CN111600975A - Mobile phone touch screen sensitivity dynamic adjustment platform - Google Patents

Abstract

The invention relates to a touch screen sensitivity dynamic adjustment platform, which comprises: the system comprises a customized structure screen, a first touch sub-screen and a second touch sub-screen, wherein the customized structure screen is used for a smart phone using an ANDROID operating system and is composed of the first touch sub-screen and the second touch sub-screen, and the first touch sub-screen is positioned above the second touch sub-screen; the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen; the second touch sub-screen is used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of each currently running application program; and the field reinforcement mechanism comprises a first member and a second member which form an L-shaped structure and is used for realizing hardware reinforcement of the second touch sub-screen. The touch screen sensitivity dynamic adjustment platform is reliable in logic and has certain pertinence. The using requirements of ANDROID smart phone users can be met.

Description

Mobile phone touch screen sensitivity dynamic adjustment platform

Technical Field

The invention relates to the field of smart phones, in particular to a mobile phone touch screen sensitivity dynamic adjusting platform.

Background

The capacitive touch screen is a common touch screen design mode of a smart phone. After receiving the touch signal, the capacitive touch screen converts the touch data into electric pulses and transmits the electric pulses to the touch screen control IC for processing. The signal is amplified by a low noise amplifier LNA, then is subjected to analog-to-digital conversion and demodulation, and finally is sent to a DSP control chip for data processing.

A capacitive touch screen typically has M x N (M columns and N rows) physical capacitive touch sensors. The M + N sensors form M × N capacitive sensing points, and when a finger of a user approaches the touch screen, the capacitance of the touch screen changes accordingly. The spacing of the sensors, i.e., the distance between adjacent rows or columns, is typically on the order of a few millimeters, and this spacing determines the physical resolution of the touch screen, mxn.

The coordinate system between the capacitive touch screen module and the LCD module is completely different. The pixel coordinates of an LCD module are generally determined by its resolution, e.g., a screen of WVGA, which has a resolution of 800 × 480, i.e., 800 lines of 480 RGB pixels each. Thus, a particular position may be determined by the pixel point (X, Y) in the X and Y directions. The capacitive touch screen module determines a coordinate system according to its original physical dimensions in the X and Y directions. A reasonable mapping method must exist between the two coordinate systems to ensure the correctness of the input and output operations.

Currently, for a smartphone using the ANDROID operating system, it is usually necessary to frequently accept an operation of sliding a user upwards to trigger side-by-side display of each currently running application program, which brings a great challenge to the sensitivity and stability of the smartphone in the bottom area of the touch screen.

Disclosure of Invention

In order to solve the related technical problems in the prior art, the invention provides a touch screen sensitivity dynamic adjustment platform which can meet the requirements of sensitivity and stability of a bottom touch screen caused by the operation that a user of an ANDROID smartphone slides upwards to trigger the side-by-side display of each application program in current operation.

Therefore, the invention at least needs to have the following three key points:

(1) the method comprises the steps that based on the fact that the operation that a user of the ANDROID smart phone slides upwards to trigger each application program in current operation to be displayed side by side is frequent, the touch screen of the smart phone is customized, and therefore the sensitivity of the touch screen at the bottom of the display screen of the smart phone is improved;

(2) the method comprises the following steps of performing targeted reinforcement on a touch screen at the bottom of a display screen of the smart phone to resist sliding force caused by frequent upward sliding operation of a user and avoid looseness of the touch screen;

(3) based on the change of the current operating system of the smart phone, the sensitivity of a touch screen at the bottom of a display screen of the smart phone is dynamically adjusted, so that unnecessary waste of power resources is reduced.

According to an aspect of the present invention, there is provided a touch screen sensitivity dynamic adjustment platform, the platform comprising:

the customized structure screen is used for a smart phone using an ANDROID operating system and comprises a first touch sub-screen and a second touch sub-screen, wherein the first touch sub-screen is positioned above the second touch sub-screen, and the two sub-screens are closely spliced to obtain the customized structure screen;

the size of the first touch sub-screen is a multiple of an integer of the second touch sub-screen, and the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen;

the second touch sub-screen is used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of each currently running application program;

the first touch sub-screen is not used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of all application programs currently running;

the first touch sub-screen is composed of M multiplied by N physical capacitive touch sensors, namely M columns of N rows of physical capacitive touch sensors, and the second touch sub-screen is composed of P multiplied by Q physical capacitive touch sensors, namely P columns of Q rows of physical capacitive touch sensors;

the field reinforcement mechanism comprises a first member and a second member, the first member is arranged behind the second touch sub-screen, the second member is arranged above a shell at the bottom of the smart phone, and the first member and the second member form an L-shaped structure to realize hardware reinforcement of the second touch sub-screen;

the system identification device is used for detecting an operating system currently used by the smart phone and sending out other system instructions when the ANDROID operating system is not currently used by the smart phone;

the electronic control switch is respectively connected with the second touch sub-screen and the system identification equipment and is used for executing partial sensor closing actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving other system instructions;

the system identification equipment is further used for sending out a system matching instruction when the smartphone currently uses an ANDROID operating system;

wherein P is a multiple of M, and N is equal to Q, so that the touch sensitivity of the second touch sub-screen is greater than the touch sensitivity of the first touch sub-screen.

The touch screen sensitivity dynamic adjustment platform is reliable in logic and has certain pertinence. The using requirements of ANDROID smart phone users can be met.

Drawings

Embodiments of the invention will now be described with reference to the accompanying drawings, in which:

fig. 1 is a diagram illustrating an outline of a customized structure screen used in a dynamic touch screen sensitivity adjustment platform according to the present invention.

Fig. 2 is a block diagram illustrating a structure of a touch screen sensitivity dynamic adjustment platform according to a first embodiment of the present invention.

Fig. 3 is a block diagram illustrating a structure of a touch screen sensitivity dynamic adjustment platform according to a second embodiment of the present invention.

Detailed Description

Embodiments of a touch screen sensitivity dynamic adjustment platform of the present invention will be described in detail below with reference to the accompanying drawings.

Currently, for a user using an ANDROID smartphone, the operation of sliding upwards at the bottom of a touch screen to trigger the side-by-side display of each currently running application program is frequent, the touch sensitivity requirement on the bottom of the touch screen is higher than that in other areas of the touch screen, and meanwhile, the occurrence of frequent operation brings new challenges to the stability of the bottom of the touch screen.

In order to overcome the defects, the invention builds a dynamic touch screen sensitivity adjusting platform and can effectively solve the corresponding technical problem.

Fig. 1 is a diagram illustrating an outline of a customized structure screen used in a dynamic touch screen sensitivity adjustment platform according to the present invention.

As shown in fig. 1, in the customized structure screen, including the first touch sub-screen at the upper position and the second touch sub-screen at the lower position, it is obvious that the area of the first touch sub-screen is larger than that of the second touch sub-screen, and meanwhile, in both the first touch sub-screen and the second touch sub-screen, x is used to describe the length of the screen, and y is used to describe the width of the screen.

The present invention will be described in detail and with reference to a number of different embodiments.

Fig. 2 is a block diagram illustrating a structure of a touch screen sensitivity dynamic adjustment platform according to a first embodiment of the present invention, the platform including:

the customized structure screen is used for a smart phone using an ANDROID operating system and comprises a first touch sub-screen and a second touch sub-screen, wherein the first touch sub-screen is positioned above the second touch sub-screen, and the two sub-screens are closely spliced to obtain the customized structure screen;

the size of the first touch sub-screen is a multiple of an integer of the second touch sub-screen, and the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen;

the second touch sub-screen is used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of each currently running application program;

the first touch sub-screen is not used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of all application programs currently running;

the first touch sub-screen is composed of M multiplied by N physical capacitive touch sensors, namely M columns of N rows of physical capacitive touch sensors, and the second touch sub-screen is composed of P multiplied by Q physical capacitive touch sensors, namely P columns of Q rows of physical capacitive touch sensors;

the field reinforcement mechanism comprises a first member and a second member, the first member is arranged behind the second touch sub-screen, the second member is arranged above a shell at the bottom of the smart phone, and the first member and the second member form an L-shaped structure to realize hardware reinforcement of the second touch sub-screen;

the system identification device is used for detecting an operating system currently used by the smart phone and sending out other system instructions when the ANDROID operating system is not currently used by the smart phone;

the electronic control switch is respectively connected with the second touch sub-screen and the system identification equipment and is used for executing partial sensor closing actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving other system instructions;

the system identification equipment is further used for sending out a system matching instruction when the smartphone currently uses an ANDROID operating system;

wherein P is a multiple of M, and N is equal to Q, so that the touch sensitivity of the second touch sub-screen is greater than the touch sensitivity of the first touch sub-screen.

Fig. 3 is a block diagram illustrating a structure of a touch screen sensitivity dynamic adjustment platform according to a second embodiment of the present invention, the platform including:

the state indicating equipment is connected with the electronic control switch and used for displaying the current sensitivity of the second touch sub-screen in real time based on the control action of the electronic control switch on the second touch sub-screen;

the state indicating equipment is a red-green indicating lamp arranged on the shell of the smart phone or a display driving mechanism of the smart phone;

the customized structure screen is used for a smart phone using an ANDROID operating system and comprises a first touch sub-screen and a second touch sub-screen, wherein the first touch sub-screen is positioned above the second touch sub-screen, and the two sub-screens are closely spliced to obtain the customized structure screen;

the size of the first touch sub-screen is a multiple of an integer of the second touch sub-screen, and the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen;

the second touch sub-screen is used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of each currently running application program;

the first touch sub-screen is not used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of all application programs currently running;

the first touch sub-screen is composed of M multiplied by N physical capacitive touch sensors, namely M columns of N rows of physical capacitive touch sensors, and the second touch sub-screen is composed of P multiplied by Q physical capacitive touch sensors, namely P columns of Q rows of physical capacitive touch sensors;

the field reinforcement mechanism comprises a first member and a second member, the first member is arranged behind the second touch sub-screen, the second member is arranged above a shell at the bottom of the smart phone, and the first member and the second member form an L-shaped structure to realize hardware reinforcement of the second touch sub-screen;

the system identification device is used for detecting an operating system currently used by the smart phone and sending out other system instructions when the ANDROID operating system is not currently used by the smart phone;

the electronic control switch is respectively connected with the second touch sub-screen and the system identification equipment and is used for executing partial sensor closing actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving other system instructions;

the system identification equipment is further used for sending out a system matching instruction when the smartphone currently uses an ANDROID operating system;

wherein P is a multiple of M, N is equal to Q, so that the touch sensitivity of the second touch sub-screen is greater than the touch sensitivity of the first touch sub-screen;

when the state indicating equipment is a display driving mechanism of the smart phone, displaying the current sensitivity of the second touch sub-screen on a display interface of a first touch sub-screen of the smart phone in real time based on the control action of the electronic control switch on the second touch sub-screen;

when the state indicating equipment is a display driving mechanism of the smart phone, the state indicating equipment is also used for displaying the current sensitivity of the first touch sub-screen on a display interface of the first touch sub-screen of the smart phone in real time.

Next, a detailed description will be given of a specific structure of the touch screen sensitivity dynamic adjustment platform according to each of the above embodiments of the present invention.

In the touch screen sensitivity dynamic adjustment platform: and the electronic control switch is also used for executing partial sensor opening actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving a system matching instruction.

In the touch screen sensitivity dynamic adjustment platform: performing a partial sensor turn-off action on P columns and Q rows of physical capacitive touch sensors constituting the second touch sub-screen includes: turning off a part of sensors constituting the second touch sub-screen so that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen.

In the touch screen sensitivity dynamic adjustment platform: performing a partial sensor turn-on action on P columns and Q rows of physical capacitive touch sensors constituting the second touch sub-screen includes: and opening all physical capacitive touch sensors constituting the second touch sub-screen so that the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen.

In the touch screen sensitivity dynamic adjustment platform: turning off a part of sensors constituting the second touch sub-screen such that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen includes: and turning off part of the sensors forming the second touch sub-screen in a mode of turning off the sensors in an interlaced mode.

In the touch screen sensitivity dynamic adjustment platform: turning off a part of sensors constituting the second touch sub-screen such that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen includes: and turning off part of the sensors constituting the second touch sub-screen in a mode of turning off the sensors in alternate columns.

Further, ANDROID (ANDROID) is a Linux-based operating system of free and open source code. The mobile phone is mainly used for mobile devices such as smart phones and tablet computers, and is led and developed by Google corporation and the open cell phone alliance. The ANDROID operating system was originally developed by AndyRubin, primarily to support cell phones. Funding was acquired by Google in month 8 of 2005. In 11 th 2007, Google developed an improved ANDROID system together with 84 hardware manufacturers, software developers, and telecommunications carriers, which established an open cell phone alliance. Google then issues the source code for the ANDROID in a manner authorized by Apache to open the source license. The first ANDROID smartphone was released in 10 months 2008. ANDROID is gradually expanding to tablet computers and other fields, such as televisions, digital cameras, game machines, smart watches, and the like. In the first quarter of 2011, ANDROID has its market share globally surpassed the Seiban system for the first time, jumping on the first world. In the fourth quarter of 2019, the global market share of ANDROID platform handsets has reached 78.1%.

Those of ordinary skill in the art will understand that: all or part of the steps for implementing the method embodiments may be implemented by hardware related to program instructions, and the program may be stored in a computer readable storage medium, and when executed, the program performs the steps including the method embodiments; and the aforementioned storage medium includes: Read-Only Memory (ROM), Random Access Memory (RAM), magnetic or optical disk, and other various media capable of storing program codes.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (9)

1. A touch screen sensitivity dynamic adjustment platform, the platform comprising:

the customized structure screen is used for a smart phone using an ANDROID operating system and comprises a first touch sub-screen and a second touch sub-screen, wherein the first touch sub-screen is positioned above the second touch sub-screen, and the two sub-screens are closely spliced to obtain the customized structure screen;

the size of the first touch sub-screen is a multiple of an integer of the second touch sub-screen, and the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen;

the second touch sub-screen is used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of each currently running application program;

the first touch sub-screen is not used for receiving the operation that a user of the smart phone slides upwards to trigger the side-by-side display of all application programs currently running;

the first touch sub-screen is composed of M multiplied by N physical capacitive touch sensors, namely M columns of N rows of physical capacitive touch sensors, and the second touch sub-screen is composed of P multiplied by Q physical capacitive touch sensors, namely P columns of Q rows of physical capacitive touch sensors;

the field reinforcement mechanism comprises a first member and a second member, the first member is arranged behind the second touch sub-screen, the second member is arranged above a shell at the bottom of the smart phone, and the first member and the second member form an L-shaped structure to realize hardware reinforcement of the second touch sub-screen;

the system identification device is used for detecting an operating system currently used by the smart phone and sending out other system instructions when the ANDROID operating system is not currently used by the smart phone;

the electronic control switch is respectively connected with the second touch sub-screen and the system identification equipment and is used for executing partial sensor closing actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving other system instructions;

the system identification equipment is further used for sending out a system matching instruction when the smartphone currently uses an ANDROID operating system;

wherein P is a multiple of M, and N is equal to Q, so that the touch sensitivity of the second touch sub-screen is greater than the touch sensitivity of the first touch sub-screen.

2. The touch screen sensitivity dynamic adjustment platform of claim 1, wherein:

and the electronic control switch is also used for executing partial sensor opening actions on the P columns and Q rows of physical capacitance touch sensors forming the second touch sub-screen when receiving a system matching instruction.

3. The touch screen sensitivity dynamic adjustment platform of claim 2, wherein:

performing a partial sensor turn-off action on P columns and Q rows of physical capacitive touch sensors constituting the second touch sub-screen includes: turning off a part of sensors constituting the second touch sub-screen so that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen.

4. The touch screen sensitivity dynamic adjustment platform of claim 3, wherein:

performing a partial sensor turn-on action on P columns and Q rows of physical capacitive touch sensors constituting the second touch sub-screen includes: and opening all physical capacitive touch sensors constituting the second touch sub-screen so that the touch sensitivity of the second touch sub-screen is greater than that of the first touch sub-screen.

5. The touch screen sensitivity dynamic adjustment platform of claim 4, wherein:

turning off a part of sensors constituting the second touch sub-screen such that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen includes: and turning off part of the sensors forming the second touch sub-screen in a mode of turning off the sensors in an interlaced mode.

6. The touch screen sensitivity dynamic adjustment platform of claim 5, wherein:

turning off a part of sensors constituting the second touch sub-screen such that the touch sensitivity of the second touch sub-screen is equal to or close to the touch sensitivity of the first touch sub-screen includes: and turning off part of the sensors constituting the second touch sub-screen in a mode of turning off the sensors in alternate columns.

7. The touch screen sensitivity dynamic adjustment platform of claim 6, wherein the platform further comprises:

and the state indicating equipment is connected with the electronic control switch and is used for displaying the current sensitivity of the second touch sub-screen in real time based on the control action of the electronic control switch on the second touch sub-screen.

8. The touch screen sensitivity dynamic adjustment platform of claim 7, wherein:

the state indicating equipment is a red-green indicating lamp arranged on a shell of the smart phone or a display driving mechanism of the smart phone.

9. The touch screen sensitivity dynamic adjustment platform of claim 8, wherein:

when the state indicating equipment is a display driving mechanism of the smart phone, displaying the current sensitivity of the second touch sub-screen on a display interface of a first touch sub-screen of the smart phone in real time based on the control action of the electronic control switch on the second touch sub-screen;

when the state indicating equipment is a display driving mechanism of the smart phone, the state indicating equipment is also used for displaying the current sensitivity of the first touch sub-screen on a display interface of the first touch sub-screen of the smart phone in real time.

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