CN106843474B - Mobile terminal display processing method and system - Google Patents

Abstract

The invention relates to the technical field of mobile terminals, and discloses a method and a system for processing display of a mobile terminal, wherein the method comprises the following steps: the mobile terminal receives the degree of myopia or hyperopia input by a user; a distance sensor in the mobile terminal detects the distance between a user and a screen of the mobile terminal and stores the degree and the distance; and the mobile terminal performs distortion processing on the content to be displayed by using an image distortion algorithm according to the degrees and the distance and then transmits the content to be displayed to a screen for display. According to the method, the degree of glasses of a user wearing glasses for myopia or hyperopia and the distance between the user wearing glasses and the screen of the mobile terminal are collected, the image distortion algorithm is called to perform distortion processing on the display content transmitted to the screen, and then a clear picture is formed on the retina of the user, so that the user can see the screen of the mobile terminal clearly by naked eyes, and the eyes of the user are protected better.

Description

Mobile terminal display processing method and system

Technical Field

The invention relates to the technical field of mobile terminals, in particular to a mobile terminal display processing method and a mobile terminal display processing system.

Background

Along with the popularization of intelligent terminal equipment, the intelligent terminal becomes an indispensable part in the life of people, and people need to interact with the intelligent terminal for a long time.

At present, myopia and hyperopia groups are increasingly huge, and most people need to wear glasses to assist in solving visual disorders. However, when the glasses are worn for a long time, fatigue is easily generated, and adverse effects such as resistance reduction of the eyes are caused.

The main reason for the blurred vision of the far-sighted and near-sighted eyes is that the dioptric system of the eyes is diseased, so that the focusing focus of light rays is not on the retina, the focusing focus of the near-sighted eye is in front of the retina, and the focusing focus of the far-sighted eye is behind the retina. Therefore, by wearing glasses of different diopters, correction compensation is performed so that the focal point of the light falls on the retina again.

The wearing of the glasses frame glasses has the traumatic risk that the glasses structures such as metal, glass, resin and the like can bring to eyes, and some myopes like wearing contact lenses, so that the contact lenses have larger dangers: various eye diseases such as corneal inflammation, conjunctival congestion, corneal perception hypoesthesia and the like are easily caused, and if the eye diseases are high myopia, various complications are easily caused, so that serious eye diseases are caused.

Accordingly, the prior art is yet to be improved and developed.

Disclosure of Invention

The present invention aims to provide a method and a system for processing display of a mobile terminal, aiming at acquiring the degree of glasses of a user wearing glasses for near-sighted or far-sighted and the distance from the screen of the mobile terminal, and calling an image distortion algorithm to perform distortion processing on display content transmitted to the screen, so as to form a clear picture on the retina of the user, so that the user can see the screen of the mobile terminal clearly with naked eyes, thereby better protecting the eyes of the user.

The technical scheme adopted by the invention for solving the technical problem is as follows:

a display processing method of a mobile terminal, wherein the method comprises the following steps:

step A, the mobile terminal receives the degree of myopia or hyperopia input by a user;

b, a distance sensor in the mobile terminal detects the distance between a user and a screen of the mobile terminal, and the degree and the distance are stored;

and C, the mobile terminal utilizes an image distortion algorithm to carry out distortion processing on the content to be displayed according to the degrees and the distance and then transmits the content to the screen for display.

The mobile terminal display processing method, wherein the step a specifically includes:

a1, when the user uses the mobile terminal, opening an application for processing images for myopia and hyperopia, and popping up a prompt box for prompting the user to input the degrees of myopia or hyperopia;

a2, when receiving the specific value of the near-sight or far-sight power input by the user, storing the value of the power in the application.

The mobile terminal display processing method, wherein the step B specifically includes:

b1, when the mobile terminal starts the distance sensor in the process of receiving the user input of the near-sighted or far-sighted degree;

b2, after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal, the value of the horizontal distance is stored in the application.

The mobile terminal display processing method, wherein the step C specifically includes:

c1, according to the degrees and the distance saved in the application, the mobile terminal calls an image distortion algorithm through a GPU or a CPU to perform distortion processing on the display content to be sent to the screen;

c2, when the image distortion algorithm completes the distortion processing according to the degree and the distance, the processed image is sent to the screen.

The mobile terminal display processing method comprises the steps that after the mobile terminal stores the degree of myopia or hyperopia input by the user for the first time, when the image distortion algorithm is started again to carry out distortion processing on display content, the user directly calls the degree of myopia or hyperopia stored in the mobile terminal, or when the user needs to change the degree of myopia or hyperopia, an instruction for re-inputting the degree is sent to complete input.

A mobile terminal display processing system, wherein the system comprises:

the vision input module is used for receiving the degree of myopia or hyperopia input by a user through the mobile terminal;

the distance detection module is used for detecting the distance between a user and a screen of the mobile terminal by a distance sensor in the mobile terminal and storing the degree and the distance;

and the algorithm processing module is used for carrying out distortion processing on the content to be displayed by the mobile terminal by utilizing an image distortion algorithm according to the degrees and the distance and then transmitting the content to be displayed to a screen for display.

The mobile terminal display processing system, wherein, the eyesight input module specifically includes:

the opening prompting unit is used for opening an application for performing image processing on myopia and hyperopia when a user uses the mobile terminal, and popping up a prompt box for prompting the user to input myopia or hyperopia degrees;

and the input storage unit is used for storing the numerical value of the near-sightedness or far-sightedness in the application after receiving the specific numerical value of the degree input by the user.

The mobile terminal display processing system, wherein the distance detection module specifically includes:

the mobile terminal comprises a sensor opening unit, a distance sensor and a control unit, wherein the sensor opening unit is used for opening the distance sensor when receiving the process that the user inputs the myopia or hypermetropia degrees;

and the detection and storage unit is used for storing the numerical value of the horizontal distance in the application after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal.

The mobile terminal display processing system, wherein the algorithm processing module specifically comprises:

the distortion processing unit is used for calling an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to a screen according to the degrees and the distance stored in the application;

and the picture display unit is used for sending the processed image to a screen after the image distortion algorithm finishes distortion processing according to the degree and the distance.

The mobile terminal display processing system comprises a mobile terminal and an image distortion algorithm, wherein after the mobile terminal stores the degree of myopia or hyperopia input by the user for the first time, when the image distortion algorithm is started again to perform distortion processing on the display content, the user directly calls the degree of myopia or hyperopia stored in the mobile terminal, or sends an instruction of re-inputting the degree to complete input when the user needs to change the degree of myopia or hyperopia.

The invention discloses a mobile terminal display processing method and a system, wherein the method comprises the following steps: the mobile terminal receives the degree of myopia or hyperopia input by a user; a distance sensor in the mobile terminal detects the distance between a user and a screen of the mobile terminal and stores the degree and the distance; and the mobile terminal performs distortion processing on the content to be displayed by using an image distortion algorithm according to the degrees and the distance and then transmits the content to be displayed to a screen for display. According to the method, the degree of glasses of a user wearing glasses for myopia or hyperopia and the distance between the user wearing glasses and the screen of the mobile terminal are collected, the image distortion algorithm is called to perform distortion processing on the display content transmitted to the screen, and then a clear picture is formed on the retina of the user, so that the user can see the screen of the mobile terminal clearly by naked eyes, and the eyes of the user are protected better.

Drawings

FIG. 1 is a flowchart illustrating a mobile terminal display processing method according to a preferred embodiment of the present invention.

Fig. 2 is a pathological diagram of myopia and hypermetropia.

Fig. 3 is a schematic diagram of the principle of correcting vision by wearing glasses.

Fig. 4 is a schematic diagram illustrating the principle of an image distortion algorithm in the display processing method of the mobile terminal according to the present invention.

Fig. 5 is a schematic diagram of distortion conversion of an image by using an image distortion algorithm in the display processing method of the mobile terminal of the present invention.

FIG. 6 is a functional block diagram of a preferred embodiment of a mobile terminal display processing system of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1, fig. 1 is a flowchart illustrating a display processing method of a mobile terminal according to a preferred embodiment of the present invention.

As shown in fig. 1, a method for processing a display of a mobile terminal according to an embodiment of the present invention includes the following steps:

s100, the mobile terminal receives the degree of myopia or hyperopia input by a user.

Further, the step S100 specifically includes:

s110, when the user uses the mobile terminal, opening an application for image processing aiming at myopia and hyperopia, and popping up a prompt box for prompting the user to input myopia or hyperopia degrees;

and S120, when the specific value of the myopia or hyperopia degree input by the user is received, storing the value of the degree in the application.

In the invention, the application (software) for processing the image aiming at the myopia and the hyperopia is pre-installed in the mobile terminal, the application was developed specifically for visual compensation of users with near-sighted or far-sighted glasses, when a user needs to use the mobile terminal to perform related operations, such as reading news, opening a web page, instant chat, and the like, and clicks to open the application for the first time, a prompt box pops up on the interface of the application, the prompt box is used for prompting the user to input the near-sight or far-sight degrees, and the user can know the degree of the glasses of the user if wearing the glasses, or the user only has slight myopia or hyperopia and does not have glasses, but knows that the glasses power is at an approximate value, the user inputs a specific numerical value according to the own power, and accordingly the input and the storage of the myopia or hyperopia power are completed.

And S200, detecting the distance between the user and the screen of the mobile terminal by a distance sensor in the mobile terminal, and storing the degree and the distance.

Further, the step S200 further includes:

s210, when receiving the process that the user inputs the myopia or hyperopia degrees, the mobile terminal starts a distance sensor;

and S220, after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal, storing the numerical value of the horizontal distance in the application.

In the invention, when a user inputs myopia or hypermetropia degrees, the mobile terminal simultaneously performs a detection action, namely the mobile terminal starts a distance sensor for example detection, the distance to be detected is the horizontal distance between the eyes of the user and the screen of the mobile terminal, even if the screen of the mobile terminal is not directly opposite to the eyes of the user, only the distance from the central range of the mobile terminal to the eyes of the user needs to be detected, and after the distance detection is finished, the value of the horizontal distance is stored in the application. The invention can also realize distance detection by other distance detection methods, such as an infrared distance detection mode and the like.

And S300, the mobile terminal utilizes an image distortion algorithm to carry out distortion processing on the content to be displayed according to the degrees and the distance and then transmits the content to the screen for display.

Further, the step S300 specifically includes:

s310, according to the degrees and the distance saved in the application, the mobile terminal calls an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to a screen;

and S320, after the image distortion algorithm completes distortion processing according to the degree and the distance, sending the processed image to a screen.

In the invention, after the application acquires the degree of myopia or hyperopia of the user and the distance between the user and the screen of the mobile terminal, the vision compensation is carried out on the user, the display content to be sent to the screen is distorted by calling an image distortion algorithm through a GPU (graphic Processing Unit) or a CPU (Central Processing Unit), and the processed image is sent to the screen after the image distortion algorithm finishes the distortion Processing according to the degree and the distance, so that the user wearing glasses with myopia or hyperopia can clearly see the content displayed on the screen by naked eyes, thereby protecting the eyes and eyesight of the user.

In addition, after the mobile terminal stores the degree of myopia or hyperopia after the user inputs for the first time, when the image distortion algorithm is started again to carry out distortion processing on the display content, the interface of the application pops up a prompt for prompting the user whether to use the previously stored degree or to input the option again, and the user can directly call the degree of myopia or hyperopia stored in the mobile terminal or send a command of re-inputting the degree to complete the input when the user needs to change the degree of myopia or hyperopia.

The following describes the process and principle of the present invention for transmitting the content to be displayed to the screen after performing distortion processing on the content by using a distortion algorithm.

As shown in fig. 2 and 3, the reason for the generation of the myopia and the hyperopia can be seen from fig. 2, and normally, the light reflected by the object is refracted by the dioptric system of the eye and then imaged on the retina; the myopia is characterized in that after passing through the dioptric system, an object is imaged in front of a retina; presbyopia and presbyopia are imaged behind the retina. But the final result can cause the patient to see the object in a fuzzy way, and the auxiliary correction of the glasses is needed to obtain the normal vision.

Fig. 3 shows the principle of correcting vision by wearing glasses, which is to make the object image position fall on the retina again before the light enters the dioptric system of human eyes, so that the user can see the image clearly.

As shown in fig. 4, after the content to be displayed is distorted by the image distortion algorithm, the normal image can be seen through the principle of myopia correction, so that a patient with myopia or hyperopia can see the image clearly after passing through the lens. Taking myopia correction as an example, according to the characteristics of the light path, the image can be normally imaged on the retina by moving the position of the lens to the position of the screen of the intelligent terminal device, but the diopter of the lens needs to be correspondingly changed according to the distance between the screen and the eyes, so that the image is subjected to distortion processing of a lens algorithm, and the same effect can be realized.

As shown in fig. 5, under normal conditions, assuming that the screen image display effect B is in the square area of fig. 5, radial distortion, as shown at A, C, is produced by refraction of the lens, which is the pincushion and barrel distortion produced by the concave and convex lenses, respectively. For myopic and hyperopic patients, B- > A, B- > C distortion transformation can be carried out on the image.

According to the characteristics of the lens, the center of the lens can be connected without distortion, and the farther away from the center, the more serious the distortion is, and the image can be circularly expanded and distorted outwards.

The mathematical model of the distortion is described by the first terms of the taylor series expansion around the center point, the first two terms being usually chosen according to the free choice of the distortion effect. Assume that the pixel original position is (x, y), and the target position after the distortion processing is (x ', y'). The distortion formula is as follows:

x’ = x(1+k1*r^2 +k2*r^4 + …);

y’ = y(1+k1*r^2 +k2*r^4 + … );

wherein r is the position of the original position of the pixel point from the central point. The key to the distortion algorithm is how to determine the parameters k1 and k 2. They need to be determined according to the diopter requirements of the near and far sighted persons and the distance of the user from the screen.

The invention needs the user to input the degree of myopia/hyperopia before using, and detects the distance between the user and the screen through the front camera, dynamically calculates k1 and k2, and recalculates the display position of each pixel before the display data is sent to the screen to be displayed according to the calculation result, thereby realizing the processing of the distortion of the image.

Based on the above method embodiment, the present invention further provides a mobile terminal display processing system, as shown in fig. 6, the system includes:

the vision input module 210 is used for the mobile terminal to receive the degree of myopia or hyperopia input by the user; as described above.

The distance detection module 220 is used for detecting the distance between the user and the screen of the mobile terminal by a distance sensor in the mobile terminal and storing the degree and the distance; as described above.

The algorithm processing module 230 is used for the mobile terminal to perform distortion processing on the content to be displayed by using an image distortion algorithm according to the degrees and the distance and then transmit the content to the screen for display; as described above.

Further, the mobile terminal display processing system, wherein the eyesight input module specifically includes:

the opening prompting unit is used for opening an application for performing image processing on myopia and hyperopia when a user uses the mobile terminal, and popping up a prompt box for prompting the user to input myopia or hyperopia degrees; as described above.

The input storage unit is used for storing the numerical value of the near-sighted or far-sighted power in the application after receiving the specific numerical value of the near-sighted or far-sighted power input by the user; as described above.

Further, the mobile terminal display processing system, wherein the distance detection module specifically includes:

the mobile terminal comprises a sensor opening unit, a distance sensor and a control unit, wherein the sensor opening unit is used for opening the distance sensor when receiving the process that the user inputs the myopia or hypermetropia degrees; as described above.

The detection storage unit is used for storing the numerical value of the horizontal distance in the application after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal; as described above.

Further, the mobile terminal display processing system, wherein the algorithm processing module specifically includes:

the distortion processing unit is used for calling an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to a screen according to the degrees and the distance stored in the application; as described above.

The image display unit is used for sending the processed image to a screen after the image distortion algorithm finishes distortion processing according to the degree and the distance; as described above.

Further, the mobile terminal display processing system, wherein after the mobile terminal stores the degree of myopia or hyperopia input by the user for the first time, when the image distortion algorithm is started again to perform distortion processing on the display content, the user selects to directly call the degree of myopia or hyperopia stored in the mobile terminal, or when the user needs to change the degree of myopia or hyperopia, the user sends an instruction to re-input the degree to complete the input; as described above.

In summary, the present invention discloses a method and a system for processing display of a mobile terminal, wherein the method comprises: the mobile terminal receives the degree of myopia or hyperopia input by a user; a distance sensor in the mobile terminal detects the distance between a user and a screen of the mobile terminal and stores the degree and the distance; and the mobile terminal performs distortion processing on the content to be displayed by using an image distortion algorithm according to the degrees and the distance and then transmits the content to be displayed to a screen for display. According to the method, the degree of glasses of a user wearing glasses for myopia or hyperopia and the distance between the user wearing glasses and the screen of the mobile terminal are collected, the image distortion algorithm is called to perform distortion processing on the display content transmitted to the screen, and then a clear picture is formed on the retina of the user, so that the user can see the screen of the mobile terminal clearly by naked eyes, and the eyes of the user are protected better.

Of course, it will be understood by those skilled in the art that all or part of the processes of the methods of the above embodiments may be implemented by a computer program instructing relevant hardware (such as a processor, a controller, etc.), and the program may be stored in a computer readable storage medium, and when executed, the program may include the processes of the above method embodiments. The storage medium may be a memory, a magnetic disk, an optical disk, etc.

It is to be understood that the invention is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the invention as defined by the appended claims.

Claims (6)

1. A mobile terminal display processing method is characterized by comprising the following steps:

step A, the mobile terminal receives the degree of myopia or hyperopia input by a user;

b, a distance sensor in the mobile terminal detects the distance between a user and a screen of the mobile terminal, and the degree and the distance are stored;

c, the mobile terminal utilizes an image distortion algorithm to carry out distortion processing on the content to be displayed according to the degrees and the distance and then transmits the content to the screen for display;

after the mobile terminal stores the degree of myopia or hyperopia input by the user for the first time, when the image distortion algorithm is started again to carry out distortion processing on the display content, the user directly calls the degree of myopia or hyperopia stored in the mobile terminal, or sends a command of re-inputting the degree to complete input when the user needs to change the degree of myopia or hyperopia;

when the application acquires the degrees of myopia or hyperopia of a user and the distance between the user and a screen of the mobile terminal, performing visual compensation on the user, calling an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to the screen, and after the image distortion algorithm completes the distortion processing according to the degrees and the distance, sending the processed image to the screen, so that the user wearing glasses with myopia or hyperopia can clearly see contents displayed on the screen by naked eyes, and the eyes and the eyesight of the user are protected;

the step C specifically comprises the following steps:

c1, according to the degrees and the distance saved in the application, the mobile terminal calls an image distortion algorithm through a GPU or a CPU to perform distortion processing on the display content to be sent to the screen;

c2, when the image distortion algorithm completes the distortion processing according to the degree and the distance, the processed image is sent to the screen;

the target position of the pixel point in the distortion processing image is determined by the diopter requirements of the myopia and hypermetropia and the distance from the user to the screen.

2. The display processing method of the mobile terminal according to claim 1, wherein the step a specifically comprises:

a1, when the user uses the mobile terminal, opening an application for processing images for myopia and hyperopia, and popping up a prompt box for prompting the user to input the degrees of myopia or hyperopia;

a2, when receiving the specific value of the near-sight or far-sight power input by the user, storing the value of the power in the application.

3. The display processing method of the mobile terminal according to claim 2, wherein the step B specifically includes:

b1, when the mobile terminal starts the distance sensor in the process of receiving the user input of the near-sighted or far-sighted degree;

b2, after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal, the value of the horizontal distance is stored in the application.

4. A mobile terminal display processing system, the system comprising:

the vision input module is used for receiving the degree of myopia or hyperopia input by a user through the mobile terminal;

the distance detection module is used for detecting the distance between a user and a screen of the mobile terminal by a distance sensor in the mobile terminal and storing the degree and the distance;

the algorithm processing module is used for the mobile terminal to carry out distortion processing on the content to be displayed by utilizing an image distortion algorithm according to the degrees and the distance and then transmitting the content to be displayed to a screen for display;

after the mobile terminal stores the degree of myopia or hyperopia input by the user for the first time, when the image distortion algorithm is started again to carry out distortion processing on the display content, the user directly calls the degree of myopia or hyperopia stored in the mobile terminal, or sends a command of re-inputting the degree to complete input when the user needs to change the degree of myopia or hyperopia;

when the application acquires the degrees of myopia or hyperopia of a user and the distance between the user and a screen of the mobile terminal, performing visual compensation on the user, calling an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to the screen, and after the image distortion algorithm completes the distortion processing according to the degrees and the distance, sending the processed image to the screen, so that the user wearing glasses with myopia or hyperopia can clearly see contents displayed on the screen by naked eyes, and the eyes and the eyesight of the user are protected;

the algorithm processing module specifically comprises:

the distortion processing unit is used for calling an image distortion algorithm through a GPU or a CPU to perform distortion processing on display contents to be sent to a screen according to the degrees and the distance stored in the application;

the image display unit is used for sending the processed image to a screen after the image distortion algorithm finishes distortion processing according to the degree and the distance;

the target position of the pixel point in the distortion processing image is determined by the diopter requirements of the myopia and hypermetropia and the distance from the user to the screen.

5. The mobile terminal display processing system of claim 4, wherein the vision input module specifically comprises:

the opening prompting unit is used for opening an application for performing image processing on myopia and hyperopia when a user uses the mobile terminal, and popping up a prompt box for prompting the user to input myopia or hyperopia degrees;

and the input storage unit is used for storing the numerical value of the near-sightedness or far-sightedness in the application after receiving the specific numerical value of the degree input by the user.

6. The mobile terminal display processing system according to claim 5, wherein the distance detection module specifically comprises:

the mobile terminal comprises a sensor opening unit, a distance sensor and a control unit, wherein the sensor opening unit is used for opening the distance sensor when receiving the process that the user inputs the myopia or hypermetropia degrees;

and the detection and storage unit is used for storing the numerical value of the horizontal distance in the application after the distance sensor detects the horizontal distance between the eyes of the user and the screen of the mobile terminal.

Images