1. The utility model provides a mouse function simulation system for mobile intelligent device which characterized in that includes:

the detection module is used for detecting the input position and judging whether the input position is positioned in the input comfortable area;

the switching module is connected with the detection module, judges whether the input comfort area is saturated or not when the input signal is positioned in the input comfort area, displays the input signal in the input comfort area if the input comfort area is unsaturated, and displays the input signal in the non-input comfort area if the input comfort area is saturated;

the display module is used for receiving the input signal and displaying the input signal in the corresponding area;

the mobile intelligent device is a touch large screen, an infrared sensor is arranged on the touch large screen and used for detecting the height of a user, an input comfort zone of the user is determined according to the actual height of the user, the infrared sensor is connected with the control module and used for transmitting information sensed by the infrared sensor to the control module, a first height H1, a second height H2 and a third height H3 are arranged in the control module, H1 is greater than H2 and less than H3, if the information sensed by the infrared sensor is smaller than or equal to the first height H1, the first zone on the touch large screen is selected as the input comfort zone, and the second zone, the third zone and the fourth zone are non-input comfort zones;

if the second height H2 is larger than or equal to the height information of the user sensed by the infrared sensor and is larger than the first height H1, selecting a second area on the touch screen as an input comfort area, and selecting the first area, a third area and a fourth area as non-input comfort areas;

if the third height H3 is larger than or equal to the user height information sensed by the infrared sensor and larger than the second height H2, selecting a third area on the touch screen as an input comfort area, and selecting the first area, the second area and the fourth area as non-input comfort areas;

and if the height information of the user sensed by the infrared sensor is higher than the third height H3, selecting a fourth area on the touch screen as an input comfort area, and selecting the first area, the second area and the third area as non-input comfort areas.

2. The mouse function simulation system applied to the mobile intelligent device according to claim 1,

for an input signal receiving area on the touch large screen, the first area is arranged below the second area, the second area is arranged below the third area, the fourth area is arranged above the third area, and the area of the first area, the area of the second area, the area of the third area and the area of the fourth area are equal.

3. The mouse function simulation system applied to the mobile intelligent device according to claim 2,

the first area is connected with a first controller, the second area is connected with a second controller, the third area is connected with a third controller, the fourth area is connected with a fourth controller,

when the first area is used as an input comfort area, the first controller is respectively connected with the second controller, the third controller and the fourth controller, so that the first controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the first controller is used for controlling the input sequence of the auxiliary controllers;

when the second area is used as an input comfort area, the second controller is respectively connected with the first controller, the third controller and the fourth controller, so that the second controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as sub-controllers, and the second controller is used for controlling the input sequence of the auxiliary controllers;

when the third area is used as an input comfort area, the third controller is respectively connected with the first controller, the second controller and the fourth controller, so that the third controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the third controller is used for controlling the input sequence of the auxiliary controllers;

when the fourth area is used as an input comfort area, the fourth controller is respectively connected with the first controller, the second controller and the third controller, so that the control instruction of the control module takes the fourth controller as a main controller, and takes other controllers connected with the main controller as auxiliary controllers, and the fourth controller is used for controlling the input sequence of the auxiliary controllers.

4. The mouse function simulation system applied to the mobile intelligent device according to claim 3,

when the first area is taken as an input comfort area, detecting a signal input quantity I1 in the first area, wherein a first signal processing quantity H10 is arranged in the first controller and is used for representing the maximum signal processing capacity of the first controller, and if the signal input quantity I1 in the first area is more than or equal to 0.9 multiplied by H10 and indicates that the input signal input quantity of the first area is close to the processing capacity of the first controller, starting the second controller after a first time interval T1;

if the signal input quantity I1 in the first area is less than or equal to 0.1 XH 10, which indicates that the input signal input quantity in the first area is very small and far reaches the processing limit of the first controller, the second controller is started after the third time interval T3;

if 0.9 × H10> the signal input amount I1>0.1 × H10 in the first region, the second controller is activated after the second time interval T2.

5. The mouse function simulation system applied to the mobile intelligent device according to claim 4,

when the second area is taken as an input comfort area, detecting a signal input quantity I2 in the second area, wherein a second signal processing quantity H20 is arranged in the second controller and is used for representing the maximum signal processing capacity of the second controller, and if the signal input quantity I2 in the second area is more than or equal to 0.8 multiplied by H20 and indicates that the input signal input quantity in the second area is close to the processing capacity of the second controller, starting the first controller after a first time interval T1;

if the signal input quantity I2 in the second area is less than or equal to 0.2 XH 20, which indicates that the input signal input quantity in the second area is very small and far reaches the processing limit of the first controller, the first controller is started after a third time interval T3;

if the signal input amount I2>0.2 × H20 in the second region of 0.8 × H20>, the first controller is activated after the second time interval T2.

6. The mouse function simulation system applied to the mobile intelligent device according to claim 5,

when the third area is taken as an input comfort area, detecting a signal input quantity I3 in the third area, wherein a third signal processing quantity H30 is arranged in the third controller and is used for representing the maximum signal processing capacity of the third controller, and if the signal input quantity I3 in the third area is greater than or equal to 0.7 multiplied by H30 and indicates that the input signal input quantity in the third area approaches the processing capacity of the third controller, starting the first controller after a first time interval T1;

if the signal input quantity I3 in the third area is less than or equal to 0.3 XH 30, which indicates that the input signal input quantity in the third area is very small and far reaches the processing limit of the third controller, the first controller is started after a third time interval T3;

if the signal input amount I3>0.3 × H30 in the third region is 0.7 × H30>, the first controller is activated after the second time interval T2.

7. The mouse function simulation system applied to the mobile intelligent device according to claim 6,

when the fourth area is taken as an input comfort area, detecting a signal input quantity I4 in the fourth area, wherein a fourth signal processing quantity H40 is arranged in the fourth controller and is used for representing the maximum signal processing capacity of the fourth controller, and if the signal input quantity I4 in the fourth area is more than or equal to 0.6 multiplied by H30 and indicates that the input signal input quantity of the fourth area is close to the processing capacity of the fourth controller, starting the first controller after a first time interval T1;

if the signal input quantity I4 in the fourth area is less than or equal to 0.4 XH 30, which indicates that the input signal input quantity in the fourth area is very small and far reaches the processing limit of the fourth controller, the first controller is started after a third time interval T3;

if the signal input amount I4>0.4 × H30 in the fourth region of 0.6 × H30>, the first controller is activated after the second time interval T2.

8. The mouse function simulation system applied to the mobile intelligent device according to claim 7, wherein the first signal processing amount H10= second signal processing amount H20= third signal processing amount H30= fourth signal processing amount H40.

Background

The mouse is the most common device for computer systems next to the keyboard, also known as a point input device. The mouse is composed of a position sensor, a special processor chip and a sampling mechanism. When the mouse moves relative to the desktop, the sampling mechanism transmits the position and distance information to the sensor in the X and Y directions, the sensor converts the position and distance information into pulses, the pulses are input to the special processor, and the special processor transmits the data format corresponding to the action displacement to the host computer according to the interface (serial port or USB port) communication protocol, so as to realize the input control of the mouse to the host computer.

However, with the continuous development of the technology, the input form is changed day by day, the mode of the keyboard and the mouse is evolved into the interactive mode with more intuition of the stylus pen input, the existing mobile terminal is beginning to support touch input or electronic pen input to realize more accurate input control on the mobile terminal, the types of the mobile intelligent devices are also updated and iterated, the functions of the mobile intelligent devices are richer, and the functions realized are richer.

Disclosure of Invention

Therefore, the invention provides a mouse function simulation system applied to mobile intelligent equipment, which can solve the problem that the existing control on a mobile terminal has limitation.

In order to achieve the above object, the present invention provides a mouse function simulation system applied to a mobile intelligent device, including:

the detection module is used for detecting the input position and judging whether the input position is positioned in the input comfortable area;

the switching module is connected with the detection module, judges whether the input comfort area is saturated or not when the input signal is positioned in the input comfort area, displays the input signal in the input comfort area if the input comfort area is unsaturated, and displays the input signal in the non-input comfort area if the input comfort area is saturated;

the display module is used for receiving the input signal and displaying the input signal in the corresponding area;

the mobile intelligent device is a touch large screen, an infrared sensor is arranged on the touch large screen and used for detecting the height of a user, an input comfort zone of the user is determined according to the actual height of the user, the infrared sensor is connected with the control module and used for transmitting information sensed by the infrared sensor to the control module, a first height H1, a second height H2 and a third height H3 are arranged in the control module, H1 is greater than H2 and less than H3, if the information sensed by the infrared sensor is smaller than or equal to the first height H1, the first zone on the touch large screen is selected as the input comfort zone, and the second zone, the third zone and the fourth zone are non-input comfort zones;

if the second height H2 is larger than or equal to the height information of the user sensed by the infrared sensor and is larger than the first height H1, selecting a second area on the touch screen as an input comfort area, and selecting the first area, a third area and a fourth area as non-input comfort areas;

if the third height H3 is larger than or equal to the user height information sensed by the infrared sensor and larger than the second height H2, selecting a third area on the touch screen as an input comfort area, and selecting the first area, the second area and the fourth area as non-input comfort areas;

and if the height information of the user sensed by the infrared sensor is higher than the third height H3, selecting a fourth area on the touch screen as an input comfort area, and selecting the first area, the second area and the third area as non-input comfort areas.

Further, for an input signal receiving area on the touch large screen, the first area is arranged below the second area, the second area is arranged below the third area, the fourth area is arranged above the third area, and the area of the first area, the area of the second area, the area of the third area and the area of the fourth area are equal.

Furthermore, the first area is connected with a first controller, the second area is connected with a second controller, the third area is connected with a third controller, the fourth area is connected with a fourth controller,

when the first area is used as an input comfort area, the first controller is respectively connected with the second controller, the third controller and the fourth controller, so that the first controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the first controller is used for controlling the input sequence of the auxiliary controllers;

when the second area is used as an input comfort area, the second controller is respectively connected with the first controller, the third controller and the fourth controller, so that the second controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as sub-controllers, and the second controller is used for controlling the input sequence of the auxiliary controllers;

when the third area is used as an input comfort area, the third controller is respectively connected with the first controller, the second controller and the fourth controller, so that the third controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the third controller is used for controlling the input sequence of the auxiliary controllers;

when the fourth area is used as an input comfort area, the fourth controller is respectively connected with the first controller, the second controller and the third controller, so that the control instruction of the control module takes the fourth controller as a main controller, and takes other controllers connected with the main controller as auxiliary controllers, and the fourth controller is used for controlling the input sequence of the auxiliary controllers.

Further, when the first area is taken as an input comfort area, detecting a signal input quantity I1 in the first area, wherein a first signal processing quantity H10 is arranged in the first controller and used for representing the maximum signal processing capacity of the first controller, and if the signal input quantity I1 in the first area is more than or equal to 0.9 × H10 and represents that the input signal input quantity of the first area approaches the processing capacity of the first controller, starting the second controller after a first time interval T1;

if the signal input quantity I1 in the first area is less than or equal to 0.1 XH 10, which indicates that the input signal input quantity in the first area is very small and far reaches the processing limit of the first controller, the second controller is started after the third time interval T3;

if 0.9 × H10> the signal input amount I1>0.1 × H10 in the first region, the second controller is activated after the second time interval T2.

Further, when the second area is taken as an input comfort area, detecting a signal input quantity I2 in the second area, wherein a second signal processing quantity H20 is arranged in the second controller and used for representing the maximum signal processing capacity of the second controller, and if the signal input quantity I2 in the second area is greater than or equal to 0.8 × H20 and represents that the input signal input quantity in the second area approaches the processing capacity of the second controller, starting the first controller after a first time interval T1;

if the signal input quantity I2 in the second area is less than or equal to 0.2 XH 20, which indicates that the input signal input quantity in the second area is very small and far reaches the processing limit of the first controller, the first controller is started after a third time interval T3;

if the signal input amount I2>0.2 × H20 in the second region of 0.8 × H20>, the first controller is activated after the second time interval T2.

Further, when the third area is taken as the input comfort area, detecting a signal input amount I3 in the third area, wherein a third signal processing amount H30 is provided in the third controller to represent the maximum signal processing capacity of the third controller, and if the signal input amount I3 in the third area is greater than or equal to 0.7 × H30 and represents that the input signal input amount in the third area approaches the processing capacity of the third controller, starting the first controller after a first time interval T1;

if the signal input quantity I3 in the third area is less than or equal to 0.3 XH 30, which indicates that the input signal input quantity in the third area is very small and far reaches the processing limit of the third controller, the first controller is started after a third time interval T3;

if the signal input amount I3>0.3 × H30 in the third region is 0.7 × H30>, the first controller is activated after the second time interval T2.

Further, when the fourth area is taken as an input comfort area, detecting a signal input quantity I4 in the fourth area, wherein a fourth signal processing quantity H40 is arranged in the fourth controller and used for representing the maximum signal processing capacity of the fourth controller, and if the signal input quantity I4 in the fourth area is greater than or equal to 0.6 × H30 and represents that the input signal input quantity of the fourth area is close to the processing capacity of the fourth controller, starting the first controller after a first time interval T1;

if the signal input quantity I4 in the fourth area is less than or equal to 0.4 XH 30, which indicates that the input signal input quantity in the fourth area is very small and far reaches the processing limit of the fourth controller, the first controller is started after a third time interval T3;

if the signal input amount I4>0.4 × H30 in the fourth region of 0.6 × H30>, the first controller is activated after the second time interval T2.

Further, the first signal processing amount H10= second signal processing amount H20= third signal processing amount H30= fourth signal processing amount H40.

Compared with the prior art, the touch control large screen input method has the advantages that the input comfortable area for the user to input exists in the display area of the touch control large screen in the using process, the user can keep a basic standing posture when inputting in the input comfortable area, and the input comfortable area is located in the input comfortable area of the user without bending down or waisting, so that the input function of the large screen is completed.

Particularly, the input comfort areas of users with different heights are determined based on the range of the height information of the users, so that the matching best area is conveniently the input comfort area when the users input, then the non-input comfort area is indirectly determined, after the information in the input comfort area is saturated, the corresponding information is input in the input comfort area and is displayed in the non-input comfort area, further, the information display of the two areas is completed, and the utilization efficiency of the touch large screen is improved.

Particularly, the four same area areas are arranged, so that the optimal input area of a user can be defined, the partition input can be realized conveniently, the operation of each area can be realized, the control on the mobile touch large screen is more flexible, the input control can be performed in any area, and the utilization of the input space of the touch large screen is more efficient.

Particularly, each area is connected with a corresponding controller, the controllers are used for controlling each area, the functions of the corresponding controllers are different when the identities of different areas are different, when the first area is used as an input comfortable area, the first controller connected with the first area is used as a main controller, the controllers connected with other areas are used as auxiliary controllers, the main controller controls the working sequence of the auxiliary controllers, in the actual process, the effective work of the corresponding areas of the auxiliary controllers is realized through the control action of the main controller, the input efficiency of the large touch screen is improved, and the efficient utilization of the large touch screen is realized.

Especially, by setting the first signal processing amount H10, the signal processing capability of the first controller is characterized, and in the practical application process, if the signal input amount of the first area is close to saturation, the second controller needs to be started after the first time interval, and the corresponding signal is input and displayed in the second area, so that the accurate judgment of the working time node of the second controller is realized, and the input efficiency of the mobile intelligent device is improved.

Especially, by setting the third signal processing amount H30, the signal processing capability of the third controller is characterized, and in the actual application process, if the signal input amount of the third area is close to saturation, the first controller needs to be started after the first time interval, and the corresponding signal is input and displayed in the first area, so that the accurate judgment of the working time node of the first controller is realized, and the input efficiency of the mobile intelligent device is improved.

Particularly, the same judgment standard is adopted, so that the signal processing capacity of each region is balanced, the accurate judgment of the starting time of the corresponding non-input comfort zone controller is facilitated, the processing capacity of input signals is improved, and the working efficiency of the mobile intelligent device is improved.

Drawings

Fig. 1 is a schematic structural diagram of a mouse function simulation system applied to a mobile intelligent device according to an embodiment of the present invention.

Detailed Description

In order that the objects and advantages of the invention will be more clearly understood, the invention is further described below with reference to 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.

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and do not limit the scope of the present invention.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Referring to fig. 1, a mouse function simulation system applied to a mobile intelligent device according to an embodiment of the present invention includes:

the detection module 10 is used for detecting an input position and judging whether the input position is positioned in an input comfortable area;

the switching module 20 is connected with the detection module, and when the input signal is located in the input comfort zone, whether the input comfort zone is saturated is judged, if the input comfort zone is unsaturated, the input signal is displayed in the input comfort zone, and if the input comfort zone is saturated, the display area is switched, and the input signal is displayed in the non-input comfort zone;

and the display module 30 is configured to receive the input signal and display the input signal in the corresponding area.

Specifically, the mobile intelligent device applied to the mouse function simulation system of the mobile intelligent device in the embodiment of the present invention may be a mobile touch-sensitive large screen, and an input comfort region for user input exists in a display region of the touch-sensitive large screen during use, so that a user can keep a basic standing posture during input in the input comfort region, and the mobile intelligent device is located in the input comfort region of the user without bending or waisting, thereby completing an input function of the large screen.

Specifically, the input signal may be a touch signal, and when the input signal is input, if the input position is located in the input comfort region, the input signal is displayed in the input comfort region; when the input comfort zone is saturated with information, the input signal is displayed in the non-input comfort zone.

Specifically, an infrared sensor is arranged on the touch screen and used for detecting the height of a user, an input comfort zone of the user is determined according to the actual height of the user, the infrared sensor is connected with the control module and used for transmitting information sensed by the infrared sensor to the control module 40, a first height H1, a second height H2 and a third height H3 are arranged in the control module, H1 is greater than H2 and is less than H3, if the information sensed by the infrared sensor is not greater than the first height H1, a first zone on the touch screen is selected as the input comfort zone, and a second zone, a third zone and a fourth zone are selected as non-input comfort zones;

if the second height H2 is larger than or equal to the height information of the user sensed by the infrared sensor and is larger than the first height H1, selecting a second area on the touch screen as an input comfort area, and selecting the first area, a third area and a fourth area as non-input comfort areas;

if the third height H3 is larger than or equal to the user height information sensed by the infrared sensor and larger than the second height H2, selecting a third area on the touch screen as an input comfort area, and selecting the first area, the second area and the fourth area as non-input comfort areas;

and if the height information of the user sensed by the infrared sensor is higher than the third height H3, selecting a fourth area on the touch screen as an input comfort area, and selecting the first area, the second area and the third area as non-input comfort areas.

Specifically, the mouse function simulation system applied to the mobile intelligent device determines the input comfort zones of users with different heights through the range of the height information of the users, so that the optimal zone is matched as the input comfort zone when the users input information, then indirectly determines the non-input comfort zone, and after the information in the input comfort zone is saturated, corresponding information is input in the input comfort zone and displayed in the non-input comfort zone, thereby completing information display of the two zones and improving the utilization efficiency of a touch screen.

Specifically, for an input signal receiving area on the touch large screen, the first area is arranged below the second area, the second area is arranged below the third area, the fourth area is arranged above the third area, and the area of the first area, the area of the second area, the area of the third area and the area of the fourth area are equal.

Specifically, the four same area areas are arranged, so that the optimal input area of a user is defined, the partition input is facilitated, the operation of each area is realized, the control of the mobile touch large screen is more flexible, the input control can be performed in any area, and the utilization of the input space of the touch large screen is more efficient.

Specifically, a first controller is connected to the first area, a second controller is connected to the second area, a third controller is connected to the third area, a fourth controller is connected to the fourth area,

when the first area is used as an input comfort area, the first controller is respectively connected with the second controller, the third controller and the fourth controller, so that the first controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the first controller is used for controlling the input sequence of the auxiliary controllers;

when the second area is used as an input comfort area, the second controller is respectively connected with the first controller, the third controller and the fourth controller, so that the second controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as sub-controllers, and the second controller is used for controlling the input sequence of the auxiliary controllers;

when the third area is used as an input comfort area, the third controller is respectively connected with the first controller, the second controller and the fourth controller, so that the third controller is used as a main controller for controlling the control instruction of the control module, and other controllers connected with the main controller are used as auxiliary controllers, and the third controller is used for controlling the input sequence of the auxiliary controllers;

when the fourth area is used as an input comfort area, the fourth controller is respectively connected with the first controller, the second controller and the third controller, so that the control instruction of the control module takes the fourth controller as a main controller, and takes other controllers connected with the main controller as auxiliary controllers, and the fourth controller is used for controlling the input sequence of the auxiliary controllers.

Specifically, each area is connected with a corresponding controller, the controllers are used for controlling each area, the functions of the corresponding controllers are different when the identities of different areas are different, when the first area is used as an input comfort area, the first controller connected with the first area is used as a main controller, the controllers connected with other areas are used as auxiliary controllers, and the main controller is used for controlling the working sequence of the auxiliary controllers.

Specifically, when the first area is taken as an input comfort area, detecting a signal input quantity I1 in the first area, wherein a first signal processing quantity H10 is arranged in the first controller and used for representing the maximum signal processing capacity of the first controller, and if the signal input quantity I1 in the first area is more than or equal to 0.9 × H10 and indicates that the input signal input quantity in the first area approaches the processing capacity of the first controller, starting the second controller after a first time interval T1;

if the signal input quantity I1 in the first area is less than or equal to 0.1 XH 10, which indicates that the input signal input quantity in the first area is very small and far reaches the processing limit of the first controller, the second controller is started after the third time interval T3;

if 0.9 × H10> the signal input amount I1>0.1 × H10 in the first region, the second controller is activated after the second time interval T2.

Specifically, the maximum signal processing capacity of the first controller is the total amount of signals that need to be processed in the signal saturation state in the first region, and it should be noted that the maximum signal processing capacities of the second controller, the third controller and the fourth controller may be analogized and respectively correspond to the total amount of signals that need to be processed in the signal saturation state in the second region, the total amount of signals that need to be processed in the signal saturation state in the third region and the total amount of signals that need to be processed in the signal saturation state in the fourth region.

Specifically, in the embodiment of the present invention, the first signal processing amount H10 is set to characterize the signal processing capability of the first controller, and in an actual application process, if the signal input amount of the first area is close to saturation, the second controller needs to be started after the first time interval, and a corresponding signal is input and displayed in the second area, so that the accurate determination of the working time node of the second controller is realized, and the input efficiency of the mobile intelligent device is improved.

Specifically, when the second area is taken as an input comfort area, detecting a signal input quantity I2 in the second area, wherein a second signal processing quantity H20 is arranged in the second controller and used for representing the maximum signal processing capacity of the second controller, and if the signal input quantity I2 in the second area is more than or equal to 0.8 × H20 and indicates that the input signal input quantity in the second area is close to the processing capacity of the second controller, starting the first controller after a first time interval T1;

if the signal input quantity I2 in the second area is less than or equal to 0.2 XH 20, which indicates that the input signal input quantity in the second area is very small and far reaches the processing limit of the first controller, the first controller is started after a third time interval T3;

if the signal input amount I2>0.2 × H20 in the second region of 0.8 × H20>, the first controller is activated after the second time interval T2.

Specifically, in the embodiment of the present invention, the second signal processing amount H20 is set to characterize the signal processing capability of the second controller, and in an actual application process, if the signal input amount of the second area is close to saturation, the first controller needs to be started after the first time interval, and a corresponding signal is input and displayed in the first area, so that an accurate determination on the working time node of the first controller is realized, and the input efficiency of the mobile intelligent device is improved.

Specifically, when the third area is taken as the input comfort area, detecting a signal input amount I3 in the third area, wherein a third signal processing amount H30 is arranged in the third controller to represent the maximum signal processing capacity of the third controller, and if the signal input amount I3 in the third area is greater than or equal to 0.7 × H30 and represents that the input signal input amount in the third area approaches the processing capacity of the third controller, starting the first controller after a first time interval T1;

if the signal input quantity I3 in the third area is less than or equal to 0.3 XH 30, which indicates that the input signal input quantity in the third area is very small and far reaches the processing limit of the third controller, the first controller is started after a third time interval T3;

if the signal input amount I3>0.3 × H30 in the third region is 0.7 × H30>, the first controller is activated after the second time interval T2.

Specifically, in the embodiment of the present invention, the third signal processing amount H30 is set to characterize the signal processing capability of the third controller, and in an actual application process, if the signal input amount of the third area is close to saturation, the first controller needs to be started after the first time interval, and a corresponding signal is input and displayed in the first area, so that the accurate determination of the working time node of the first controller is realized, and the input efficiency of the mobile intelligent device is improved.

Specifically, when the fourth area is taken as an input comfort area, detecting a signal input quantity I4 in the fourth area, wherein a fourth signal processing quantity H40 is arranged in the fourth controller and is used for representing the maximum signal processing capacity of the fourth controller, and if the signal input quantity I4 in the fourth area is greater than or equal to 0.6 × H30 and indicates that the input signal input quantity in the fourth area is close to the processing capacity of the fourth controller, starting the first controller after a first time interval T1;

if the signal input quantity I4 in the fourth area is less than or equal to 0.4 XH 30, which indicates that the input signal input quantity in the fourth area is very small and far reaches the processing limit of the fourth controller, the first controller is started after a third time interval T3;

if the signal input amount I4>0.4 × H30 in the fourth region of 0.6 × H30>, the first controller is activated after the second time interval T2.

Specifically, in the embodiment of the present invention, the fourth signal processing amount H40 is set to characterize the signal processing capability of the fourth controller, and in an actual application process, if the signal input amount of the fourth area is close to saturation, the first controller needs to be started after the first time interval, and a corresponding signal is input and displayed in the first area, so that the accurate determination of the working time node of the first controller is realized, and the input efficiency of the mobile intelligent device is improved.

Specifically, the first signal processing amount H10= the second signal processing amount H20= the third signal processing amount H30= the fourth signal processing amount H40.

Specifically, the embodiment of the invention enables the signal processing capacity of each region to be balanced by adopting the same judgment standard, facilitates the accurate judgment of the starting time of the corresponding non-input comfort zone controller, improves the processing capacity of the input signal and improves the working efficiency of the mobile intelligent device.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention; various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.