. The smart detection device of claim 1, further comprising a first communication unit and a second communication unit, wherein the first communication unit, the processor, and the stereoscopic image capture device are grouped as an intelligent processing device, The second communication unit and the electrode device are combined into a measuring device, and the intelligent processing device and the measuring device are communicatively connected to each other through the first communication unit and the second communication unit. The smart detecting device of claim 8, wherein the smart processing device is a smart phone, a tablet computer, a car body, or a combination thereof. The smart detecting device of claim 8, wherein the measuring device is a one-piece grease meter, a wearable article, a fingerprint sensor, a vehicle body, a heart-shaped power measuring unit, a brain wave measuring unit, or Its combination. The smart detection device of claim 1, wherein the stereoscopic image capturing device comprises at least two camera lenses, wherein the camera lenses respectively capture an image and transmit the image to the processor, and the processor synthesizes the images to generate the image. Stereoscopic image of biological appearance. The smart detection device of claim 1, wherein the stereoscopic image capturing device further comprises an infrared imaging unit that captures a temperature distribution image and transmits the image to the processor, and the processor distributes the image based on the temperature Calculating a temperature feedback information, the processor calculates the physiological information based on the temperature feedback information, the measurement information, and the biological appearance information. The smart detection device of claim 1, wherein the electrode device further comprises a plurality of pairs of electrode sheets, the pair of electrode sheets being electrically connected to the processor, respectively, when each pair of the electrode sheets forms a detection loop And generating a monitoring information to the processor, the processor calculating the physiological information according to the biological appearance information, the measurement information, and the monitoring information.