CN113160968B - Personalized diagnosis system based on mobile internet and application method - Google Patents

Abstract

The invention provides a personalized diagnosis system and an application method based on mobile Internet. The diagnosis system comprises embedded interactive exercise equipment with a human-computer interactive display interface; the man-machine interaction display interface comprises a first display area and a second display area; the embedded interactive exercise device is provided with a first variable space and a second variable space; the embedded interactive exercise equipment receives personalized diagnosis information sent by the mobile internet platform; the personalized diagnosis information includes first exercise guidance information and second exercise effect information; displaying the first exercise guidance information in the first display area and the second exercise effect information in the second display area; adjusting the size of the first variable space and/or the second variable space based on the interactive feedback information of the first display area and/or the second display area. The invention can realize personalized diagnosis based on the embedded equipment with limited memory space.

Description

Personalized diagnosis system based on mobile internet and application method

Technical Field

The invention belongs to the technical field of personalized remote diagnosis, and particularly relates to a personalized diagnosis system and an application method based on mobile internet.

Background

In the internet + context, a new model for national fitness has also emerged. Various sports fitness APPs have been brought to the birth, great convenience is provided for people, meanwhile, fitness sports are effectively popularized, and the scale of fitness groups is enlarged.

Health APPs can only provide basic exercise and interactive perception, and the popularity of home exercise devices is the first beginning of personalized exercise. The Chinese invention patent application with the application number of CN201910558157.9 provides a fitness system capable of being customized in a personalized mode, and the fitness system comprises a portable monitoring unit, a servo unit, a winding mechanism, a force transmission medium, an operation unit, a human-computer interaction unit and a cloud end. The fitness system provided by the invention is suitable for different people with different heights and different arm lengths, realizes personalized fitness customization, and has the following advantages and positive effects: different from the traditional self-weight or weight-balance type fitness items, the active and passive fitness exercises can enable a body builder to feel resistance by setting corresponding torque, so that the fitness equipment is safe and can increase the fitness effect and the fitness experience. Aiming at different crowds, the body-building system can memorize the optimal starting and stopping operation position of a certain body-building project of the person, so that the same body-building system is suitable for different crowds to carry out humanized customized body-building, and is economical and practical. The normal people can build body correctly and safely without the help of the training coach.

However, with the increasing maturity of embedded technologies and their wide application in biomedical engineering, medical health devices are developing to be miniaturized and portable. However, the memory of embedded devices is usually limited, which is different from a general computer processing system, for example, it does not usually use a large capacity storage medium like a hard disk, but most use EPROM, EEPROM or flash memory as a storage medium. The application controls the operation and behavior of the system, while the operating system controls the programming of the application to interact with the hardware. Embedded systems are often specific to a particular application in some respect, and their hardware is designed for a particular user population, often with some specificity.

However, for concepts such as cloud health, cloud exercise, and the like, a certain data center simultaneously serves a large number of remote users, for example, corresponding exercise guidance information/effect information is given according to physiological parameters reported by the users in real time, and the data center cannot match the data one by one to be suitable for the size and format of the hardware equipment of the remote users, which causes the problem that the users using the embedded equipment are usually stuck and unable to normally display pictures; meanwhile, the remote data center cannot sense the interest points of the user side in real time, and cannot make corresponding adjustment according to the personalized requirements of the user.

Disclosure of Invention

In order to solve the technical problems, the invention provides a personalized diagnosis system and an application method based on the mobile internet. The diagnosis system comprises embedded interactive exercise equipment with a human-computer interactive display interface; the man-machine interaction display interface comprises a first display area and a second display area; the embedded interactive exercise device is provided with a first variable space and a second variable space; the embedded interactive exercise equipment receives personalized diagnosis information sent by the mobile internet platform; the personalized diagnostic information comprises first exercise guide information and second exercise effect information; displaying the first exercise guidance information in the first display area and the second exercise effect information in the second display area; adjusting the size of the first variable space and/or the second variable space based on the interaction feedback information of the first display area and/or the second display area.

Specifically, in a first aspect of the invention, a personalized diagnosis system based on the mobile internet is provided, and the diagnosis system comprises an embedded interactive exercise device, wherein the embedded interactive exercise device is provided with a human-machine interactive display interface;

as one of the features of the present invention, the embedded interactive exercise device has a memory space of a first set size;

the human-computer interaction display interface comprises a first display area and a second display area;

the memory space is provided with a first variable space and a second variable space;

the embedded interactive exercise equipment is provided with a wireless communication interface, is communicated with a mobile Internet platform through the wireless communication interface and receives personalized diagnosis information sent by the mobile Internet platform;

the personalized diagnosis information comprises first exercise guide information and second exercise effect information;

displaying the first exercise guidance information in the first display area and the second exercise effect information in the second display area;

adjusting the size of the first variable space and/or the second variable space based on the interaction feedback information of the first display area and/or the second display area.

And the first exercise guidance information is used for indicating exercise postures and actions performed by the user;

the second exercise effect information is used to indicate a desired effect of the user after performing the first exercise guidance information.

In a second aspect of the present invention, an application method of a personalized diagnosis system based on the mobile internet is provided, where the personalized diagnosis system includes an embedded interactive exercise device, the embedded interactive exercise device includes a touch display interface and a memory space with a set size, the touch display interface includes a first touch display area and a second touch display area, and the memory space includes a first memory space and a second memory space.

In the method of the second aspect, the steps of:

s800: setting the size of the first memory space to be equal to the size of the second memory space;

s801: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s802: displaying the first exercise guidance information through the first touch display area and displaying the second exercise effect information through the second touch display area;

s803: acquiring touch operation data of a user in the first touch display area and/or the first touch display area within a preset time period;

s804: and adjusting the size of the first memory space and/or the size of the second memory space based on the touch operation data.

In a third aspect of the present invention, a method for applying a personalized diagnosis system based on a mobile internet is further provided, where the personalized diagnosis system includes an embedded interactive exercise device, the embedded interactive exercise device includes a display area and a memory space with a set size, the display area includes a first display area and a second display area, the memory space includes a first memory space and a second memory space, and the first display area and the second display area are both configured with a gaze focus monitoring component;

the method of the third aspect comprises the steps of:

s900: setting the size of the first memory space to be equal to the size of the second memory space;

s901: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s902: displaying the first exercise guidance information through the first touch display area and displaying the second exercise effect information through the second touch display area;

s903: acquiring focusing time length data of focusing of the user's gaze on the first display area and/or the first display area within a predetermined time period;

s904: adjusting the size of the first memory space and/or the size of the second memory space based on the focus duration data.

The above-described method of the present invention may be implemented automatically in the form of program instructions executed by a computer system, and accordingly, in a fourth aspect of the present invention, there is provided a non-volatile storage medium having computer-executable program code instructions stored thereon; the program code instructions are executed by a terminal device comprising a processor and a memory for implementing the method of the second or third aspect.

The invention can realize personalized diagnosis based on the embedded equipment with limited memory space.

Further advantages of the invention will be apparent from the detailed description of embodiments which follows, when considered in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is an overall architecture diagram of a mobile internet-based personalized diagnosis system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of the content display of the human-computer interaction display interface of the system of FIG. 1;

fig. 3 is a flowchart of a first embodiment of an application method of a personalized diagnosis system based on mobile internet, which is implemented based on the system of fig. 1;

fig. 4 is a flowchart of a second embodiment of an application method of a personalized diagnosis system based on the mobile internet, which is implemented based on the system of fig. 1.

Detailed Description

The invention is further described with reference to the following drawings and detailed description.

Referring to fig. 1, it is an overall architecture diagram of a personalized diagnosis system based on the mobile internet according to an embodiment of the present invention.

In FIG. 1, the diagnostic system includes an embedded interactive exercise device with a human interactive display interface.

The man-machine interaction display interface comprises a first display area and a second display area. The embedded interactive exercise device has a memory space of a first set size.

The system used by the embedded device is generally referred to as a non-personal computer system and comprises two parts of software and hardware. The hardware includes processors/microprocessors, memory and peripheral devices and I/O ports, graphics controllers, etc. Such a system is different from a general computer processing system, for example, it does not generally use a large capacity storage medium like a hard disk, but most uses an EPROM, an EEPROM, or a flash memory as a storage medium. The application controls the operation and behavior of the system, while the operating system controls the programming of the application to interact with the hardware.

The embedded server interconnecting the household embedded equipment and the network becomes the best solution for intelligent home and telemedicine, and the embedded equipment can obtain the maximum network resources at the lowest cost. To use an embedded server, the embedded device must support a network communication protocol. The network may provide functions such as telecommunications, online upgrades, access to resources, etc. for the embedded device.

However, in practical applications, for the final purpose, the related network applications are only simple processes on the system, and data exchange between the two processes inevitably causes data copying, thereby causing waste of memory resources. For embedded devices with limited memory, memory resources are quite valuable, and the occupation of system memory resources by a protocol stack is reduced as much as possible.

The memory space is provided with a first variable space and a second variable space.

The embedded interactive exercise equipment is provided with a wireless communication interface, is communicated with a mobile Internet platform through the wireless communication interface and receives personalized diagnosis information sent by the mobile Internet platform.

More specifically, the mobile internet platform comprises a plurality of mobile data sources, including a mobile data center, a mobile cloud platform and an internet platform.

The personalized diagnosis information comprises first exercise guide information and second exercise effect information;

displaying the first exercise guidance information in the first display area and the second exercise effect information in the second display area;

adjusting the size of the first variable space and/or the second variable space based on the interactive feedback information of the first display area and/or the second display area.

Preferably, the memory space is composed of a first variable space and a second variable space; at any time, the sum of the size of the first variable space and the size of the second variable space is equal to the first set size.

As another preferable mode, at any time, the size of each of the first variable space and the second variable space is larger than a set minimum value.

On the basis of fig. 1, see fig. 2.

The first exercise guidance information is used for indicating exercise postures and actions performed by the user;

the second exercise effect information is used to indicate a desired effect of the user after performing the first exercise guidance information.

Displaying the first exercise guidance information in the first display area, including:

displaying an exercise picture corresponding to the exercise gesture and action performed by the indicated user in the first display area;

displaying the second exercise effect information in the second display area, including:

displaying an expected effect map of the user after performing the first exercise guidance information in the second display area.

More specifically, referring to fig. 2, the expected effect map is a plurality of effect maps displayed in a gradually enlarged manner as a time trend changes.

More specifically, in the above embodiment, the first display area and the second display area each include a gaze monitoring component, and the gaze monitoring component is configured to monitor a duration for which a user's gaze focuses on the first display area and/or the second display area;

and/or the presence of a gas in the gas,

the first display area and the second display area are both touch display areas.

Therefore, the interactive feedback information of the first display area and/or the second display area comprises the touch operation data of the user in the touch display area and/or the duration data monitored by the gaze monitoring component.

Adjusting the size of the first variable space and/or the second variable space based on the interactive feedback information of the first display area and/or the second display area.

More specifically, as an illustrative and non-limiting illustration, in the above-described embodiment of the present invention, the first exercise guidance information is stored in the first variable space, and the second exercise effect information is stored in the second variable space.

As an illustrative illustration, if a second frequency of the touch operation of the user on the second display area is sensed to be greater than a first frequency of the touch operation of the user on the first display area, the second variable space is increased; otherwise, the second variable space is reduced.

In the above-described embodiment, increasing the second variable space means that more exercise effect information can be displayed in the next stage.

As still another illustrative example, if a first duration of time that the user's gaze is focused on the first display region is longer than a second duration of time that the user's gaze is focused on the second display region, the auxiliary instruction increases the first variable space; otherwise, the first variable space is decreased.

Obviously, in the above-described embodiment, increasing the first variable space means that more exercise guidance information can be displayed in the next stage.

It should be noted that the instruction for adjusting the space may be generated based on the duration data alone, the instruction for adjusting the space may be generated based on the frequency data alone, or the two may be combined, that is, the instruction for adjusting the space may be generated based on the frequency data and the duration data, when the instruction is combined, the weight of the duration data and the weight of the frequency data of each display area may be specifically considered, an operation score is generated after the weighting processing is performed, and the instruction for adjusting the space is generated based on the operation score.

With continuing reference to fig. 3-4, fig. 3-4 show two different embodiments of the method for applying the personalized diagnosis system based on the mobile internet, respectively.

In fig. 3, the personalized diagnosis system on which the method is based includes an embedded interactive exercise device, the embedded interactive exercise device includes a touch display interface and a memory space with a set size, the touch display interface includes a first touch display area and a second touch display area, and the memory space includes a first memory space and a second memory space.

On the basis, the method comprises the following steps:

s800: setting the size of the first memory space to be equal to the size of the second memory space;

s801: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s802: displaying the first exercise guidance information through the first touch display area and displaying the second exercise effect information through the second touch display area;

s803: acquiring touch operation data of a user in the first touch display area and/or the first touch display area within a preset time period;

s804: and adjusting the size of the first memory space and/or the size of the second memory space based on the touch operation data.

In fig. 4, the personalized diagnostic system based on which the method is based includes an embedded interactive exercise device, where the embedded interactive exercise device includes a display area and a memory space with a set size, the display area includes a first display area and a second display area, the memory space includes a first memory space and a second memory space, and both the first display area and the second display area are configured with a gaze focus monitoring component;

on this basis, the method comprises the following steps:

s900: setting the size of the first memory space to be equal to the size of the second memory space;

s901: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s902: displaying the first exercise guidance information through the first touch display area and displaying the second exercise effect information through the second touch display area;

s903: acquiring focusing time length data of focusing the user's gaze on the first display area and/or the first display area within a predetermined time period;

s904: adjusting the size of the first memory space and/or the size of the second memory space based on the focus duration data.

It should be noted that in the method described in fig. 3 or fig. 4, multiple target controls may be implemented as autonomy.

Taking fig. 4 as an example, after step S902, it is further required to determine whether a preset time period is reached, and after step S904, it is further required to determine whether a current preset target is reached;

if the preset target is reached, returning to step 900; otherwise, return to step S901.

Similarly, the same is true for the embodiment of fig. 3, i.e. after step S802, it is further necessary to determine whether the preset time period is reached, and after step S804, it is further necessary to determine whether the current preset target is reached;

if the preset target is reached, returning to step 800; otherwise, return to step S801.

Aiming at the characteristic that the memory of the embedded equipment is limited, the memory space with the preset size is divided into a first variable space and a second variable space with adjustable sizes, the first variable space and the second variable space are respectively used for storing exercise guide information and exercise effect information, and a feedback instruction is generated based on different interest degrees of the exercise guide information and the exercise effect information in the interactive exercise process of a user, so that the sizes of the first variable space and the second variable space are adjusted, and the personalized diagnosis requirement of the user can be met to the greatest extent in the limited space.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A personalized diagnosis system based on mobile Internet comprises an embedded interactive exercise device, wherein the embedded interactive exercise device is provided with a human-computer interactive display interface;

the method is characterized in that:

the embedded interactive exercise equipment is provided with a memory space with a first set size;

the man-machine interaction display interface comprises a first display area and a second display area;

the first display area and the second display area are both touch display areas;

the memory space is composed of a first variable space and a second variable space;

the embedded interactive exercise equipment is provided with a wireless communication interface, is communicated with a mobile Internet platform through the wireless communication interface and receives personalized diagnosis information sent by the mobile Internet platform;

the personalized diagnosis information comprises first exercise guide information and second exercise effect information;

displaying the first exercise guidance information in the first display area and the second exercise effect information in the second display area;

adjusting the size of the first variable space and/or the second variable space based on the interactive feedback information of the first display area and the second display area, specifically including:

the interactive feedback information of the first display area and the second display area comprises touch operation data of a user in the touch display area;

if the second frequency of the touch operation of the sensing user on the second display area is greater than the first frequency of the touch operation of the sensing user on the first display area, increasing the second variable space; otherwise, the second variable space is reduced.

2. The mobile internet-based personalized diagnostic system of claim 1, wherein:

the first display area and the second display area both comprise a gaze monitoring component, and the gaze monitoring component is used for monitoring the duration of focusing the gaze of a user on the first display area and the second display area.

3. The mobile internet-based personalized diagnostic system of claim 2, wherein:

adjusting the size of the first variable space and/or the second variable space based on the interactive feedback information of the first display area and the second display area, further comprising:

interactive feedback information of the first display area and the second display area comprises duration data obtained by monitoring of a gaze monitoring component;

if the first time length that the user's gaze focuses on the first display region is longer than the second time length that the user's gaze focuses on the second display region, increasing the first variable space; otherwise, the first variable space is reduced.

4. The personalized diagnosis system based on mobile internet as claimed in claim 1, wherein:

the first exercise guidance information is used for indicating exercise postures and actions performed by a user;

the second exercise effect information is used to indicate a desired effect of the user after performing the first exercise guidance information.

5. The mobile internet-based personalized diagnostic system of claim 1, wherein:

displaying the first exercise guidance information in the first display area, including:

displaying an exercise screen corresponding to an exercise gesture and action performed by a user in the first display area;

displaying the second exercise effect information in the second display area, including:

and displaying an expected effect graph after the user executes the first exercise guide information in the second display area.

6. An application method of a personalized diagnosis system based on a mobile internet, the personalized diagnosis system comprising an embedded interactive exercise device, the embedded interactive exercise device comprising a touch display interface and a memory space with a set size, the touch display interface comprising a first touch display area and a second touch display area, the memory space comprising a first variable space and a second variable space, the method comprising:

s800: setting the size of the first variable space equal to the size of the second variable space;

s801: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s802: displaying the first exercise guidance information through the first touch display area and displaying the second exercise effect information through the second touch display area;

s803: acquiring touch operation data of a user in the first touch display area and the second touch display area within a preset time period;

s804: adjusting the size of the first variable space and/or the size of the second variable space based on the touch operation data;

wherein the step S804 specifically includes:

if the second frequency of the touch operation of the sensing user on the second touch display area is greater than the first frequency of the touch operation of the sensing user on the first touch display area, increasing the second variable space; otherwise, the second variable space is reduced.

7. An application method of a personalized diagnosis system based on a mobile internet comprises an embedded interactive exercise device, wherein the embedded interactive exercise device comprises a display area and a memory space with a set size, the display area comprises a first display area and a second display area, the memory space comprises a first variable space and a second variable space, and the first display area and the second display area are both provided with a gaze focus monitoring component;

characterized in that the method comprises:

s900: setting a size of the first variable space equal to a size of the second variable space;

s901: the embedded exercise equipment receives first exercise guide information and second exercise effect information through a mobile internet;

s902: displaying the first exercise guidance information through a first display area, and displaying the second exercise effect information through a second display area;

s903: acquiring focusing time length data of focusing of the user's gaze on the first display area and the second display area within a predetermined time period;

s904: adjusting a size of the first variable space and/or a size of the second variable space based on the focus duration data;

wherein, the step S904 specifically includes: if the first time length that the user's gaze focuses on the first display region is longer than the second time length that the user's gaze focuses on the second display region, increasing the first variable space; otherwise, the first variable space is reduced.

8. A non-volatile storage medium having computer-executable program code instructions stored thereon; execution of the program code instructions by a terminal device comprising a processor and a memory for implementing the method of any of claims 6 or 7.

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