WO2017113386A1 - Physical health comprehensive testing platform - Google Patents

Abstract

A physical health comprehensive testing platform, which comprises a sensor module (1) and a higher-level data processing device (2). The sensor module (1) comprises sensors such as an electrocardiography sensor (11), a pressure sensor (12), and a volumetric pulse wave sensor (13). A unified external crystal resonator is employed for time synchronization among the electrocardiography sensor (11), the pressure sensor (12), and the volumetric pulse wave sensor (13). The sensors such as the electrocardiography sensor (11), the pressure sensor (12), and the volumetric pulse wave sensor (13) respectively are wired or wirelessly connected to the higher-level data processing device (2). Because electrocardiography data inputted into the higher-level data processing device (2) is coordinated with data such as pulse pressure wave, blood oxygen, and heart rate variations, complementary enhancement and interactive effects of joint testing are formed between the sensors (11, 12, and 13) of the physical health comprehensive testing platform, thus increasing the accuracy and validity of detected data, increasing the degree of use convenience for a user, and improving user experience.

Description

 Manual Name: Human Health Comprehensive Testing Platform Technical Field

 [0001] The present invention specifically relates to a human body comprehensive detection platform based on a body surface.

[0002]

 BACKGROUND

 [0004] At present, human body health detection platforms on the market mostly include various sensor components such as blood pressure, blood sugar, brain electricity, body coordinates, temperature or environment, which are mostly in a discrete design manner and lack of correlation between data acquired by each sensor device. The product design of the common human health detection platform is difficult, but the detection efficiency is general. At the same time, the sensor components of the human health detection platform with discrete design can not be fully detected, and the detection function and the recovery training function are separated from each other, which is easy to cause the user to use the problem of low viscosity and difficulty in persistence.

 [0005]

 SUMMARY OF THE INVENTION

 According to a first aspect, an embodiment provides a human health comprehensive detection platform, which includes a sensor module and a first-level data processing device, the sensor module includes an electrocardiogram sensor and a pressure sensor, and the ECG sensor and the device A uniform external crystal oscillator is used to perform the inter-turn synchronization between the pressure sensors; the ECG sensor and the pressure sensor are respectively wired or wirelessly connected to the upper-level data processing device to collect the ECG data collected by the ECG sensor. The pulse pressure wave and the heart rate change data collected by the pressure sensor are sent to the upper-level data processing device to coordinate with each other.

 According to the human body comprehensive detection platform of the above embodiment, each sensor of the human health comprehensive detection platform is made by the coordination of the electrocardiogram data and the pulse pressure wave and the heart rate change number input into the upper-level data processing device. The detection data is more accurate, the user is more convenient to use, and the user experience is better.

 [0009]

 BRIEF DESCRIPTION OF THE DRAWINGS

1 is a structural block diagram of a human body comprehensive detection platform in an embodiment of the present application; [0012] wherein, 1, the sensor module; 11, the ECG sensor; 12, the pressure sensor; 13, the volume pulse wave sensor; 2, the upper level data processing device; 21, the training module; 3, the background server; 4, the temperature module 5, positioning module; 6, air pressure module; 7, gas module; 8, brain electricity acquisition module; 9, blood glucose collection module; 10, medication data module.

 [0013]

 DETAILED DESCRIPTION

 As shown in FIG. 1, the human health comprehensive detection platform in an embodiment of the present application includes a sensor module 1 and a higher-level data processing device 2. The sensor module 1 includes, but is not limited to, an electrocardiograph sensor 11 and a pressure sensor 12.

 [0016] The electrocardiogram sensor 11 collects myocardial nerve activity, and the pressure sensor 12 collects blood volume changes caused by arterial blood vessel beats at the blood vessel test site, and the voltage change signal obtained by the piezoelectric detector reflects the heart rate change. The blood vessel test site includes, but is not limited to, a radial artery or the like. A uniform external crystal is used between the ECG sensor and the pressure sensor 12 for day-to-day synchronization.

 [0017] The electrocardiographic sensor and the pressure sensor 12 are respectively wired or wirelessly connected to the upper-level data processing device 2 to transmit the ECG data collected by the ECG sensor and the pulse pressure wave and heart rate change data collected by the pressure sensor 12 to the upper The primary data processing device 2 cooperates with each other. That is, the principle of joint detection of the ECG sensor and the pressure sensor 12 is as follows:

 [0018] In a normal test environment, the pulse pressure wave obtained by the pressure sensor 12 is compared with the ECG data obtained by the ECG sensor, and the heart rate data is used to guide the post-processing and eigenvalue analysis of the ECG data, and then Data correction and conversion of blood pressure data are performed by the difference between the peak of the electrocardiogram and the pulse pressure wave.

[0019] Specifically, the pulse pressure wave of the measured part to be measured is compared with the electrocardiogram, and the difference between the peak value of the pulse wave and the peak value of the ECG wave and the existing blood pressure calibration data are used, thereby Calculate the corresponding systolic pressure and average pressure of the part to be tested. Considering that the relationship between diastolic blood pressure and systolic blood pressure of the traditional blood pressure tension method is taken from the measured data, as long as the systolic pressure and the average compression standard are confirmed, the diastolic blood pressure is fitted and accurately derived. Therefore, by using the systolic pressure and the average pressure, the diastolic blood pressure measured by the blood pressure tension method can be completed, and mapping and fitting calibration can be performed, and the data of systolic pressure, horizontal pressure, and diastolic pressure can be accurately obtained from the relative relationship. And the ECG peak data of ECG data is more accurate and can be used as heart rate change data. Benchmark data, providing guided training of pressure pulse wave data to calibrate the extraction algorithm.

 [0020] In addition, in some embodiments, the human health comprehensive detection platform is in a special scene, including but not limited to an electromagnetic interference environment and a myoelectric interference of a strong motion state, and the ECG sensor cannot complete the normal acquisition. The pressure sensor 12, which cooperates with the ECG sensor, can provide heart rate change data to supplement. The ECG peak data of the ECG sensor data is more accurate and can be used as a reference data for heart rate changes to provide guidance training for pressure pulse wave data to calibrate the extraction algorithm. In special scenarios including, but not limited to, electromagnetic interference environments and myoelectric interference with strong motion conditions, the ECG sensor fails to perform normal acquisition, and the trained pressure sensor can provide heart rate change data supplementation.

 [0021] Referring to FIG. 1, the sensor module 1 further includes a volume pulse wave sensor 13, which includes, but is not limited to, a projected oximetry probe or a reflective oximetry probe.

 [0022] The volume pulse wave sensor 13 mainly functions to assist in collecting heart rate change data. The volume pulse wave sensor 13 collects the blood volume change caused by the arterial pulsation at the blood vessel test site, and the voltage change signal obtained by the photodetector reflects the change of the blood oxygen value, reflecting the heart rate change, and the blood vessel test site includes but is not limited to 桡Arteries, etc. A uniform external crystal oscillator is used between the volumetric pulse wave sensor 13 and the electrocardiographic sensor for daytime synchronization.

 [0023] The volume pulse wave sensor 13 is wired or wirelessly connected to the above-mentioned upper-level data processing device 2 to collect the pulse pressure wave and the heart rate change data from the ECG data collected by the ECG sensor and the volume pulse wave sensor 13. Coordinate with each other in the data processing device 2 of the upper level. That is, the principle of the combined detection of the electrocardiographic sensor 11 and the pressure sensor 12 and the volume pulse wave sensor 13 is as follows:

 [0024] In a normal test environment, the pulse pressure wave obtained by the pressure sensor 12 is compared with the ECG data obtained by the ECG sensor, and the heart rate data is used to guide the post-processing and eigenvalue analysis of the ECG data, and then Data correction and conversion of blood pressure data are performed by the difference between the peak of the electrocardiogram and the pulse pressure wave.

 [0025] However, the difference between the above-mentioned ECG sensor and the pressure sensor 12 is that the pressure sensor 12 is sensitive to low frequency pressure interference and cannot be shielded, and the volume pulse wave sensor 13 is sensitive to external light interference but can be shielded by reasonable light. The design is environmentally or shielded. In actual design, the pressure sensor 12 and the volume pulse wave sensor 13 can complement each other.

[0026] After the volume I pulse wave sensor 13, the volume pulse wave sensor 13 acquires the pulse pressure wave The accuracy of the pulse pressure wave acquired by the pressure sensor 12 is more accurate, and therefore, the pulse pressure wave can be acquired only by the volume pulse wave sensor 13. At the same time, the pressure sensor 12 can concentrate on the acquisition of systolic pressure and mean pressure, which provides favorable support for the more accurate estimation of diastolic blood pressure.

 [0027] Also, in some embodiments, the human health comprehensive detection platform is in a special scene, including but not limited to an electromagnetic interference environment and a myoelectric interference of a strong motion state, and the ECG sensor cannot complete the normal acquisition. The volume pulse wave sensor 13 that cooperates with the electrocardiographic sensor 11 can provide heart rate change data for supplementation. The ECG peak data of the ECG sensor data is more accurate and can be used as a reference data for heart rate changes to provide guidance training for volumetric pulse wave data to calibrate the extraction algorithm. In a special scenario (including but not limited to electromagnetic interference environment, low frequency vibration environment and myoelectric interference of strong motion state), the electrocardiographic sensor 11 includes the pressure sensor 12 unable to complete normal acquisition, and thus the trained volumetric pulse wave sensor 13 can Provide heart rate change data supplements.

 [0028] On the other hand, the blood oxygen data processing algorithm of the volume pulse wave sensor 13 and the heart rate change data are mutually correlated, and the accurate heart rate change data provided by the ECG sensor 11 and the pressure sensor 12 and the volume pulse wave sensor 13 are jointly detected. Accurate extraction of blood oxygen data from the volume pulse wave sensor 13 can be supported.

[0029] In addition, the combined processing of the volume pulse wave sensor 13 and the pressure sensor 12 can further enhance the accurate extraction of the blood oxygen data of the volume pulse wave sensor 13. The acquisition and post-processing software algorithm processing, blood oxygen data and blood vessel pulse pressure data are correlated with each other, according to the blood pressure tension measurement principle, when the applied pressure of the blood vessel pulse pressure sensor test probe is equivalent to the blood vessel wall pressure, the blood pressure wave The amplitude is the strongest. Judging by the extreme value of the amplitude of the blood pressure wave, the pole can be selected as the screening criterion for the optimal collection point of blood pressure and blood oxygen data, and the two sets of data of blood oxygen and blood vessel pulse pressure are mutually complementary. The bottleneck of the traditional reflective blood oxygen test is that the test result is related to the test site and the degree of contact with the body surface, and the data output is unstable. With the aid of the blood pressure wave amplitude pole as the auxiliary criterion, the blood vessel is flat and the probe is in contact with the skin. Stable measurable, thus the parameters of vascular pulse pressure, can be used as an auxiliary criterion for optimal blood oxygen data screening, considering the principle of mechanical forward and reverse transmission and interaction, the reference criterion is applicable to the blood oxygen sensor probe described in the right one. Combined with the pressure sensor probe (including but not limited to, the reflective oximeter is built into the pressure sensor pressure transmitting probe, the two are in contact with the part to be tested; or the reflective oximeter is built in the back of the pressure sensor housing, The finger of the tester presses the blood vessel probe and the surface on which it is facing, and presses the blood vessel part of the body surface that the sensor has contacted with the pressure sensor. Obtain various forms of vascular pulse pressure 待 of the site to be tested, and the blood oxygenation data of the reflective oximeter from the pressure finger.

 [0030] Further, the introduction of the volume pulse wave sensor 13 improves the blood pressure estimation processing according to claim 1: In comparison with the method in which the electrocardiographic sensor 11 and the pressure sensor 12 according to claim 1 perform blood pressure training estimation, the volume pulse wave sensor 13 is introduced. Later, the pulse wave can be extracted by the volume pulse wave sensor 13, which is more accurate and complementary to the pressure sensor. The same pressure sensor can focus on the treatment of systolic pressure and average pressure for more accurate blood pressure training. The calculation results provide favorable support.

 [0031] Referring again to FIG. 1, the human health comprehensive detection platform further includes a temperature module 4, which is respectively wired or wirelessly connected to the sensor module 1 and the upper-level data processing device 2 described above.

 [0032] The temperature module 4 includes, but is not limited to, an external infrared body temperature sensor, an ambient temperature sensor, and a built-in device temperature sensor. Among them, the external infrared sensor is mainly used to provide human body temperature data. Ambient temperature sensors are mainly used to warn of extreme ambient temperatures, abnormal equipment temperatures, and abnormal body temperatures. The built-in device temperature sensor is mainly used to provide the ambient temperature data of each of the above sensors to provide a reference for the calibration of the collected data of each of the above sensors.

 [0033] Referring again to FIG. 1, the human health comprehensive detection platform further includes a positioning module 5, which is respectively wired or wirelessly connected to the sensor module 1 and the upper-level data processing device 2 described above.

 [0034] The positioning module 5 includes, but is not limited to, a three-dimensional accelerometer, an inertial gyroscope, and a GPS device. Among them, the three-dimensional accelerometer and the inertial gyroscope can be either an integrated integrated design or a discrete design. The main function of the three-dimensional accelerometer and inertial gyroscope is to locate the human body posture, including but not limited to sitting, lying, lying and falling. The main function of the GPS device is to provide outdoor position coordinates. When the position coordinates acquired by the G PS device are interrupted indoors, combined with the coordinates of the break point, the data provided by the reference three-dimensional accelerometer and the inertial gyroscope can jointly detect the traveling direction and distance after the interruption point, thus passing through the three-dimensional accelerometer The cooperation with the inertial gyroscope and the GPS device can complement the indoor position coordinates and height data. The accuracy of the indoor position coordinates and height data is related to the matching accuracy of the GPS device and the three-dimensional accelerometer and the inertial gyroscope.

[0035] Referring again to FIG. 1, the human health comprehensive detection platform further includes a pneumatic module 6, which is wired or wirelessly connected to the positioning module 5 and the upper-level data processing device 2, respectively. And the upper level data processing device 2 can provide a dedicated input interface for the data collected by the air pressure module 6. [0036] The air pressure data collected by the air pressure module 6 provides environmental reference data for the environmental background of the human health data on the one hand, and provides an early warning for the extreme high and low pressure environment. On the other hand, the change of the air pressure is related to the height. The data provided by the air pressure sensor is sent to the positioning module 5, and the data is calibrated by the GPS device, the three-dimensional accelerometer and the inertial gyroscope, and can be corrected by referring to the local barometric altitude change table. Height data.

 [0037] Referring again to FIG. 1, the human health comprehensive detection platform further includes a gas module 7, which is wired or wirelessly connected to the upper level data processing device 2. And the upper level data processing device 2 can provide a dedicated input interface for the data collected by the gas module 7.

 [0038] The gas module 7 includes, but is not limited to, a humidity sensor, an oxygen sensor, a carbon dioxide sensor, a carbon monoxide sensor, and other toxic and harmful gas sensors. The data collected by the gas module 7 provides environmental reference data on the one hand for the environmental background of the human health data, and on the other hand provides an early warning of the toxic and harmful environment. Among them, the toxic and harmful environment includes high humidity environment.

 [0039] Referring again to FIG. 1, the human health comprehensive detection platform further includes an EEG acquisition module 8, and the EEG acquisition module 8 is connected to the upper-level data processing device 2 by wire or wirelessly. And the upper level data processing device 2 can provide a dedicated input interface for the data collected by the brain electrical collection module 8. The neural activity of the brain is closely related to the body temperature, blood oxygen, heart rate, and blood pressure of the human body. This data correlation can be combined with data detection in the superior data processing platform.

 [0040] Referring again to FIG. 1, the human health comprehensive detection platform further includes a blood glucose collection module 9, and the blood glucose collection module 9 is wired or wirelessly connected to the upper-level data processing device 2. And the upper level data processing device 2 can provide a dedicated input interface for the data collected by the blood glucose collecting module 9. Blood sugar is closely related to human body temperature, blood oxygen, heart rate, and blood pressure. This data correlation can be combined with data detection in a superior data processing platform.

 [0041] Referring again to FIG. 1, the human health comprehensive detection platform further includes a medication data module 10, which is wired or wirelessly connected to the upper-level data processing device 2. And the upper level data processing device 2 can provide a dedicated input interface for the data collected by the medication data module 10. The effect of medication is closely related to the body temperature, blood oxygen, heart rate, and blood pressure of the human body. This data correlation can be combined with data detection in a superior data processing platform.

[0042] The data collected by the medication data module 10 includes a record of the medication demand for the medicine, and a record of the medicine production information. Record, the number of medications and the dose of medication. In addition, the upper-level data processing device 2 may also store prompt alarms for medical record, medical record, medication reminder, drug side effects, and drug contraindication.

Referring again to FIG. 1, the superior data processing apparatus includes a training module 21 and a display interface for providing a feedback-type human body relaxation and nervous system human self-control training function. The display interface displays human heart rate data, blood oxygen pulse wave and dynamic blood oxygen test data, dynamic blood pressure test data, and brain wave test data.

[0044] The training principle of the training module 21 is as follows: heart rate, blood oxygenation, respiratory rate and brain wave change are the result of the brain's control of the external environment stress reaction and the internal plant nervous system and respiratory exchange cooperative control, the human body has considerable Self-control ability, through training to regulate the sympathetic nervous system, thereby affecting the body's performance and immune system and brain nerve excitation state, and the best physiological feedback indicators of human self-control, such as ECG data and heart rate changes, etc. Completed through long-term training. If arrhythmia, hypoxemia, and anxiety are found during the test, and after a period of time, the human health comprehensive test platform will recommend this training function. This function requires the user to gaze at the actual ECG or oximetry pulse diagram of the above display interface during the health data activity, and adjust the breathing and muscle strength activity guidance according to the audio guidance, including but not limited to deep breathing and rapid breathing, muscle strength Activities include, but are not limited to, clenching fists to relax and hold. The peer assists the musical background with a rhythm similar to the target heart rate. Through fast-paced background music and breathing guidance and muscle strength activity guidance, you can improve your heart rate, blood pressure, blood oxygenation and high brain nerve excitement. You can reduce your heart rate by relaxing the background music and breathing world and muscle strength activities. , blood pressure and blood oxygen value, soothing brain nerves. In this alternate training, the user can adjust the sympathetic nervous system control, thereby restoring the normal physiological function, thereby achieving the relief of the body pressure and improving the human immune system. It is a simple and auxiliary benign circulation feedback type self-control exercise system. Through the integration of testing and training. Abandoning the past passive testing method of boring test, adopting a new active interaction mode with the human being as the core. While greatly increasing the amount of effective sampling data and sampling data distribution points and frequency, enhance user viscosity and long-term adherence.

[0045] Referring again to FIG. 1, the human health comprehensive detection platform further includes a background server 3 connected to the upper-level data processing device by wire or wirelessly. It should be noted that the data transmitted to the upper-level data processing device can be further transmitted to The background server 3 stores the data, and the upper-level data processing device can also retrieve the data in the background server 3. In addition, the above superior data processing includes a mobile terminal having a human health app. Display terminal at the end. The mobile terminal includes a smart phone, a tablet pad, and a PC/tablet two-in-one smart device. The display terminal includes, but is not limited to, a mobile terminal screen, a computer screen, a wearable device display, a projection display, and a smart glasses display.

 The present invention has been described with reference to the specific examples, which are intended to be illustrative of the invention and are not intended to limit the invention. Variations to the above specific embodiments may be made by those skilled in the art in light of the teachings of the present invention.

technical problem

Problem solution

Advantageous effects of the invention

Claims

Claim

 [Claim 1] A human health comprehensive detection platform, comprising: a sensor module and a higher-level data processing device, wherein the sensor module includes an electrocardiogram sensor and a pressure sensor, and the electrocardiographic sensor and the pressure sensor The electrocardiographic sensor and the pressure sensor are respectively wired or wirelessly connected to the upper-level data processing device by using a unified external crystal oscillator to collect the ECG data collected by the ECG sensor and the pressure sensor. The pulse pressure wave and heart rate change data are sent to the upper level data processing device to coordinate with each other.

 [Claim 2] The human health comprehensive detection platform according to claim 1, further comprising a volumetric pulse wave sensor, wherein the volume pulse wave sensor and the electrocardiographic sensor and the pressure sensor are unified The external crystal oscillator performs the inter-turn synchronization; the volume pulse wave sensor is wired or wirelessly connected to the upper-level data processing device, and the data related to the blood oxygen concentration and the heart rate change collected by the volume pulse wave sensor is sent to the upper-level data. In the processing device, the electrocardiogram data collected separately from the electrocardiographic sensor and the pressure sensor are coordinated with the pulse pressure wave and the heart rate change data.

 [Claim 3] The human health comprehensive detection platform according to claim 2, further comprising a temperature module, wherein the temperature module is respectively wired or wirelessly connected to the sensor module and the upper-level data processing device .

 [Claim 4] The human health comprehensive detection platform according to claim 3, wherein the temperature module includes, but is not limited to, an external infrared body temperature sensor, an ambient temperature sensor, and a built-in device temperature sensor.

 [Claim 5] The human health comprehensive detection platform according to claim 2, further comprising a positioning module, wherein the positioning module is respectively wired or wirelessly connected to the sensor module and the upper-level data processing device.

 [Claim 6] The human health comprehensive detection platform according to claim 5, wherein the positioning module includes, but is not limited to, a three-dimensional accelerometer, an inertial gyroscope, and a GPS device.

[Claim 7] The human health comprehensive detection platform according to claim 5, further comprising The air pressure module is connected to the positioning module and the upper-level data processing device by wire or wirelessly.

 [Claim 8] The human health comprehensive detection platform according to claim 2, further comprising a gas module, wherein the gas module is wired or wirelessly connected to the upper-level data processing device

[Claim 9] The human health comprehensive detection platform according to claim 8, wherein the gas module includes, but is not limited to, a humidity sensor, an oxygen sensor, a carbon dioxide sensor, and a carbon monoxide sensor.

 [Claim 10] The human health comprehensive detection platform according to claim 2, further comprising an EEG acquisition module, wherein the EEG acquisition module is respectively wired or connected to the sensor module and the upper-level data processing device Wireless connections.

[Claim 11] The human health comprehensive detection platform according to claim 2, further comprising a blood glucose collecting module, wherein the blood glucose collecting module is respectively wired or wirelessly connected to the sensor module and the upper level data processing device .

[Claim 12] The human health comprehensive detection platform according to claim 2, further comprising a medication data module, the medication data module being wired or wirelessly connected to the upper-level data processing device.

 [Claim 13] The human health comprehensive detection platform according to claim 12, wherein the upper-level data processing device stores a medical record, a medical record, a medication reminder, a drug side effect, and a drug contraindication Alarm.

 [Claim 14] The human health comprehensive detection platform according to claim 2, wherein the superior data processing device includes a training module for providing feedback-type human body relaxation and human body self-control training of the nervous system, and The display interface for presenting the heart rate data of the human body, the blood oxygen pulse wave and the dynamic blood oxygen test data, the dynamic blood pressure test data, and the brain wave test data, wherein the training module is electrically connected to the display interface.

[Claim 15] The human health comprehensive detection platform according to any one of claims 1 to 14, further comprising a background server wired or wirelessly connected to the upper-level data processing device.

[Claim 16] The human health comprehensive detection platform according to claim 15, wherein the number According to the processing device, the display terminal includes a mobile terminal having a human health app, and the mobile terminal includes, but is not limited to, a smart phone, a tablet pad, and a PC/tablet two-in-one smart device.

[Claim 17] The display terminal includes, but is not limited to, a mobile terminal screen, a computer screen, a wearable device display screen, a projection display, and a smart glasses display.