WO2017114489A1

WO2017114489A1 - Mobile phone having health-monitoring and feedback treatment function

Info

Publication number: WO2017114489A1
Application number: PCT/CN2016/113530
Authority: WO
Inventors: 周国明; 周璇; 周博; 唐丽春; 朱立功
Original assignee: 周国明
Priority date: 2015-12-30
Filing date: 2016-12-30
Publication date: 2017-07-06
Also published as: CN205458634U

Abstract

Provided is a mobile phone having a health-monitoring and feedback treatment function; the display screen (2) of said mobile phone is directly connected to a housing (1), or is connected to and inlaid in the housing (1) by means of a USB connector; the left and right outer sides of the housing (1) are metal panels (5, 6), which serve as two electrodes; the housing (1) is internally provided with a rechargeable battery (3), a circuit board (4), and a USB plug (9); the bottom of the housing (1) is provided with a USB jack (10), and the exterior is provided with a set of function buttons (8), an earphone jack (7), and a spare jack (11); externally connected are a headset sensor (12) and an integrated finger sensor (15); the back side of the housing (1) is provided with a camera Y and a multi-wavelength light emitter X; the mobile phone is small, lightweight, and multi-purpose, has such functions as for the collection, processing, display, and transmission of life and health data, and predicts in real time several important health data concerning the human body, such as heartbeat, heart rate, cardiac rhythm, brain function state, blood oxygen saturation and blood oxygen concentration, breathing frequency, fingertip temperature, finger arterial pressure, and lung function; at the same time, it adjusts and treats some organ functions, and is used for individuals, families, community medical stations, hospitals, and emergency centers of all levels.

Description

Mobile phone with health monitoring and feedback therapy

This application claims priority to Chinese patent application filed on Dec. 30, 2015, with the application number CN201521110632.X, entitled "A mobile phone with health monitoring and feedback therapy functions", the entire contents of which are incorporated by reference. Combined in this application.

Technical field

The present application belongs to the technical field of medical device for life science human health monitoring, and particularly relates to a mobile phone with health monitoring and feedback therapy functions.

Background technique

It is well known that clinical data such as body temperature, blood pressure, heart rate, ECG, EEG, and oxygen saturation are objective reflections of human physical activity and are the basic basis and important indicators for judging physical health. The basic data of these vital signs are not only required by the medical staff in the hospital, but also the patients themselves after discharge and their families and nursing staff need to understand and master. However, the current status quo at home and abroad: The above-mentioned life indicators can only be monitored in the hospital operating room or in the intensive care unit, that is, only to meet the medical needs of the hospital, but not to meet the needs of the society. In this way, a large number of elderly people and patients who need out-of-hospital or home care can not get adequate supervision and timely treatment, and there are some patients who do not need hospitalization indicators and need to be supervised to take risks in their homes and jobs. Security risks. In addition to the above-mentioned patients and middle-aged and elderly people, with the improvement of people's living standards, some young people who are sporty, although there is no disease, but exist Hidden dangers, in order to protect the health of the body, there are also requirements for independent monitoring at any time. To this end, in recent years, domestic and foreign experts are working on the development of small portable health monitoring instruments.

For example, "a remote health monitoring watch" announced by the Chinese patent CN201310124629, "a wearable wireless life information device" announced by CN201120073585, "wearing sensor based elderly health monitoring vest" announced by CN201310238024, respectively Use wristbands, headbands, straps, belts, and vests to collect body information, and provide data such as pulse, blood pressure, heart rate, and body temperature through mobile communication network systems, central processors, and terminal monitors, so that people at the terminal can see them at any time. Relevant information, to understand the person's life and health status, to meet the current needs of people to monitor the physical parameters. Their common defects are not only inconvenient in information collection, but also have limitations on the parameters of the physical signs. That is, each device can only provide one or two or three technical parameters, so it still cannot meet the actual needs. Another example is Apple's IWATCH, which can only passively monitor the pedometer and pulse rate. There is a health software on Apple IPHONE6, but it can't collect real-time data of vital signs available to doctors such as ECG, EEG, blood oxygen, blood pressure, etc. The amount of exercise can only be roughly estimated by the pedometer information. It is only a healthy concept and cannot provide health monitoring indicators available to the hospital. There are also portable monitors with CRT or LCD screens on the market, but they are bulky and are not easy to carry by the inspectors. In recent years, people have generally noticed the development and utilization of mobile phone functions, and it is inherently envisaged to use smart phones as information disclosure of human body information monitoring terminals. For example, CN103347078A discloses a "home health monitoring method based on Android mobile phone system", "a smart phone-based human body information monitoring terminal and monitoring method" disclosed in CN103462598A, which all conceptually expand the functions of existing mobile phones. Or, in general, the possibility or the way to realize the use of the mobile phone as a human body information monitoring terminal is given. Law, but there are no specific technical measures to achieve this method, so it can not be implemented on the product, that is, these technologies cannot be used as instruments for monitoring vital signs of human body.

Summary of the invention

The purpose of the application is to provide a mobile phone with health monitoring and feedback therapy function, which is small and light, multi-purpose, and can simultaneously predict human electrocardiogram, heart rate and heart rate through information collection, processing, storage, display and communication functions. , EEG, blood oxygen saturation, fingertip blood oxygen concentration, respiratory rate, fingertip temperature, finger arterial pressure, lung function and other important health data, and can make corresponding adjustment plans based on test data, send electricity The signal is remotely and/or closely adjusted by the sensor to restore the health of the human body and reduce the incidence of sudden death.

The application provides a mobile phone with health monitoring and feedback therapy function, which comprises a casing and a display screen, and the display screen is directly connected to the casing through a line, or is embedded in the casing through a USB connector; The two sides are respectively a metal plate, and the metal plate is used as two electrodes; a rechargeable battery, a circuit board and a USB plug are arranged in the casing; and a function key is arranged on the outer front side and the side of the casing or on the display screen The group has a USB jack at the bottom, and a headphone jack and a spare jack respectively on the two sides; and the headset sensor is connected to the USB jack through the headphone jack, and the integrated finger-type sensor is connected with the spare jack; A multi-wavelength camera Y is disposed in the back hole of the shell, and a multi-wavelength light emitter X and a parameter corrector Z are mounted on the side of the camera Y; the lung function detector is coupled to the USB jack.

The display has two modes: one, when the display is directly connected to the case, the normal mode; and the other, when the display is connected to the chassis through the USB connector, it is in the smart phone mode.

A working module is disposed on the circuit board, and the working module is configured to perform a module for human body physiological information collection, signal amplification, signal conditioning, A/D analog-to-digital conversion, and MCU central processing, that is, the working module includes a human body. Information acquisition input module, amplification circuit module, signal conditioning circuit module, A/D analog-to-digital conversion module, MCU central processing module, these modules can be completed on one integrated board; the circuit board also has a universal call working module, It includes a microphone, a speaker, and a Bluetooth module, a network transmission module, a memory and a micro gas pumping system, a parameter effector Z, and constitutes a circuit working system.

The function key group includes a call for emergency call, a remote start keyboard, an emergency call keyboard, an on or off button, a single measurement and continuous dynamic conversion button, a call button, a charging button, and a work opening key.

The headset sensor is a simple brain electric cap on the earphone support frame and then the brain electrode, and the basic electrode has a right ear electrode, a left ear electrode, a left camphor electric electrode, a right camphor electric electrode, a top electrode, and a multi-core The headphone flexible cable is integrated into the headphone plug.

The integrated finger-type sensor is a flat elastic finger sleeve made of elastic insulating material, which is embedded with a finger artery pressure balloon, a gas conduit, a photo-emission tube, a light intensity detector, a skin temperature sensor, and a detection value. The sensor sensor and the skin blood oxygen concentration monitoring sensor are corrected, and are collected by the multi-core flexible wire row to the finger sleeve sensor plug, and the finger sleeve sensor plug is connected with the two electrodes of the outer left and right sides of the casing.

The pulmonary function detector is composed of an oral tube, a tubular airflow sensor bracket, a valve, a pressure sensor, an impeller type photoelectric flow sensor, and a digital processing module connected to the pressure sensor wire and the airflow pulse sensing wire at the same time, digitized. The front end of the processing module is a USB data plug.

There are two product modes in this application: one mode is conventional, that is, it is a stand-alone phone; the other mode is a combination, that is, it is embedded in the charging back case. The former, the circuit and the display are integrated, and the cost is high; the latter, the circuit is integrated in the charging back shell, and the display uses the existing mobile phone, which can save cost. The working principle is: collecting the life signal of the human body by using two sensors connected to the surface of the casing and the external camera, and processing the human life signal through the circuit conversion, and displaying the corresponding result and/or transmitting the relevant data by using the function key group disk on the display screen. . These include: electrocardiogram, heart rate, heart rate, electroencephalogram, blood oxygen saturation, fingertip blood oxygen concentration, respiratory rate, fingertip temperature, ear temperature, finger arterial pressure, lung function test, etc. The description is as follows:

1) Electrocardiogram measurement principle: The metal plates on both sides of the casing are the two electrodes of the left and right hands, and the right ear electrode and the left ear electrode are used as the RA, LA, RL, and LL electrodes of the electrocardiographic electrode, respectively. On the hospital monitor, LL and RL should be installed in the left and right lower limbs. However, it has been proved by experiments that the two electrodes of the right ear electrode and the left ear electrode are equal potential points. The ECG results are not significant when measuring the standard I lead. Differences do not affect the use of health monitoring.

2) Respiratory measurement principle: From the working process and the electrode used in the electrocardiogram test, the impedance value between the electrodes with the electrical impulse change is extracted by the software and hardware, and the parameters such as the respiratory rate can be calculated.

3) The movement comes with X and Y automatic blood oxygen and pulse wave principle: This function is the pulse rate and blood oxygen saturation measuring device that comes with the movement. When the finger is pressed on X and Y, these indicators will be The phone shows up. The working principle is: when × according to the MCU instruction, different wavelengths of light are emitted in turn, Y synchronously accepts the light intensity of different wavelengths under the control of the MCU command and becomes an electrical signal classification acquisition and storage, according to the difference between oxygen and hemoglobin and reduced hemoglobin. The change of the absorption rate of the wavelength light can obtain the value of the blood oxygen saturation, and the number of pulse waves is detected according to the peak of the light intensity fluctuation caused by the pulse wave change. The parameter correction device in the movement is used to correct the influence of the interference factor on the measured value. This one The full-wavelength photoelectric sensor can be used as a camera to realize the color camera function. In addition, this X can also be used for illumination when selectively emitting white light wavelengths, selectively emitting a specific color flashing alarm signal for use in the rescue.

4) Measuring the oxygen saturation and heart rate, heart rate measurement principle: When the finger is inserted into the finger-type sensor, the dual-wavelength light-emitting tube alternately emits dual-wavelength light under the control of the MCU, and the light is transmitted through the front end of the finger. Receiving tube receiving, the intensity of the light intensity signal is converted into a pulsating electric signal consistent with the pulse pulsation, and is pre-amplified by the electrode output and the input plug into the amplifier, and then the electric signal preliminarily amplified by the amplifier is sent again. The signal conditioner performs data conditioning under the command of the MCU and then sends it to the A/D analog-to-digital converter for analog-to-digital conversion, and then sends the digital signal to the MCU for calculation, that is, the pulse frequency value HR can be obtained. Finally, the blood oxygen saturation value SPO2 was calculated from the change of the two-wavelength light absorption rate of oxyhemoglobin and non-oxyhemoglobin.

5) The principle of measuring the temperature of the fingertip: the electrical signal level outputted by the temperature sensitive element above the temperature sensor is linear with the temperature of the skin it is in contact with. The output electrical signal is amplified by the electrode output and the input plug is sent to the corresponding amplifier for preliminary amplification. After the data is processed through the input plug, it is sent to the analog-to-digital converter to complete the A/D conversion. The MCU calculates the digital signal according to the program rules, and obtains the temperature value of the finger for clinical reference. The significance is that the temperature of the finger can most effectively reflect the microcirculation state, and at a certain time, it has a function relationship with body temperature under certain conditions, and indirectly derives the body temperature value.

6) Measurement principle of temperature in the ear: The protruding portion of 12a and 12b is a side temperature sensor, which is sent to the MCU through 12f, 12g and 4a, thereby measuring the temperature in the ear.

7) The principle of arterial pressure measurement: If the pressure of the finger artery is to be measured, the MCU is started by the keyboard, and the MCU performs the inflation and deflation work of the air pump. The photo-electric tube emits light normally, and the light intensity detector receives the pulse-pulsing degree as soon as it is received. The light intensity signal is converted into an electrical signal. The pressure value is pressed when inflated The force sensor is converted into an electrical signal, which is sent to the amplifier for amplification through the interface and the input plug. The signal conditioner is further amplified under the program control of the MCU and sent to the analog-to-digital converter for A/D conversion, and then the pressure value is calculated by the MCU. The systolic and diastolic pressures of the finger artery can be measured by recording the changes in Korotkoff sound according to the mature technique during the process of venting and deflation. Here, during the inflation process, when the pressure value reaches a point equal to or greater than the finger artery pressure point, the electrical signal received by the photoelectric receiver placed at the distal end of the balloon stops the pulsation, and the pressure value at this time refers to the arterial pressure. Systolic pressure value. During the deflation process, when the pressure in the balloon reaches a point equal to and less than the finger artery pressure, the electrical signal received by the photoreceptor begins to pulsate from small to large as the finger artery pulsates, and the pressure value at the beginning of the pulsation point It also refers to the value of arterial systolic pressure. When the deflation makes the pressure in the balloon equal to the diastolic pressure of the finger artery, the amplitude received by the photoelectric receiver reaches the maximum value. The pressure value in the balloon at this turning point is the diastolic pressure of the finger artery. Value, so that the sensor can measure the arterial pressure while measuring heart rate and oxygen saturation. Its significance: refers to the arterial pressure directly respond to the finger supply, indirect reaction microcirculation, the arterial pressure has a certain functional relationship with the blood pressure value, according to which the correction value measured by the sensory correction sensor can be indirectly through the MCU. Calculate the person's blood pressure value to guide clinical practice.

8) Fingertip blood oxygen concentration measurement principle: The fingertip sensor tip is a set of percutaneous blood oxygen concentration monitoring sensors, including a thermostat and an oxygen electrode. When the system is started, the thermostat is heated to a set value and then thermostated. The oxygen molecules in the tissue are released due to the increase of temperature, and the molecular concentration is a function of the blood oxygen concentration of the arteries. When the oxygen molecules are used for the oxygen measuring electrode, an oxidation reaction occurs with the molecules on the surface of the electrode, and this reaction is generated on the surface of the electrode. The micro-current and the current value are a function of the blood oxygen concentration. At this time, the left and right electrode plates of the casing are used as reference electrodes at normal temperature, and the micro-current signal and the reference electrode signal generated by the skin blood oxygen concentration monitoring sensor are passed. The interface is sent to the amplifier Large, and then through the signal conditioner for data conditioning, mode converter for A / D conversion, and then the MCU calculates the finger oxygen concentration. The significance: the percutaneous oxygen concentration of the fingertips is close to the arterial oxygen concentration, and the custodian and the hospital can evaluate the immediate oxygen metabolism of the patient. If the normal person is in motion, or a certain cause leads to the tissue deficiency There will be significant changes in oxygen. For example, in hyperbaric oxygen therapy, blood oxygen levels can be found to be 27 times higher than in outdoor life, while blood oxygen saturation can only show a maximum of 100%. Therefore, the blood oxygen concentration is more sensitive than the blood oxygen saturation SPO2. The latter measures the oxygen saturation in the red blood cells. Only when the free oxygen is depleted and the combined oxygen of the red blood cells is insufficient, the temperature is delayed compared with the actual hypoxia time. .

9) EEG measurement principle: The headset sensor is embedded with a plurality of bioelectric electrodes electrically connected to the local skin through a conductive substance: the basic electrode has a right ear electrode, a left ear electrode, a left temporal brain electric electrode, and a right camphor The electrical and top electrodes use the microphone signals they reflect to perform general personal health monitoring. In this invention, 8 to 16 electrodes can be placed under the necessity of professional monitoring of the electroencephalogram, and only 5 electrodes are mentioned here, and the electrical signals collected by the electrodes are input to the casing circuit through the headset plug, and the input on the circuit board. After the socket introduces the bioelectric signal, it enters the corresponding signal amplifier preamplifier, and the signal conditioner performs the filtering and amplification processing according to the requirements of the MCU, and sends the analog converter to the mode converter to complete the analog and digital conversion, and then extracts the EEG signal according to the programming requirements of the MCU. The brain function status is analyzed and displayed on the display.

10) The head pulse automatically emits a pulse to stimulate the specific acupuncture points of the scalp to realize the principle of neuromodulation therapy: when the MCU receives the discharge pulse command, it will send a pulse signal back to the programmable amplifier to drive the amplifier 4s to realize program-controlled amplification, and the amplified electrical pulse. Returning to the input electrodes of the head through the input socket, earphone plug and flexible cable, the task of the electrode is to send a discharge pulse to the body. This process can also be realized by Bluetooth-like wireless communication.

11) Call working system, including microphone, speaker, operating keyboard and Bluetooth module, network transmission module, etc., they complete the general communication work under the unified control of MCU, which is equivalent to the function of mobile phone to ensure man-machine dialogue.

12) Principle of pulmonary function test: Put the disposable mouth tube into the mouth. When the human body inhales or exhales the gas, the gas flows into the lung through the tube air flow sensor bracket. The micro-resistance of the valve in the gas flow process makes the two sides of the valve form micro The pressure difference is detected by the pressure sensor and converted into a voltage value. The voltage value is a function of the flow rate and flow rate of the gas. The voltage value is sent to the digital processing module through the pressure sensor wire to become a digital signal, and then sent to the mobile phone through the USB data plug of the mobile phone. The internal MCU displays the lung function parameters on the screen of the mobile phone after calculation by the relevant program of the mobile phone. Another type of detection is an impeller-type photoelectric flow sensor: when a person inhales or exhales gas, the impeller on the impeller photoelectric flow sensor also rotates with the flow of the gas, and the photoelectric device mounted thereon converts the airflow speed into electricity. The pulse signal, the frequency of the pulse and the duty cycle are a function of the strength of the airflow. The pulse signal is sent to the digital processing module via the airflow pulse sensing wire for digital processing, and then sent to the internal MCU of the mobile phone through the USB data plug of the mobile phone, through the mobile phone. After the relevant program is calculated, the lung function parameters are displayed on the screen of the mobile phone. When the above two methods are used together at the same time, the precision is complemented by the advantages and complemented for medical examination, and the cost can be reduced when used alone, and the family health monitoring and lung function screening can be satisfied.

Compared with the prior art, the mobile phone with health monitoring and feedback therapy function provided by the present application is a mobile phone, but it is not a traditional concept mobile phone. Although it has a call function, it is mainly not for making a call. Its purpose is mainly to monitor the vital signs of the human body, in order to save lives and protect health. It is small and light, for the application staff, no matter how old or young, no matter how serious the disease is, as long as it is needed, it can be carried around like a mobile phone; it is multi-purpose, As long as it is held, it can simultaneously predict the human body's ECG, heart rate, heart rate, EEG, blood oxygen saturation, fingertip oxygen concentration, respiratory rate, fingertip temperature, finger arterial pressure, lung function and many other life. Sign data. This instrument provides a guarantee for the health monitoring of individuals and family members, informs patients to provide timely medical treatment, and provides doctors with reliable personal health monitoring indicators in a timely manner, which is conducive to timely treatment of patients; if necessary, it can also be activated by calling for help. The remote data function sends the data to the remote medical center through the wireless network to obtain timely treatment of relevant parties. In addition, when the patient detects that he is in the sub-health state, he can start to adjust the treatment procedure. Some of the signal input sensors set by the mobile phone become the actuator for outputting the therapeutic conditioning signal, and can detect the physiological state again after the treatment is over. The result of the recovery, in order to determine the next direction of treatment, is to adjust or go to the hospital for medical treatment.

DRAWINGS

1 is a schematic diagram of an internal three-dimensional structure of a mobile phone with a health monitoring and feedback therapy function according to an embodiment of the present application;

2 is a rear view structural view of a mobile phone with a health monitoring and feedback therapy function shown in FIG. 1;

3 is a schematic external perspective view of a mobile phone with a health monitoring and feedback therapy function shown in FIG. 1;

4 is a schematic structural view of a headset sensor;

Figure 5 is a schematic structural view of an integrated finger-type sensor;

6 is a schematic diagram of an electrical principle of a mobile phone with a health monitoring and feedback therapy function according to an embodiment of the present application;

Figure 7 is a schematic view showing the structure of a pulmonary function detector.

Description of the reference numerals in FIG. 6: input socket 4a, headset socket 4aa, input plug 4b, amplification circuit module 4c, signal conditioning circuit module 4d, A/D analog-to-digital conversion module 4e, MCU 4f, keyboard 4g, USB interface 4h , LCD display 4i, Bluetooth module 4j, network transmission module / keyboard 4K, memory 4I, air pump 4m, POWER4n, mobile phone working module 4o, microphone 4p, speaker 4q, call module 4r, programmable amplifier drive amplifier 4s;

Description of the reference numerals in Fig. 7: oral tube 16a, tubular air flow sensor holder 16b, flap 16c, pressure sensor 16d, pressure sensor lead 16e, digitization processing module 16f, impeller type photoelectric flow sensor 16g, airflow pulse sensing lead 16h, mobile phone USB data plug 16i.

detailed description

As shown in FIG. 1 and FIG. 2 , the mobile phone with health monitoring and feedback therapy function includes a casing and a display screen, and the so-called display screen 2 is directly connected to the casing 1 through a line. Or the inside of the casing 1 is connected by the USB connector; the left and right sides of the casing 1 are respectively metal plates 5 and 6 as two electrodes; the battery 1 is provided with a rechargeable battery 3, a circuit board 4 and a USB plug. 9; a function key group 8 is arranged on the front lower part and the side or display screen of the outer casing, a USB jack 10 is arranged at the bottom, a headphone jack 7 and a spare jack 11 are respectively arranged on the two sides; and the headset sensor 12 passes through the earphone The jack 7 is connected to the USB jack 10, and the integrated finger-type sensor 15 is connected to the spare jack 11; in addition, a multi-wavelength camera Y is disposed in the back hole of the casing 1, and the side of the camera Y is equipped with a multi-wavelength light emitter. X and parameter corrector Z. They are inside the camera Y The light receiver constitutes a sensor group of blood oxygen saturation, fingertip blood pressure, cardiovascular parameters and fingertip microcirculation parameters.

As shown in FIG. 6, the mobile phone with health monitoring and feedback therapy functions is provided with various plugs and working modules on the circuit board 4, including a human body information collecting input plug 4b, an amplifying circuit module 4c, and a signal conditioning circuit. The module 4d, the A/D analog-to-digital conversion module 4e, the MCU central processing module 4f, and the universal call working module include a microphone 4p, a speaker 4q, and a Bluetooth module 4j, a network transmission module 4K, a memory 4I and a micro-pump 4m. Circuit working system.

As shown in Figure 1-3, the mobile phone with health monitoring and feedback therapy function has a function key group 8 including a call for help, a remote start keyboard, an emergency call keyboard, an on or off button, and a single measurement and Continuous dynamic conversion button, call button, charging button, work switch key, etc. These function keys are distributed on the lower part, the bottom side and the both sides of the front side of the casing 1.

As shown in FIG. 4, the mobile phone with the health monitoring and feedback therapy function has a headset sensor 12 which is a simple brain electric cap on the earphone support frame and then a brain electrode. The basic electrode has a right ear electrode 12a and a left ear electrode 12b. The left sacral electric electrode 12c, the right sacral electric electrode 12e, and the top electrode 12d are integrated into the earphone plug 12g through the multi-core flexible cable 12f by the primary amplification processing.

As shown in FIG. 5, the integrated fingerless sensor 15 of the mobile phone with health monitoring and feedback therapy function is a flat elastic finger sleeve made of elastic insulating material, and the finger artery pressure air bag 15a is embedded thereon. The gas conduit 15b, the photocathode 15c, the light intensity detector 15d, the skin temperature sensor 15e, the detected value correction sensor 15f, the cutaneous blood oxygen concentration monitoring sensor 15g, and are collected to the finger sleeve sensor plug through the multi-core flexible wire row 15h. In addition, the sensor plug is connected to the two electrodes of the metal plates 5 and 6 on the left and right sides of the casing 1. When this fingerless sensor is not inserted At 1500, the measurement of blood oxygen saturation and finger arterial pressure can be automatically switched to the sensor group measurement mode composed of the multi-wavelength camera Y and the multi-wavelength light-emitting component X and the parameter-effect positive sensor Z.

As shown in FIG. 3, the mobile phone with health monitoring and feedback therapy function has a display area and an operation area on the display panel 2, and a display working circuit is arranged therein, the circuit includes a video conversion processing module, and a lower part thereof A USB jack is provided to enable plugging with the plug 1 of the casing 1.

As shown in Fig. 7, the so-called pulmonary function detector is composed of an oral tube 16a, a tubular air flow sensor holder 16b, a valve 16c, a pressure transmitter 16d, an impeller type photoelectric flow sensor 16g, and a pressure sensor wire 16e and an air flow simultaneously. The digitizing processing module 16f is connected to the pulse sensing wire 16h, and the front end of the digitizing processing module 16f is a mobile phone USB data plug 16i to realize connection with the USB jack 10 of the mobile phone. In addition, the lung function detector can also be connected to the earphone jack of the mobile phone.

In summary, the structure in the figure indicates that the mobile phone with health monitoring and feedback therapy function provided by the present application itself and the accessory finger sleeve and the headset are integrated composite multifunctional life health sensors, which have life and health data processing, display, storage and far. The transmission and health self-regulation function is accompanied by functions such as audio, video call, dialogue, and live sound and light rescue with the mobile phone or emergency center. Applicable to individuals, families, community medical stations, hospitals and emergency centers at all levels.

Claims

A mobile phone with a health monitoring and feedback therapy function, comprising a casing (1) and a display screen (2), characterized in that the display screen (2) is directly connected to the casing (1) through a line, Or inlaid into the casing (1) through a USB connector; the outer left and right sides of the casing (1) are respectively metal plates (5, 6), and respectively serve as two electrodes; The casing (1) is provided with a rechargeable battery (3), a circuit board (4) and a USB plug (9); at the lower front side and the side of the outer casing of the casing (1) or the display screen (2) There is a function key group (8), a USB jack (10) is arranged at the bottom, and a headphone jack (7) and a spare jack (11) are respectively arranged on the two sides; and the headset sensor (12) is inserted through the earphone a hole (7) connected to the USB jack (10), an integrated finger-type sensor (15) connected to the spare jack (11); and a hole in the back hole of the casing (1) The multi-wavelength camera Y is equipped with a multi-wavelength light emitter X and a parameter corrector Z on the side of the camera Y; a lung function detector (16) is coupled to the USB jack (10).
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein the display screen (2) has two modes: one, when the display screen (2) is directly connected through the line The casing (1) is in a normal mode when connected; and second, when the display screen (2) is inlaid with the casing (1) through a USB connector, it is in a smart phone mode.
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein a working module is arranged on the circuit board (4), and the working module is configured to complete human body physiological information collection. , signal amplification, signal conditioning, A/D analog-to-digital conversion, MCU central processing module; the circuit board (4) is also provided with a universal call working module, which includes Wind, speaker, and Bluetooth, network transmission module, memory and micro gas pumping system, parameter effector Z, and constitute a circuit working system.
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein the function key group (8) comprises a call for a call, a remote start button, an emergency call keyboard, an on or off Screen key, single measurement and conversion button, call button, charging button, work switch key.
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein the headset sensor (12) is a simple brain electric cap on the earphone support frame and then the brain electrode, and the basic electrode has a right Ear electrode (12a), left ear electrode (12b), left sacral electrode (12c), right sacral electrode (12e), top electrode (12d), and assembled to earphone plug through multi-core flexible cable (12f) (12g).
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein the integrated finger-type sensor (15) is a flat elastic finger sleeve made of elastic insulating material, on which Inlaid with aortic pressure airbag (15a), gas conduit (15b), photoinitiated tube (15c), light intensity detector (15d), skin temperature sensor (15e), detection value correction sensor (15f), blood An oxygen concentration monitoring sensor (15g) is assembled to the finger sleeve sensor plug through a multi-core flexible wire row (15h), and the finger sleeve sensor plug and the metal plate on the outer left and right sides of the casing (1) (5 , 6) The two electrodes are connected.
The mobile phone with health monitoring and feedback therapy function according to claim 1, wherein the pulmonary function detector (16) comprises an oral tube (16a), a tubular air flow sensor holder (16b), and a valve (16c), pressure transmitter (16d), impeller photoelectric flow sensor (16g) and simultaneous pressure sensor wire (16e) and airflow pulse sensing wire (16h) The connected digitization processing module (16f) is constructed, and the front end of the digitization processing module (16f) is a USB data plug (16i).