CN106897562B

CN106897562B - Working method of portable health terminal for travel

Info

Publication number: CN106897562B
Application number: CN201710110292.8A
Authority: CN
Inventors: 王宇航; 黄岑宇
Original assignee: Zhenjiang College
Current assignee: Zhenjiang College
Priority date: 2017-02-28
Filing date: 2017-02-28
Publication date: 2022-04-29
Anticipated expiration: 2037-02-28
Also published as: CN106897562A

Abstract

The invention provides a working method of a travel portable health terminal, which is particularly suitable for users who frequently travel, wherein the functions of the travel portable health terminal comprise an emergency call function, a voice service function, a general function, an intelligent function, a human motion condition monitoring function and a physiological and environmental monitoring function.

Description

Working method of portable health terminal for travel

Technical Field

The invention relates to the field of intelligent wearable equipment, in particular to a working method of a travel portable health terminal.

Background

With the rapid development of electronic information technology, the health terminal is not a strange concept, and various wearable intelligent health terminals gradually enter the lives of people, so that daily basic health monitoring is provided for the people.

Meanwhile, with the continuous increase of national economy and the gradual deepening of open degree to the outside, the tourism industry in China is vigorously developed and bright spots appear frequently, and the domestic trip market is stably increased, the outbound trip market is continuously and rapidly developed, and the inbound trip market is unexpectedly increased since 2015. With the rapid development of the tourism industry, tourism has become the most common leisure mode for the public, and more people frequently choose to travel.

Disclosure of Invention

Problems to be solved by the invention

At present, no working method of a health terminal specially designed for users who frequently travel exists, the existing working method of the health terminal basically only considers the conventional monitoring of human health indexes, but rarely monitors the external environment or considers the difference of related parameters under different motion states of the users when using the health terminal, and related functions specially designed for travel are not provided.

In view of the above problems, an object of the present invention is to provide a working method of a travel-only health terminal, which is particularly suitable for users who frequently travel, and the working method of the health terminal not only performs physiological monitoring of the users, but also performs environmental monitoring and motion state monitoring, and combines acquisition of geographic location information of the users, so as to provide more relevant index monitoring and more accurate early warning reminding for the users, and also provide a relevant intelligent function for the users who travel specially.

Means for solving the problems

The invention provides a working method of a travel portable health terminal, wherein the functions of the travel portable health terminal comprise a human motion condition monitoring function and a physiological and environmental monitoring function, and the realization of the human motion state monitoring function comprises the following steps: step S1, collecting data of the three-axis acceleration sensor, and judging whether the user is in a motion state, if the user is in a static state, entering step S21, and if the user is in a motion state, entering step S22; step S21, using the geographical position information of the user obtained by the GPS module, if the position is changed, judging that the user is in a riding state, then entering step S211, if the position is not changed, then entering step S212; step S212, jointly judging the body posture of the user by using the data of the triaxial acceleration sensor, the gyroscope tester and the heart rate sensor, if the user goes to sleep, entering step S2121, and if not, entering step S2122; step S22, calculating the moving speed of the user by using the geographical position information of the user obtained by the GPS module, and based on the judgment of the moving speed, if the moving speed is high, entering step S221, and if the moving speed is low, entering step S222; step S221, collecting data of a humidity sensor, and if the humidity exceeds a threshold value, entering step S2211, otherwise, entering step S2212; step S2212, jointly judging the body posture of the user by using the data of the triaxial acceleration sensor, the gyroscope tester and the heart rate sensor, if the user is climbing a mountain, entering step S22121, otherwise, entering step S22122; step S211, starting the riding state monitoring; step S2121, starting sleep state monitoring; step S2122, starting sitting state monitoring; step S222, starting running state monitoring, carrying out user step number statistics by using data of the triaxial acceleration sensor, and carrying out running mileage statistics on the user based on data of the GPS module and calculating calorie consumption of the user based on the mileage after the user confirms; step S2211, starting swimming state monitoring; step S22121, starting mountain climbing state monitoring; step S22122, starting walking state monitoring, carrying out statistics of user steps by using data of the triaxial acceleration sensor, and carrying out statistics of walking mileage of the user and calculating calorie consumption of the user based on the mileage after the user confirms based on data of the GPS module; the implementation of the physiological and environmental monitoring function comprises the following steps: the method comprises the steps that a physiological monitoring module is used for collecting physiological condition monitoring data of a user, an environment monitoring module is used for collecting environment monitoring data, and the physiological condition monitoring data and the environment monitoring data of the user are displayed through a touch screen module; according to the real-time motion state of the user judged by the human motion condition monitoring module, each motion state corresponds to different normal ranges of physiological condition monitoring data respectively, if any data in the physiological condition monitoring data of the user exceeds the normal range corresponding to the real-time motion state, alarm information is further displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt; according to the real-time motion state of the user judged by the human motion condition monitoring module, except the sleep state, each motion state corresponds to different normal ranges of environment monitoring data respectively, if any data in the environment monitoring data exceeds the normal range corresponding to the real-time motion state, alarm information is displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt.

Furthermore, the functions of the travel portable health terminal also comprise an emergency call function and a voice service function, the start of the emergency call function and the start of the voice service function both respond to corresponding inputs of a user, the communication module is called in the emergency call function to be connected with a mobile phone to call out an emergency help-seeking telephone, and the audio module is called in the voice service function to detect the voice input of the user and execute the corresponding functions.

Further, the functions of the travel health terminal also comprise a general function, and the realization of the general function comprises the following steps: judging whether time calibration is needed or not, and if so, executing a timing program; judging whether an alarm clock or alarm clock reminding is set or not, and if so, executing an alarm clock service program; then judging whether a schedule or schedule reminding is set, if so, executing a schedule service program; and finally, calling a time schedule display program to display real-time and latest alarm clock and schedule reminding.

Furthermore, the functions of the travel health terminal further comprise an intelligent function, and the intelligent function further comprises an anti-lost function and a partnership function.

Further, the implementation of the anti-lost function comprises the following steps: starting anti-lost configuration, and carrying out Bluetooth pairing on the healthy terminal of the user and the mobile phone of the user; the distance between the health terminal and a mobile phone carried by the person is judged by detecting the Bluetooth signal in real time, if the distance exceeds a preset range, alarm information is displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt; meanwhile, corresponding travel information push of the mobile phone is obtained according to the geographic position information obtained by the GPS module.

Further, according to the working method of the travel portable health terminal, the travel information comprises the geographical position characteristics, the introduction of the scenic spots, the weather forecast and the travel notice of the current scenic spot where the user is located.

Further, the working method of the travel portable health terminal comprises the following steps of: starting the partnership configuration, and carrying out Bluetooth pairing between the healthy terminal and a plurality of other healthy terminals between the partnership; the distance between the members of the partnership is judged by detecting the Bluetooth signals in real time, if the distance exceeds a preset range, alarm information is displayed through a touch screen module, and a loudspeaker in an audio module is called to send out a corresponding alarm prompt; if the paging request exists, the conversation between the members of the partnership is carried out.

ADVANTAGEOUS EFFECTS OF INVENTION

According to the invention, a working method of a travel portable health terminal is provided, so that the health terminal has the following main functions:

1) an emergency call;

2) voice control;

3) general functions: time display, alarm clock reminding, and scheduling;

4) intelligent function: an anti-lost function and a partnership function;

5) monitoring the motion condition of the user in real time: judging exercise state (riding, sleeping, sitting still, running, swimming, climbing, walking), counting steps, mileage, and calorie consumption;

7) monitoring the physiological condition of a user in real time: heart rate, body temperature;

8) and (3) carrying out real-time environment monitoring: uv intensity, formaldehyde and second-hand smoke concentration, PM 2.5.

Through the realization of the functions, the working method of the travel portable health terminal provides more comprehensive monitoring function and better use experience for users who frequently travel.

Drawings

FIG. 1 is a block diagram showing the overall hardware module composition of the travel health terminal of the present invention;

FIG. 2 is a main software functional module composition of the travel portable health terminal of the present invention;

FIG. 3 shows the specific steps of the general functional block implementation of the present invention;

FIG. 4 shows the specific steps of the intelligent function module implementation of the present invention;

fig. 5 shows the specific steps of the human motion state monitoring module according to the present invention.

Detailed Description

The invention is explained in further detail below with reference to the figures and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

The tourism personal health terminal of the present invention, the external shape of which is configured as a bracelet or watch, as shown in fig. 1, includes a central processing module 10, a sensing monitoring module 20, a touch screen module 30, an audio module 40, a GPS module 50, a communication module 60 and a power module 70.

The central processing module 10 includes a main control MCU, and the central processing module 10 is connected to the sensing monitoring module 20, the touch screen module 30, the audio module 40, the GPS module 50, and the communication module 60, respectively, and is configured to control the modules. In specific application, the main control MCU adopts a low-power consumption singlechip, specifically an ARM Cortex-M0 kernel Bluetooth SOC.

The sensing monitoring module 20 includes a physiological monitoring module 21, an environment monitoring module 22 and a human motion state monitoring module 23.

The physiological monitoring module 21 includes a heart rate sensor 211 and a temperature sensor 212, both of which are disposed proximate to the skin of the user's arm. The heart rate sensor 211 adopts a commonly used heart rate measurement mode on wearable equipment, namely photoplethysmography (PPG), and the principle is that light transmittance is changed according to the change of the blood density in arm blood vessels during blood vessel activity, and the photosensitive sensor can bear reflected light of arm skin, sense the change of light field intensity and convert the change into the heart rate. The temperature sensor 212 is used for monitoring the temperature change of the arm body surface of the user, and the temperature of the arm body surface is generally 5-10 degrees lower than the actual temperature of the body. The physiological monitoring module 21 transmits the collected heart rate and temperature monitoring information of the user to the central processing module 10, so that the central processing module 10 can analyze and process the information.

The environment monitoring module 22 includes an ultraviolet sensor 221 and an air quality sensor 222 (specifically TGS8100), and the monitored items include ultraviolet intensity, paint formaldehyde concentration, and second-hand smoke concentration. The environment monitoring module 22 transmits the monitoring information of the ultraviolet intensity, the paint formaldehyde concentration and the second-hand smoke concentration to the central processing module 10, so that the central processing module 10 can analyze and process the monitoring information, and in addition, the central processing module 10 can synchronize the PM 2.5 index in real time through a mobile phone APP and the like.

The human motion state monitoring module 23 includes a three-axis acceleration sensor 231, a gyro-tester 232, and a humidity sensor 233. The signals collected by the human motion state monitoring module 23 are transmitted to the central processing module 10, so that the central processing module 10 can determine the following motion states of the user: riding, sleeping, sitting still, running, swimming, climbing, walking, and also can realize counting steps, mileage and calorie consumption statistics.

The touch screen module 30 is used for displaying related data and accepting input operations of a user. The displayed content comprises physiological monitoring (heart rate and temperature of a user), environmental monitoring (ultraviolet intensity, coating formaldehyde concentration, second-hand smoke concentration and PM 2.5 index), related exercise state, exercise information (steps, mileage and calorie consumption), related prompt information and the like. The input operation by the user includes setting of parameters, emergency call, and the like.

The audio module 40 includes a speaker 41, a microphone 42, and a DSP processing chip 43 electrically connected to the speaker 41 and the microphone 42, respectively. The speaker 41 is used for giving an alarm when necessary according to the control of the central processing module 10. The DSP processing chip 43 is used for encoding and decoding the audio signal transmitted from the microphone 42, and transmitting the processed audio signal to the central processing module 10 for analysis, so as to recognize the voice command and respond.

The GPS module 50 is used to locate the geographical position of the user and transmit the geographical position information of the user to the central processing module 10, so that the central processing module 10 can push the travel information according to the geographical position of the user or determine the motion state of the user by combining the geographical position information of the user.

The communication module 60 is used for performing data transmission and exchange with a portable device such as a mobile phone of a user by a wireless communication method. In a specific application, the communication module 60 adopts a bluetooth communication mode.

The power module 70 is used for supplying power to the above modules. In a specific application, the power module adopts a solar cell or a rechargeable lithium battery.

As shown in fig. 2, the main software function modules of the travel health terminal include an emergency call module, a voice service module, a general function module, an intelligent function module, a human motion state monitoring module, and a physiological and environmental monitoring module.

Wherein the emergency call module and the voice service module are both activated in response to respective inputs from the user. The emergency call module is used for realizing an emergency call function, and specifically, the communication module 60 is called to connect the mobile phone to call out an emergency call for help. The voice service module is used for implementing a voice service function, specifically, invoking the audio module 40 to detect a voice input of a user and execute a corresponding function.

The specific designs of the general function module, the intelligent function module, the human motion state monitoring module and the physiological and environmental monitoring module are described in detail below.

The universal function module is used for realizing the universal functions of the tourism portable health terminal, including time display, alarm clock reminding and schedule arrangement. Since the embedded system uses a clock chip (RTC)/calendar chip for clocking, resulting in accumulated errors, calibration must be performed at regular intervals. As shown in fig. 3, the specific steps implemented for the general functional module are briefly described as follows.

Judging whether time calibration is needed or not, and if so, executing a timing program; judging whether an alarm clock or alarm clock reminding is set or not, and if so, executing an alarm clock service program; then judging whether a schedule or schedule reminding is set, if so, executing a schedule service program; and finally, calling a time schedule display program to display real-time and latest alarm clock and schedule reminding.

The intelligent function module is used for realizing the intelligent functions of the travel-along health terminal, including an anti-lost function and a partnership function. As shown in fig. 4, the specific steps implemented for the intelligent function module are briefly described as follows.

Judging whether an anti-loss function is used or not, and if so, calling an anti-loss configuration program; judging whether the partnership function is used, if so, calling a partnership configuration program; the Bluetooth pairing is carried out on the healthy terminal of the user and the mobile phone of the user in the loss prevention configuration program, and the Bluetooth pairing is carried out between the healthy terminal and other healthy terminals in the partnership configuration program. In the loss prevention function mode, the distance between the health terminal and the mobile phone carried by the person is judged by detecting the Bluetooth signal in real time, if the distance exceeds a preset range, the alarm information is displayed through the touch screen module 30, and a loudspeaker 41 in the audio module 40 is called to send out a corresponding alarm prompt; meanwhile, the corresponding travel information of the mobile phone is obtained and pushed according to the geographic position information obtained by the GPS module 50, and the travel information is specifically the geographic position characteristics, introduction of scenic spots, weather forecast, travel notice and the like of the current scenic spot where the user is located. In the partnership function mode, the distance between the members of the partnership is judged by detecting Bluetooth signals in real time, if the distance exceeds a preset range, alarm information is displayed through the touch screen module 30, and a loudspeaker 41 in the audio module 40 is called to send out a corresponding alarm prompt; if the paging request exists, the conversation between the members of the partnership can be carried out.

The human motion condition monitoring module is used for judging the motion state of the user in real time and carrying out motion-related data statistics. As shown in fig. 5, the specific steps implemented for the human motion condition monitoring module are briefly described as follows.

Step S1, collecting data of the three-axis acceleration sensor 231, and determining whether the user is in a motion state, if the user is in a stationary state, the step S21 is performed, and if the user is in a motion state, the step S22 is performed.

In step S21, using the geographical location information of the user obtained by the GPS module 50, if the location is changed, it is determined that the user is in a riding state, and the process proceeds to step S211, and if the location is not changed, the process proceeds to step S212.

Step S212, the body posture of the user is determined by using the data of the three-axis acceleration sensor 231, the gyro tester 232 and the heart rate sensor 211, and if the user goes to sleep, the step S2121 is performed, otherwise, the step S2122 is performed.

In step S22, the user' S moving speed is calculated using the geographical location information of the user obtained by the GPS module 50, and based on the determination of the moving speed, the process proceeds to step S221 if the moving speed is fast, and the process proceeds to step S222 if the moving speed is slow.

Step S221, collecting data of the humidity sensor 233, and if the humidity exceeds the threshold, entering step S2211, otherwise, entering step S2212.

In step S2212, the body posture of the user is determined by using the data of the triaxial acceleration sensor 231, the gyro tester 232 and the heart rate sensor 211 together, and if the user is climbing a mountain, the process goes to step S22121, otherwise, the process goes to step S22122.

And step S211, starting the riding state monitoring.

Step S2121, starting sleep state monitoring.

Step S2122, start the resting state monitoring.

Step S222, starting running state monitoring, counting the number of steps of the user by using the data of the three-axis acceleration sensor 231, and counting the running mileage of the user and calculating the calorie consumption of the user based on the running mileage after the user confirms the running mileage based on the data of the GPS module 50.

And step S2211, starting swimming state monitoring.

In step S22121, hill-climbing state monitoring is started.

Step S22122, the monitoring of the walking state is started, the data of the triaxial acceleration sensor 231 is used to count the number of steps of the user, and after the user is confirmed, the walking mileage of the user is counted based on the data of the GPS module 50 and the calorie consumption of the user is calculated based on the walking mileage.

The physiological and environmental monitoring module is used for monitoring the physiological condition and the environment of the user in real time and reasonably early warning the human motion state obtained by judgment of the human motion state monitoring module. The physiological and environmental monitoring module is implemented by the following steps.

The physiological condition monitoring data (heart rate and temperature information) of a user are collected by a physiological monitoring module 21, the environment monitoring data (ultraviolet intensity, coating formaldehyde concentration and second-hand smoke concentration, and real-time synchronous PM 2.5 index of a central processing module 10) are collected by an environment monitoring module 22, and the physiological condition monitoring data and the environment monitoring data of the user are displayed by a touch screen module 30; according to the real-time motion state of the user judged by the human motion condition monitoring module, each motion state corresponds to different normal ranges of physiological condition monitoring data, if any data in the physiological condition monitoring data of the user exceeds the normal range corresponding to the real-time motion state, alarm information is further displayed through the touch screen module 30, and a loudspeaker 41 in the audio module 40 is called to send out a corresponding alarm prompt; according to the real-time motion state of the user judged by the human motion condition monitoring module, except the sleep state, each motion state corresponds to different normal ranges of environment monitoring data, if any data in the environment monitoring data exceeds the normal range corresponding to the real-time motion state, the alarm information is displayed through the touch screen module 30, and the loudspeaker 41 in the audio module 40 is called to send out a corresponding alarm prompt.

Claims

1. A working method of a travel portable health terminal, the functions of which comprise a human motion state monitoring function and a physiological and environmental monitoring function, is characterized in that:

the human motion state monitoring function is realized by a human motion state monitoring module, and the human motion state monitoring function comprises the following steps:

step S1, collecting data of the three-axis acceleration sensor, and judging whether the user is in a motion state, if the user is in a static state, entering step S21, and if the user is in a motion state, entering step S22;

step S21, using the geographical position information of the user obtained by the GPS module, if the position is changed, judging that the user is in a riding state, then entering step S211, if the position is not changed, then entering step S212;

step S212, jointly judging the body posture of the user by using the data of the triaxial acceleration sensor, the gyroscope tester and the heart rate sensor, if the user goes to sleep, entering step S2121, and if not, entering step S2122;

step S22, calculating the moving speed of the user by using the geographical position information of the user obtained by the GPS module, and based on the judgment of the moving speed, if the moving speed is high, entering step S221, and if the moving speed is low, entering step S222;

step S221, collecting data of a humidity sensor, and if the humidity exceeds a threshold value, entering step S2211, otherwise, entering step S2212;

step S2212, jointly judging the body posture of the user by using the data of the triaxial acceleration sensor, the gyroscope tester and the heart rate sensor, if the user is climbing a mountain, entering step S22121, otherwise, entering step S22122;

step S211, starting the riding state monitoring;

step S2121, starting sleep state monitoring;

step S2122, starting sitting state monitoring;

step S222, starting running state monitoring, carrying out user step number statistics by using data of the triaxial acceleration sensor, and carrying out running mileage statistics on the user based on data of the GPS module and calculating calorie consumption of the user based on the mileage after the user confirms;

step S2211, starting swimming state monitoring;

step S22121, starting mountain climbing state monitoring;

step S22122, starting walking state monitoring, carrying out statistics of user steps by using data of the triaxial acceleration sensor, and carrying out statistics of walking mileage of the user and calculating calorie consumption of the user based on the mileage after the user confirms based on data of the GPS module;

the implementation of the physiological and environmental monitoring function comprises the following steps:

the method comprises the steps that a physiological monitoring module is used for collecting physiological condition monitoring data of a user, an environment monitoring module is used for collecting environment monitoring data, and the physiological condition monitoring data and the environment monitoring data of the user are displayed through a touch screen module; according to the real-time motion state of the user judged by the human motion state monitoring module, each motion state corresponds to different normal ranges of physiological condition monitoring data respectively, if any data in the physiological condition monitoring data of the user exceeds the normal range corresponding to the real-time motion state, alarm information is further displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt; according to the real-time motion state of the user judged by the human motion state monitoring module, except the sleep state, each motion state corresponds to different normal ranges of environment monitoring data respectively, if any data in the environment monitoring data exceeds the normal range corresponding to the real-time motion state, alarm information is displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt;

the functions of the travel portable health terminal comprise an intelligent function, and the intelligent function comprises an anti-lost function and a partnership function;

the implementation of the anti-lost function comprises the following steps: starting anti-lost configuration, and carrying out Bluetooth pairing on the healthy terminal of the user and the mobile phone of the user; the distance between the health terminal and a mobile phone carried by the person is judged by detecting the Bluetooth signal in real time, if the distance exceeds a preset range, alarm information is displayed through the touch screen module, and a loudspeaker in the audio module is called to send out a corresponding alarm prompt; meanwhile, corresponding travel information push of the mobile phone is obtained according to the geographic position information obtained by the GPS module;

the implementation of the partnership function comprises the following steps: starting the partnership configuration, and carrying out Bluetooth pairing between the healthy terminal and a plurality of other healthy terminals between the partnership; the distance between the members of the partnership is judged by detecting the Bluetooth signals in real time, if the distance exceeds a preset range, alarm information is displayed through a touch screen module, and a loudspeaker in an audio module is called to send out a corresponding alarm prompt; if the paging request exists, the conversation between the members of the partnership is carried out.

2. The operating method of the travel health terminal as claimed in claim 1, wherein the operating method comprises: the functions of the travel-along health terminal also comprise an emergency call function and a voice service function, wherein the start of the emergency call function and the start of the voice service function both respond to corresponding input of a user, the communication module is called in the emergency call function to be connected with a mobile phone to call out an emergency help-seeking telephone, and the audio module is called in the voice service function to detect the voice input of the user and execute the corresponding function.

3. The operating method of the travel health terminal as claimed in claim 1, wherein the operating method comprises: the functions of the tourism personal health terminal also comprise a general function, and the realization of the general function comprises the following steps: judging whether time calibration is needed or not, and if so, executing a timing program; judging whether an alarm clock or alarm clock reminding is set or not, and if so, executing an alarm clock service program; then judging whether a schedule or schedule reminding is set, if so, executing a schedule service program; and finally, calling a time schedule display program to display real-time and latest alarm clock and schedule reminding.

4. The operating method of the travel health terminal as claimed in claim 1, wherein the operating method comprises: the tourism information comprises the geographical position characteristics, scenic spot introduction, weather forecast and tourism attention items of the current scenic spot where the user is located.