CN111033456A - Operation mode determination method and device, storage medium and electronic equipment - Google Patents
Operation mode determination method and device, storage medium and electronic equipment Download PDFInfo
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- CN111033456A CN111033456A CN201780090732.6A CN201780090732A CN111033456A CN 111033456 A CN111033456 A CN 111033456A CN 201780090732 A CN201780090732 A CN 201780090732A CN 111033456 A CN111033456 A CN 111033456A
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- 238000004590 computer program Methods 0.000 claims description 10
- 210000003811 finger Anatomy 0.000 description 15
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/048—Interaction techniques based on graphical user interfaces [GUI]
- G06F3/0487—Interaction techniques based on graphical user interfaces [GUI] using specific features provided by the input device, e.g. functions controlled by the rotation of a mouse with dual sensing arrangements, or of the nature of the input device, e.g. tap gestures based on pressure sensed by a digitiser
- G06F3/0488—Interaction techniques based on graphical user interfaces [GUI] using specific features provided by the input device, e.g. functions controlled by the rotation of a mouse with dual sensing arrangements, or of the nature of the input device, e.g. tap gestures based on pressure sensed by a digitiser using a touch-screen or digitiser, e.g. input of commands through traced gestures
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Abstract
An operation mode determination method comprising: when the terminal is detected to be operated, respectively acquiring first stress information of a left frame and second stress information of a right frame (S101); and if the stressed areas on the left frame are detected to be continuously distributed according to the first stressed information and the stressed areas on the right frame are detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stressed information, determining that the terminal is in a left-hand single-hand operation mode (S102).
Description
The embodiment of the invention relates to the technical field of terminals, in particular to an operation mode determining method and device, a storage medium and electronic equipment.
With the continuous development of technologies, the functions of the mobile terminal are more and more. For example, on a mobile terminal, it is possible to read e-books, browse news, play games, listen to music, etc. Therefore, the frequency with which the mobile terminal is used by the user is also increasing. Many users are accustomed to operating a mobile terminal with one hand during use.
The embodiment of the invention provides an operation mode determination method, an operation mode determination device, a storage medium and electronic equipment, which can accurately determine an operation mode of a terminal.
The operation mode determining method provided by the embodiment of the invention is suitable for a terminal, wherein the method comprises the following steps:
when the terminal is detected to be operated, respectively acquiring first stress information of a left frame and second stress information of a right frame of the terminal;
if the stress area on the left frame is detected to be continuously distributed according to the first stress information and the stress area on the right frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stress information, determining that the terminal is in a left-hand single-hand operation mode;
and if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is continuously distributed according to the second stress information, determining that the terminal is in a right-hand single-hand operation mode.
The operation mode determining apparatus provided in the embodiment of the present invention is applicable to a terminal, wherein the apparatus includes:
the first acquisition module is used for respectively acquiring first stress information of a left frame and second stress information of a right frame of the terminal when the terminal is detected to be operated;
a first determining module, configured to determine that the terminal is in a left-hand single-hand operation mode if it is detected that the stressed areas on the left frame are continuously distributed according to the first stress information and it is detected that the stressed area on the right frame includes a plurality of sub-areas that are distributed at intervals according to the second stress information;
and the second determining module is used for determining that the terminal is in a right-hand single-hand operation mode if the stress area on the left frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is detected to be continuously distributed according to the second stress information.
An embodiment of the present invention provides a storage medium having a computer program stored thereon, which, when executed on a computer, causes the computer to execute an operation mode determination method provided by an embodiment of the present invention.
The embodiment of the present invention further provides an electronic device, which includes a memory and a processor, wherein the processor is configured to execute, by calling a computer program stored in the memory:
when the electronic equipment is detected to be operated, respectively acquiring first stress information of a left frame and second stress information of a right frame of the electronic equipment;
if the stress areas on the left frame are detected to be continuously distributed according to the first stress information and the stress areas on the right frame are detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stress information, determining that the electronic equipment is in a left-hand single-hand operation mode;
and if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is continuously distributed according to the second stress information, determining that the electronic equipment is in a right-hand single-hand operation mode.
The embodiment of the invention provides an operation mode determination method, an operation mode determination device, a storage medium and electronic equipment, which can accurately determine an operation mode of a terminal.
Fig. 1 is a schematic diagram of components of a terminal according to an embodiment of the present invention.
Fig. 2 is a flowchart illustrating an operation mode determining method according to an embodiment of the present invention.
Fig. 3 is a schematic diagram of a right-hand one-hand operation mode of the terminal according to the embodiment of the present invention.
Fig. 4 is another flowchart illustrating an operation mode determining method according to an embodiment of the present invention.
Fig. 5 is a schematic structural diagram of a pressure sensor on the left frame of the terminal according to the embodiment of the present invention.
Fig. 6 is a schematic structural diagram of a pressure sensor on the left frame of the terminal according to the embodiment of the present invention.
Fig. 7A to 7B are schematic scene diagrams of an operation mode determination method according to an embodiment of the present invention.
Fig. 8 is a schematic structural diagram of an operation mode determination apparatus according to an embodiment of the present invention.
Fig. 9 is another schematic structural diagram of the operation mode determination apparatus according to the embodiment of the present invention.
Fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.
Fig. 11 is another schematic structural diagram of an electronic device according to an embodiment of the present invention.
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without any inventive step, are within the scope of the present invention.
It is understood that the execution subject of the embodiment of the present invention may be a terminal such as a smart phone or a tablet computer. In one embodiment, as shown in fig. 1, the terminal may include a display screen, a home key (home key). The display screen may be used to display text or images, etc. When the user presses the home screen key, the terminal may return to the home screen interface.
Referring to fig. 2, fig. 2 is a schematic flow chart of an operation mode determination method according to an embodiment of the present invention, where the flow of the operation mode determination method may include:
in step S101, when it is detected that the terminal is operated, first force information of a left frame and second force information of a right frame of the terminal are respectively obtained.
For example, with the continuous development of technologies, the functions of the mobile terminal are more and more. For example, on a mobile terminal, one may read an e-book, browse news, play games, listen to music, and so forth. Therefore, the frequency with which the mobile terminal is used by the user is also increasing. Many users are accustomed to operating a mobile terminal with one hand during use.
In step S101 of the embodiment of the present invention, when it is detected that the terminal is operated, the terminal may obtain stress information (i.e., first stress information) of a left frame and stress information (i.e., second stress information) of a right frame of the terminal.
Then, the terminal may detect that the stressed areas on the left frame are distributed continuously or that the stressed areas on the left frame include a plurality of sub-areas distributed at intervals according to the first stress information. And the terminal can detect that the stressed areas on the right frame are continuously distributed or that the stressed areas on the right frame comprise a plurality of sub-areas distributed at intervals according to the second stressed information.
If it is detected that the stressed areas on the left frame are continuously distributed according to the first stress information and the stressed areas on the right frame are continuously distributed according to the second stress information, the terminal may perform other operations.
If the stressed area on the left frame is detected to comprise a plurality of sub-areas distributed at intervals according to the first stress information, and the stressed area on the right frame is detected to comprise a plurality of sub-areas distributed at intervals according to the second stress information, the terminal can also execute other operations.
If it is detected that the stressed areas on the left frame are continuously distributed according to the first stressed information, and it is detected that the stressed areas on the right frame include a plurality of sub-areas which are distributed at intervals according to the second stressed information, the process proceeds to step S102.
If it is detected that the stressed area on the left frame includes a plurality of sub-areas distributed at intervals according to the first stress information, and it is detected that the stressed areas on the right frame are continuously distributed according to the second stress information, the process proceeds to step S103.
In step S102, if it is detected that the stressed regions on the left frame are continuously distributed according to the first stress information, and it is detected that the stressed region on the right frame includes a plurality of sub-regions distributed at intervals according to the second stress information, it is determined that the terminal is in the left-hand single-hand operation mode.
For example, the terminal detects that the stressed areas on the left frame are continuously distributed according to the first stressed information of the left frame, that is, the stressed area on the left frame is a complete single area. And the terminal detects that the stressed area on the right frame comprises a plurality of sub-areas distributed at intervals according to the second stress information of the right frame, that is, the stressed area on the right frame is composed of a plurality of sub-areas distributed at intervals (that is, not communicated with each other). Then, in this case, it can be determined that the terminal is in the left-handed single-handed operation mode (i.e., the user operates the terminal with the left hand and the single hand).
When the user operates the terminal with one hand with the left hand, the contact surface (portion) between the palm of the left hand of the user and the left frame of the terminal is a continuous surface. Thus, the force-bearing area on the left frame is a continuously distributed, complete single area. The user's left finger and the terminal right frame have multiple contact surfaces, and the multiple contact surfaces are generally spaced. Therefore, the force-receiving area on the right frame may include a plurality of sub-areas that are spaced apart.
In step S103, if it is detected that the stressed area on the left frame includes a plurality of sub-areas distributed at intervals according to the first stress information, and it is detected that the stressed area on the right frame is continuously distributed according to the second stress information, it is determined that the terminal is in the right-hand one-hand operation mode.
For example, the terminal detects that the stressed area on the left frame includes a plurality of sub-areas distributed at intervals according to the first stress information of the left frame, that is, the stressed area on the left frame is composed of a plurality of sub-areas distributed at intervals (that is, not connected to each other). And the terminal detects that the stress area on the right frame is continuously distributed according to the second stress information of the right frame, namely the stress area on the right frame is a complete single area. Then, in this case, it can be determined that the terminal is in the right-handed one-handed operation mode (i.e., the user operates the terminal with the right-handed one hand).
When the user operates the terminal with one hand, the contact surface (portion) between the palm of the user's right hand and the right frame of the terminal is a continuous surface. Thus, the force-bearing area on the right frame is a continuously distributed, complete single area. The user's right finger and the left frame of the terminal will have multiple contact surfaces, which are typically spaced apart. Thus, the force-bearing area on the left frame will include a plurality of sub-areas spaced apart.
For example, as shown in fig. 3, when the user operates the terminal with one hand in the right hand, the contact surface between the palm of the user's right hand and the right frame of the terminal is an area a, which is a complete single area, i.e. the stressed area on the right frame is continuously distributed. Meanwhile, the finger of the right hand of the user has a plurality of contact surfaces with the left frame of the terminal, such as the regions B, C, D respectively included as shown in the figure, so that the force-bearing region on the left frame includes a plurality of sub-regions B, C, D which are distributed at intervals.
Referring to fig. 4, fig. 4 is another schematic flow chart of the operation mode determining method according to the embodiment of the invention. The operation mode determining method is applicable to a terminal, wherein a left frame and a right frame of the terminal respectively comprise a plurality of pressure sensors, each pressure sensor on the left frame and the right frame is respectively provided with a corresponding identification number, and the identification numbers of the pressure sensors adjacent to each other in position are continuous in value. The flow of the operation mode determination method may include:
in step S201, when it is detected that the terminal is operated, the terminal acquires an identification number corresponding to the pressure sensor having an output value on the left frame.
For example, upon detecting that the terminal is operated, the terminal may acquire information of a pressure sensor having an output value on the left frame and acquire information of a pressure sensor having an output value on the right frame. The information of the pressure sensor having the output value on the left frame may represent first stress information of the left frame. And the information of the pressure sensor having the output value on the right frame may represent second stress information of the right frame.
Then, the terminal may detect whether the stressed areas on the left frame are continuously distributed according to the information of the pressure sensor having the output value on the left frame, and detect whether the stressed areas on the right frame are continuously distributed according to the information of the pressure sensor having the output value on the right frame.
For example, in the embodiment of the present invention, the terminal may be sequentially provided with 30 pressure sensors along the left frame, and the identification numbers assigned to the 30 pressure sensors are 1, 2, 3, … …, 28, 29, 30, respectively, in order from the top to the bottom of the terminal, as shown in fig. 5. Wherein the identification numbers of the pressure sensors located adjacently are numerically consecutive. For example, the pressure sensor a1 and the pressure sensor a2 are disposed adjacently, and the identification number 1 of the pressure sensor a1 and the identification number 2 of the pressure sensor a2 are numerically continuous. As another example, the pressure sensor a2 and the pressure sensor a3 are disposed adjacently, and the identification number 2 of the pressure sensor a2 and the identification number 3 of the pressure sensor a3 are consecutive in numerical value.
Then, when it is detected that the terminal is operated by the user, the terminal may first acquire the identification number of the pressure sensor having the output value on the left frame thereof.
It will be appreciated that the pressure sensor having an output value is also the pressure sensor on the bezel where the palm or fingers of the user are gripping. When holding the terminal, the palm or fingers of the user contact the frame and exert pressure on the contact point, so that the corresponding pressure sensor at the contact point has an output value.
For example, if the left frame has output values from the pressure sensor a16 through to the pressure sensor a29, the terminal can sequentially acquire the identification numbers from the pressure sensor a16 through to the pressure sensor a 29. For example, the identification numbers acquired by the terminal are 16, 17, 18, … …, 27, 28, and 29.
In step S202, the terminal acquires an identification number corresponding to the pressure sensor having the output value on the right frame.
For example, the terminal may be provided with 30 pressure sensors in sequence along the right frame, and the identification numbers assigned to the 30 pressure sensors are 31, 32, 33, … …, 58, 59, and 60, respectively, in order from the top to the bottom of the terminal, as shown in fig. 6. Wherein the identification numbers of the pressure sensors located adjacently are numerically consecutive. For example, the pressure sensor b28 and the pressure sensor b29 are disposed adjacently, and the identification number 58 of the pressure sensor b28 and the identification number 59 of the pressure sensor b29 are numerically continuous. For another example, the pressure sensor b29 and the pressure sensor b30 are disposed adjacently, and the identification number 59 of the pressure sensor b29 and the identification number 60 of the pressure sensor b30 are consecutive in value.
Then, after acquiring the identification number corresponding to the pressure sensor having the output value on the left frame of the terminal, the terminal may acquire the identification number of the pressure sensor having the output value on the right frame.
For example, the terminal determines that the pressure sensors having output values on the right frame are b18, b19, b22, b23, b25, and b26, and then the terminal may sequentially acquire the identification numbers of the pressure sensors. For example, the identification numbers 48, 49, 52, 53, 55, 56 are acquired by the terminal.
In step S203, the terminal acquires a first number of pressure sensors having output values on the left frame and a second number of pressure sensors having output values on the right frame.
For example, after acquiring the identification numbers corresponding to the pressure sensors having output values on the left frame and the identification numbers of the pressure sensors having output values on the right frame, the terminal may acquire the number of the pressure sensors having output values on the left frame, that is, the first number, and the number of the pressure sensors having output values on the right frame, that is, the second number.
Then, the terminal may detect whether the identification numbers of the pressure sensors having the output values on the left frame acquired by the terminal are kept continuous, and detect whether the identification numbers of the pressure sensors having the output values on the right frame acquired by the terminal are kept continuous.
Meanwhile, the terminal may also detect whether the first number is greater than the second number.
If it is detected that the identification numbers of the pressure sensors having output values on the left frame are not continuous and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the terminal can perform other operations regardless of whether the first number is greater than the second number.
If it is detected that the identification numbers of the pressure sensors having output values on the left frame are kept continuous and the identification numbers of the pressure sensors having output values on the right frame are also kept continuous, the terminal can perform other operations regardless of whether the first number is greater than the second number.
If it is detected that the identification numbers of the pressure sensors having output values on the left frame are kept continuous and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the terminal may obtain the comparison result of the first number and the second number.
If the first number is less than or equal to the second number, the terminal may perform other operations.
If the first number is greater than the second number, the process proceeds to step S204.
If it is detected that the identification numbers of the pressure sensors having output values on the right frame are kept continuous and the identification numbers of the pressure sensors having output values on the left frame are not continuous, the terminal can also obtain the comparison result of the first number and the second number.
If the second number is less than or equal to the first number, the terminal may perform other operations.
If the second number is greater than the first number, the process proceeds to step S206.
In step S204, if it is detected that the identification numbers of the pressure sensors having output values on the left frame are continuous, the identification numbers of the pressure sensors having output values on the right frame are discontinuous, and the first number is greater than the second number, the terminal determines that the stressed areas on the left frame are continuously distributed, and the stressed areas on the right frame include a plurality of sub-areas distributed at intervals.
In step S205, the terminal determines to be in the left-hand one-handed operation mode.
For example, steps S204 and S205 may include:
the terminal detects that the identification numbers of the pressure sensors with the output values on the left frame of the terminal are kept continuous, but the identification numbers of the pressure sensors with the output values on the right frame of the terminal are discontinuous, and the first number is larger than the second number, so that the terminal can determine that the stress areas on the left frame of the terminal are continuously distributed, the stress areas on the right frame of the terminal comprise a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a left-hand single-hand operation mode, namely the terminal can determine that a user operates the terminal by using a left hand and a single hand.
For example, the identification numbers of the pressure sensors having output values on the left frame acquired by the terminal are 16, 17, 18, … …, 27, 28, 29. Therefore, the terminal detects that the identification numbers of the pressure sensors having the output values on the left frame are kept continuous.
And the identification numbers of the pressure sensors with output values on the right frame acquired by the terminal are 48, 49, 52, 53, 55 and 56. Therefore, the terminal detects that the identification number of the pressure sensor having the output value on the right frame is not continuous.
And the first number of pressure sensors having output values on the left frame is 14 and the second number of pressure sensors having output values on the right frame is 6.
Then, the terminal may detect that the identification numbers of the pressure sensors having output values on the left frame thereof remain continuous, and the identification numbers of the pressure sensors having output values on the right frame thereof do not continue, and the first number is greater than the second number. In this case, the terminal may determine that the terminal is in the left-handed single-handed operation mode, that is, the terminal may determine that the user operates the terminal with the left-handed single hand.
When the user operates the terminal with one hand with the left hand, the contact surface (portion) between the palm of the left hand of the user and the left frame of the terminal is a continuous surface. Thus, the identification of the pressure sensor having the output value on the left frame may be continuous. The user's left finger and the terminal right frame have multiple contact surfaces, and the multiple contact surfaces are generally spaced. Therefore, the identification number of the pressure sensor having the output value on the right frame may be discontinuous. In addition, because the contact surface between the palm of the left hand of the user and the left frame is larger than the contact surface between the fingers of the left hand and the right frame, the first number is larger than the second number.
In step S206, if it is detected that the identification numbers of the pressure sensors with output values on the right frame are continuous, the identification numbers of the pressure sensors with output values on the left frame are discontinuous, and the second number is greater than the first number, the terminal determines that the stressed areas on the right frame are continuously distributed, and the stressed areas on the left frame include a plurality of sub-areas distributed at intervals.
In step S207, the terminal determines to be in the right-hand one-handed operation mode.
For example, steps S206 and S207 may include:
the terminal detects that the identification numbers of the pressure sensors with the output values on the right frame of the terminal are kept continuous, but the identification numbers of the pressure sensors with the output values on the left frame of the terminal are discontinuous, and the second number is larger than the first number, so that the terminal can determine that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a right-hand single-hand operation mode. That is, the terminal may determine that the user is operating the terminal with one hand.
For example, the identification numbers of the pressure sensors having output values on the right frame acquired by the terminal are 49, 50, 51, … …, 58, 59, 60. Therefore, the terminal detects that the identification numbers of the pressure sensors having output values on the right frame are kept continuous.
And the identification numbers of the pressure sensors with output values on the left frame acquired by the terminal are 18, 19, 22, 23, 25 and 26. Therefore, the terminal detects that the identification number of the pressure sensor having the output value on the left frame is not continuous.
And the first number of pressure sensors having output values on the right frame is 12 and the second number of pressure sensors having output values on the left frame is 6.
Then, the terminal may detect that the identification numbers of the pressure sensors having output values on the right frame thereof remain continuous, and the identification numbers of the pressure sensors having output values on the left frame thereof do not continue, and the second number is greater than the first number. In this case, the terminal may determine that the terminal is in the right-handed one-handed operation mode, that is, the terminal may determine that the user operates the terminal with the right-handed one-handed operation.
When the user operates the terminal with one hand, the contact surface (portion) between the palm of the user's right hand and the right frame of the terminal is a continuous surface. Therefore, the identification of the pressure sensor having the output value on the right frame may be continuous. The user's right finger and the left frame of the terminal will have multiple contact surfaces, which are typically spaced apart. Therefore, the identification number of the pressure sensor having the output value on the left frame may be discontinuous. In addition, because the contact surface between the palm of the right hand of the user and the right frame is larger than the contact surface between the fingers of the right hand and the left frame, the second number is larger than the first number.
In one implementation, the embodiment of the present invention may further include the following steps:
the terminal records a touch position corresponding to each touch operation in the preset times of touch operations.
The terminal determines a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the terminal.
The terminal counts the first times of touch operation of a preset first area in the touch area, and calculates a first proportional value of the first times and the preset times.
And the terminal counts a second frequency of touch operation of the touch area in a preset second area, and calculates a second proportional value of the second frequency and the preset frequency.
If the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than the preset proportion threshold value, the terminal determines that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
If the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is larger than the preset proportion threshold value, the terminal determines that the stress area on the right frame is continuously distributed, the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a right-hand single-hand operation mode.
For example, the terminal may record a touch position corresponding to each touch operation in the preset 20 touch operations. The terminal may then determine the touch area to which each touch location belongs. The touch area may include a preset first area and a preset second area. The touch screen area of the terminal may be composed of the preset first area and the preset second area. For example, the preset first area may be a left half screen of the touch screen, and the preset second area may be a right half screen of the touch screen. Then, the terminal may determine whether each touch position belongs to the left half screen or the right half screen.
After determining the touch area to which each touch position belongs, the terminal may count a first number of times of touch operations in which the touch area is a preset first area, and calculate a first ratio value between the first number of times and the preset number of times. For example, after determining the touch area to which each touch position belongs, the terminal may count a first number of times of touch operations of the left half-screen of which the touch area is a preset number, and calculate a first ratio value between the first number of times and a preset number of 20 times.
Then, the terminal may detect whether the first ratio value is greater than a preset ratio threshold.
If the first proportion value is detected to be larger than the preset proportion threshold value, and the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, and the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, the terminal can be determined to be in a left-hand single-hand operation mode.
For example, the terminal detects that the touch position belongs to the preset touch operation of the left half screen for 18 times in 20 touch operations, and then the first ratio is 90%. For example, the preset proportion threshold is 80%. Then, the first scale value is greater than the preset scale threshold. In this case, if it is detected that the identification numbers of the pressure sensors having output values on the left frame are kept continuous and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the terminal may determine that the terminal is in the left-handed single-handed operation mode.
It can be understood that when the user operates the terminal with one hand using the left hand, the touch operation is generally performed with the left thumb, and when the touch operation is performed with the left thumb, the touch position corresponding to the touch operation is biased to the left (especially when the terminal screen is large). Therefore, the ratio of the first count to the predetermined number is high. When the first ratio of the first frequency to the preset frequency is detected to be greater than the preset ratio threshold, the terminal can be considered to be in the left-hand single-hand operation mode.
If the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, and the identification numbers of the pressure sensors with the output values on the right frame are also detected to be continuous; or the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the identification numbers of the pressure sensors with the output values on the right frame are not continuous, so that the terminal can execute other operations no matter whether the first proportion value is larger than the preset proportion threshold value or not.
For another example, after determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset second area, and calculate a second ratio value between the second number and the preset number. For example, after determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset right half screen, and calculate a second ratio value between the second number and a preset 20 number.
Then, the terminal may detect whether the second ratio value is greater than a preset ratio threshold.
If the second proportion value is detected to be larger than the preset proportion threshold value, and the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, and the identification numbers of the pressure sensors with the output values on the left frame are detected to be discontinuous, the terminal can determine that the terminal is in a right-hand single-hand operation mode.
For example, the terminal detects that the touch position belongs to 17 touch operations of the preset right half screen in 20 touch operations, and then the second ratio value is 85%. For example, the preset proportion threshold is 80%. Then the second ratio value is greater than the preset ratio threshold. In this case, if it is detected that the identification numbers of the pressure sensors having output values on the right frame are kept continuous and the identification numbers of the pressure sensors having output values on the left frame are not continuous, the terminal may determine that the terminal is in the right-hand one-handed operation mode.
It can be understood that when the user operates the terminal with one hand using the right hand, the touch operation is generally performed with the thumb of the right hand, and when the touch operation is performed with the thumb of the right hand, the touch position corresponding to the touch operation is biased to the right side (especially when the terminal screen is large). Therefore, the ratio of the second number to the predetermined number is high. When the second ratio value of the second frequency to the preset frequency is detected to be greater than the preset ratio threshold, the terminal can be considered to be in the right-hand one-hand operation mode.
If the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, and the identification numbers of the pressure sensors with the output values on the right frame are also detected to be continuous; or the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the identification numbers of the pressure sensors with the output values on the right frame are not continuous, the terminal can execute other operations no matter whether the second proportion value is larger than the preset proportion threshold value or not.
In another implementation, the embodiment of the present invention may further include the following steps:
and the terminal respectively acquires the pressure output values of the pressure sensors on the left frame and the right frame, and respectively calculates a first average pressure output value corresponding to the left frame and a second average pressure output value corresponding to the right frame according to the pressure output values.
If the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, the first average pressure output value is larger than the second average pressure output value, the terminal determines that the stressed areas on the left frame are continuously distributed, the stressed areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
If the identification number of the pressure sensor with the output value on the right frame is detected to be continuous, the identification number of the pressure sensor with the output value on the left frame is detected to be discontinuous, the second average pressure output value is larger than the first average pressure output value, the terminal determines that the stress area on the right frame is continuously distributed, the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a right-hand single-hand operation mode.
For example, after detecting whether the identification numbers of the pressure sensors having output values on the left frame and the right frame of the terminal are continuous, the terminal may further obtain the output values of the pressure sensors on the left frame and the output values of the pressure sensors on the right frame of the terminal.
Then, the terminal can calculate a first average pressure output value corresponding to the left frame according to the output values of the pressure sensors on the left frame. Meanwhile, the terminal can calculate a second average pressure output value corresponding to the right frame according to the output values of the pressure sensors on the right frame.
For example, if there are 14 pressure sensors on the left frame having output values, the terminal may obtain the output values of the 14 pressure sensors and calculate the sum of the output values of the 14 pressure sensors. For example, if the sum of the output values of the 14 pressure sensors is 140 newtons (N), then the first average pressure output value for the left frame is 140/30= 4.67N.
And 6 pressure sensors on the right frame have output values, the terminal can acquire the output values of the 6 pressure sensors and calculate the sum of the output values of the 6 pressure sensors. For example, the sum of the output values of these 6 pressure sensors is 50 newtons (N), and the second average pressure output value corresponding to the right frame is 50/30= 1.67N.
Under the condition that the first average pressure output value is larger than the second average pressure output value, if the identification numbers of the pressure sensors with the output values on the left frame are kept continuous, and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous, the terminal can determine that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a left-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand, the interface between the palm of the user's left hand and the left rim will take up most of the weight of the terminal, whereas the interface between the fingers of the left hand and the right rim generally serves only as an auxiliary support. Therefore, the output value of the pressure sensor of the left frame of the terminal is larger, and the output value of the pressure sensor of the right frame is smaller. That is, the first average pressure output value is greater than the second average pressure output value.
For example, 12 pressure sensors on the right frame have output values, and the terminal may acquire the output values of the 12 pressure sensors and calculate the sum of the output values of the 12 pressure sensors. For example, if the sum of the output values of the 12 pressure sensors is 155 newtons (N), the second average pressure output value corresponding to the right frame is 155/30= 5.167N.
And 6 pressure sensors on the left frame have output values, the terminal can acquire the output values of the 6 pressure sensors and calculate the sum of the output values of the 6 pressure sensors. For example, the sum of the output values of these 6 pressure sensors is 55 newtons (N), and the first average pressure output value corresponding to the left frame is 55/30= 1.83N.
Under the condition that the second average pressure output value is larger than the first average pressure output value, if the identification number of the pressure sensor with the output value on the right frame keeps continuous, and the identification number of the pressure sensor with the output value on the left frame is discontinuous, the terminal can determine that the stress area on the right frame is continuously distributed, and the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a right-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by a user with one hand in the right hand, the contact surface between the palm of the user's right hand and the right rim bears most of the weight of the terminal, while the contact surface between the fingers of the right hand and the left rim generally only serves as an auxiliary support. Therefore, the output value of the pressure sensor on the right frame of the terminal is larger, and the output value of the pressure sensor on the left frame is smaller. That is, the second average pressure output value is greater than the first average pressure output value.
Under the condition that the first average pressure output value is larger than the second average pressure output value, if the identification number of the pressure sensor with the output value on the left frame is discontinuous, and the identification number of the pressure sensor with the output value on the right frame is continuous; or the identification numbers of the pressure sensors with the output values on the left frame are continuous, and the identification numbers of the pressure sensors with the output values on the right frame are continuous; or the identification number of the pressure sensor having the output value on the left frame is not continuous and the identification number of the pressure sensor having the output value on the right frame is not continuous, the terminal may perform other operations.
In another implementation, the embodiment of the present invention may further include the following steps:
and acquiring an output value of the gyroscope, and determining the posture of the terminal held by the user according to the output value of the gyroscope.
And judging whether the horizontal height of the left frame of the terminal is higher than that of the right frame or not according to the posture.
And if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, the horizontal height of the left frame of the terminal is lower than the horizontal height of the right frame, stress areas on the left frame are determined to be distributed continuously, the stress areas on the right frame comprise a plurality of sub-areas distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
And if the identification number of the pressure sensor with the output value on the right frame is detected to be continuous, the identification number of the pressure sensor with the output value on the left frame is detected to be discontinuous, and the horizontal height of the left frame of the terminal is higher than that of the right frame, determining that the stress area on the right frame is continuously distributed, the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
For example, after detecting whether the identification numbers of the pressure sensors having the output values on the left frame and the right frame of the terminal are continuous, the terminal may further acquire the output value of a gyroscope (sensor), and determine the posture of the terminal held by the user according to the output value of the gyroscope. Then, the terminal may determine whether the horizontal height of the left frame is higher than the horizontal height of the right frame according to the posture.
Under the condition that the horizontal height of the left frame is lower than that of the right frame, if the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous, the terminal can determine that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a left-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand in the left hand, the screen of the terminal will generally be directed laterally to the user, and therefore the level of the left frame will generally be lower than the level of the right frame.
Under the condition that the horizontal height of the right frame is lower than that of the left frame, if the identification numbers of the pressure sensors with the output values on the right frame are kept continuous and the identification numbers of the pressure sensors with the output values on the left frame are discontinuous, the terminal can determine that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a right-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand in the right hand, the screen of the terminal will typically be directed laterally to the user, and therefore the level of the right frame will typically be lower than the level of the left frame.
In another embodiment, the terminal may further cooperate with a gyroscope sensor to detect whether the terminal is in a left-hand single-handed operation mode or a right-hand single-handed operation mode.
It should be noted that when the user operates the terminal with one hand in the left hand, the terminal is generally tilted to the left side, and when the user operates the terminal with one hand in the right hand, the terminal is generally tilted to the right side. Because the gyroscope sensor can detect the deflection angle of the terminal, the angular deflection range of the terminal when the user operates the terminal with one hand at the left hand can be tested in advance. Then, the terminal can determine a preset first value and a preset first range corresponding to the gyroscope in the left-handed single-handed operation according to the deflection range. Then, when the output value of the gyroscope is within the preset first range of the preset first numerical value, if it is detected that the identification numbers of the pressure sensors having the output values on the left frame are continuous and the identification numbers of the pressure sensors having the output values on the right frame are discontinuous, the terminal can determine that the terminal is in the left-hand single-hand operation mode.
Similarly, the terminal may also pre-test the angular deflection range of the terminal that occurs when the user operates the terminal with one hand on the right hand. Then, the terminal can determine a preset second value and a preset second range corresponding to the gyroscope operated by the right hand with one hand according to the deflection range. Then, when the output value of the gyroscope is within the preset second range of the preset second numerical value, if it is detected that the identification numbers of the pressure sensors having the output values on the right frame are continuous and the identification numbers of the pressure sensors having the output values on the left frame are discontinuous, the terminal may determine that the terminal is in the right-hand one-handed operation mode.
In some embodiments, the terminal may set a virtual key bar at the bottom of the screen, where the virtual key bar generally includes an option key, a main screen key, and a return key. The return key is used for returning to the upper level interface, and is a key most frequently used by a user. However, in the case where the terminal screen is large and the user operates the terminal with one hand, if the return key is provided on the side away from the hand of the user for operating the terminal, it is difficult for the user to press the return key. For example, if the user operates the terminal with one hand in the left hand and the return key is provided on the right side of the virtual key bar (the bottom right side of the screen), the user's left thumb would have difficulty pressing the return key in the case where the terminal screen is large.
In one embodiment, after determining whether the terminal is in the left-hand single-handed operation mode or the right-hand single-handed operation mode, the terminal may further detect whether a return key at the bottom of the terminal is located near a side of a hand of the user holding the terminal. For example, if it is determined that the terminal is in a left-handed single-handed operation mode, i.e., the user operates the terminal with a left-handed single hand, the terminal may detect whether the return key is located on the left side of the virtual key bar. If not, the terminal may set the return key in the virtual key bar to the left. If so, the terminal may perform other operations.
In one embodiment, a single-hand operation test of the user may be performed in advance, and a touch position corresponding to a touch operation performed when the user operates the terminal with one hand may be recorded during the test. For example, the terminal may record the touch positions corresponding to 20 touch operations when each user operates the terminal with one hand in the left hand, and count the number of times that the touch positions belong to the left half screen of the terminal screen, thereby calculating a ratio of the number of times that the touch positions are located in the left half screen to the total number of times that the touch operations are 20 times when the user operates the terminal with one hand in the left hand.
After obtaining data of a plurality of proportion values, the terminal can analyze and learn the data of the proportion values through a certain learning algorithm, further calculate a target proportion value, and determine the target proportion value as a preset proportion threshold value. The preset proportional threshold may be used for the terminal to determine the one-handed operation mode. For example, the terminal may record a touch position corresponding to each touch operation in the preset number of touch operations. Then, the terminal may determine a touch area to which each touch position belongs, where the touch area includes a preset first area and a preset second area, and the preset first area and the preset second area constitute a touch screen area of the terminal. Then, the terminal may count a first number of times of touch operations in which the touch area is the preset first area, and calculate a first ratio value between the first number of times and the preset number of times. If the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, and the first proportion value is larger than the preset proportion threshold value, the terminal can determine that the terminal is in a left-hand single-hand operation mode.
Referring to fig. 7A to 7B, fig. 7A to 7B are schematic views illustrating a scenario of an operation mode determining method according to an embodiment of the present invention.
For example, the terminal is provided with 30 pressure sensors in sequence along the left frame, and the identification numbers assigned to the 30 pressure sensors are 1, 2, 3, … …, 28, 29, 30 respectively in order from the top to the bottom of the terminal, as shown in fig. 5. Wherein the identification numbers of the pressure sensors located adjacently are numerically consecutive. For example, the pressure sensor a1 and the pressure sensor a2 are disposed adjacently, and the identification number 1 of the pressure sensor a1 and the identification number 2 of the pressure sensor a2 are numerically continuous. As another example, the pressure sensor a2 and the pressure sensor a3 are disposed adjacently, and the identification number 2 of the pressure sensor a2 and the identification number 3 of the pressure sensor a3 are consecutive in numerical value.
The terminal is also provided with 30 pressure sensors in turn along the right frame, and the identification numbers assigned to the 30 pressure sensors are 31, 32, 33, … …, 58, 59, 60 respectively in order from the top to the bottom of the terminal, as shown in fig. 5. Wherein the identification numbers of the pressure sensors located adjacently are numerically consecutive. For example, the pressure sensor b28 and the pressure sensor b29 are disposed adjacently, and the identification number 58 of the pressure sensor b28 and the identification number 59 of the pressure sensor b29 are numerically continuous. For another example, the pressure sensor b29 and the pressure sensor b30 are disposed adjacently, and the identification number 59 of the pressure sensor b29 and the identification number 60 of the pressure sensor b30 are consecutive in value.
As shown in fig. 7A, when the operation by the user is detected, the terminal may determine the pressure sensor having the output value on the left frame, and then obtain the identification number of the pressure sensor having the output value on the left frame. For example, the terminal determines that the pressure sensors having output values on the left frame are a16, a17, a19, a20, a22 and a23, and then the terminal may sequentially acquire the identification numbers of the pressure sensors a16, a17, a19, a20, a22 and a 23. For example, the identification numbers acquired by the terminal are 16, 17, 19, 20, 22 and 23.
Then, the terminal may determine the pressure sensor having the output value on the right frame thereof, and then obtain the identification number of the pressure sensor having the output value on the right frame. For example, the terminal determines that the pressure sensors having output values on the right frame are from b17 through b26, and then the terminal may sequentially acquire the identification numbers of these pressure sensors. For example, the terminal acquires the identification numbers 47, 48, 59, … …, 54, 55, 56.
Then, the terminal may detect whether the identification numbers of the pressure sensors having the output values on the left frame acquired by the terminal are kept continuous, and detect whether the identification numbers of the pressure sensors having the output values on the right frame acquired by the terminal are kept continuous. For example, the terminal detects that the identification numbers of the pressure sensors having output values on the left frame are not continuous, while the identification numbers of the pressure sensors having output values on the right frame remain continuous.
In this case, the terminal may further record a touch position corresponding to each touch operation in the next 20 touch operations. The terminal may then determine the touch area to which each touch location belongs. The touch area may include a preset first area and a preset second area. The touch screen area of the terminal may be composed of the preset first area and the preset second area. For example, the preset first area may be a left half screen of the touch screen, and the preset second area may be a right half screen of the touch screen. Then, the terminal may determine whether each touch position belongs to the left half screen or the right half screen.
After determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset second area, and calculate a second ratio value between the second number and the preset number. For example, after determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset right half screen, and calculate a second ratio value between the second number and a preset 20 number.
Then, the terminal may detect whether the second ratio value is greater than a preset ratio threshold. For example, as shown in fig. 7B, the dotted line in fig. 7B is a boundary between the left half screen and the right half screen, the gray circle represents a touch position of the touch operation, and the terminal detects that the touch position belongs to the preset right half screen for 19 times of the 20 touch operations, so that the first ratio is 95%. For example, the preset proportion threshold is 80%. Then the second ratio value is greater than the preset ratio threshold.
In this case, the terminal may determine that the terminal is in a right-handed one-handed operation mode. That is, when it is detected that the identification number of the pressure sensor having the output value on the left frame is not continuous, and the identification number of the pressure sensor having the output value on the right frame is kept continuous, and the second ratio value is greater than the preset ratio threshold, the terminal may determine that the terminal is in the right-hand one-hand operation mode.
Referring to fig. 8, fig. 8 is a schematic structural diagram of an operation mode determination device according to an embodiment of the present invention. The operation mode determining apparatus may be applied to a terminal, and in an embodiment, the operation mode determining apparatus 300 may include: a first obtaining module 301, a first determining module 302, and a second determining module 303.
A first obtaining module 301, configured to, when it is detected that the terminal is operated, respectively obtain first stress information of a left frame and second stress information of a right frame of the terminal.
For example, when detecting that the terminal is operated, the first obtaining module 301 may obtain stress information of a left frame (i.e., first stress information) and stress information of a right frame (i.e., second stress information).
Then, the terminal may detect that the stressed areas on the left frame are distributed continuously or that the stressed areas on the left frame include a plurality of sub-areas distributed at intervals according to the first stress information. And the terminal can detect that the stressed areas on the right frame are continuously distributed or that the stressed areas on the right frame comprise a plurality of sub-areas distributed at intervals according to the second stressed information.
If it is detected that the stressed areas on the left frame are continuously distributed according to the first stress information and the stressed areas on the right frame are continuously distributed according to the second stress information, the terminal may perform other operations.
If the stressed area on the left frame is detected to comprise a plurality of sub-areas distributed at intervals according to the first stress information, and the stressed area on the right frame is detected to comprise a plurality of sub-areas distributed at intervals according to the second stress information, the terminal can also execute other operations.
A first determining module 302, configured to determine that the terminal is in a left-hand single-hand operation mode if it is detected that the stressed areas on the left frame are continuously distributed according to the first stress information and it is detected that the stressed area on the right frame includes a plurality of sub-areas that are distributed at intervals according to the second stress information.
For example, the terminal detects that the stressed areas on the left frame are continuously distributed according to the first stressed information of the left frame, that is, the stressed area on the left frame is a complete single area. And the terminal detects that the stressed area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the second stressed information of the right frame, namely that the stressed area on the right frame comprises a plurality of sub-areas which are distributed at intervals (namely, are not communicated with each other). Then, in this case, the first determining module 302 may determine that the terminal is in the left-handed single-handed operation mode (i.e., the user operates the terminal with the left hand and the single hand).
When the user operates the terminal with one hand with the left hand, the contact surface (portion) between the palm of the left hand of the user and the left frame of the terminal is a continuous surface. Thus, the force-bearing area on the left frame is a continuously distributed, complete single area. The user's left finger and the terminal right frame have multiple contact surfaces, and the multiple contact surfaces are generally spaced. Therefore, the force-receiving area on the right frame may include a plurality of sub-areas that are spaced apart.
A second determining module 303, configured to determine that the terminal is in a right-hand single-hand operation mode if it is detected that the stressed area on the left frame includes multiple sub-areas distributed at intervals according to the first stress information, and it is detected that the stressed area on the right frame is continuously distributed according to the second stress information.
For example, the terminal detects that the stressed area on the left frame includes a plurality of sub-areas distributed at intervals according to the first stress information of the left frame, that is, the stressed area on the left frame is composed of a plurality of sub-areas distributed at intervals (that is, not connected to each other). And the terminal detects that the stress area on the right frame is continuously distributed according to the second stress information of the right frame, namely the stress area on the right frame is a complete single area. In this case, then, the second determining module 303 may determine that the terminal is in the right-handed one-handed operation mode (i.e., the user operates the terminal with the right-handed one-handed operation).
When the user operates the terminal with one hand, the contact surface (portion) between the palm of the user's right hand and the right frame of the terminal is a continuous surface. Thus, the force-bearing area on the right frame is a continuously distributed, complete single area. The user's right finger and the left frame of the terminal will have multiple contact surfaces, which are typically spaced apart. Thus, the force-bearing area on the left frame will include a plurality of sub-areas spaced apart.
In one embodiment, the left and right rims of the terminal may each include a plurality of pressure sensors.
The first obtaining module 301 may be configured to: and acquiring information of pressure sensors with output values on a left frame and a right frame of the terminal, wherein the information of the pressure sensors with the output values on the left frame is used for representing first stress information, and the information of the pressure sensors with the output values on the right frame is used for representing second stress information.
The first determination module 302 may be configured to: and if the continuous distribution of the stress area on the left frame is detected according to the information of the pressure sensor with the output value on the left frame, and the stress area on the right frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a left-hand single-hand operation mode.
The second determining module 303 may be configured to: and if the stressed area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the left frame, and the stressed area on the right frame is continuously distributed according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a right-hand single-hand operation mode.
For example, upon detecting that the terminal is operated, the terminal may acquire information of a pressure sensor having an output value on the left frame and acquire information of a pressure sensor having an output value on the right frame. The information of the pressure sensor having the output value on the left frame may represent first stress information of the left frame. And the information of the pressure sensor having the output value on the right frame may represent second stress information of the right frame.
Then, the terminal may detect whether the stressed areas on the left frame are continuously distributed according to the information of the pressure sensor having the output value on the left frame, and detect whether the stressed areas on the right frame are continuously distributed according to the information of the pressure sensor having the output value on the right frame.
If it is detected that the stressed area on the left frame is continuously distributed according to the information of the pressure sensor with the output value on the left frame, and it is detected that the stressed area on the right frame includes a plurality of sub-areas distributed at intervals according to the information of the pressure sensor with the output value on the right frame, the first determining module 302 determines that the terminal is in the left-hand single-hand operation mode.
If it is detected that the stressed area on the left frame includes a plurality of sub-areas distributed at intervals according to the information of the pressure sensor having the output value on the left frame, and if it is detected that the stressed area on the right frame is continuously distributed according to the information of the pressure sensor having the output value on the right frame, the second determining module 303 determines that the terminal is in the right-hand one-hand operation mode.
In one embodiment, each of the pressure sensors on the left and right frames of the terminal is assigned a corresponding identification number, and the identification numbers of adjacent pressure sensors are consecutive in value.
Then, the first obtaining module 301 may be configured to: and respectively acquiring identification numbers of pressure sensors with output values on the left frame and the right frame of the terminal.
The first determination module 302 may be configured to: and if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous is detected, the fact that the stress areas on the left frame are distributed continuously is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the terminal is in a left-hand single-hand operation mode is determined.
The second determining module 303 may be configured to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, and the identification numbers of the pressure sensors with the output values on the left frame are not continuous, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
For example, the first obtaining module 301 may first obtain the identification numbers of the pressure sensors with output values on the left frame and the right frame of the terminal, respectively.
Then, the terminal may detect whether the identification numbers of the pressure sensors having the output values on the left frame are kept continuous, and detect whether the identification numbers of the pressure sensors having the output values on the right frame are kept continuous.
If it is detected that the identification numbers of the pressure sensors with output values on the left frame are continuous and the identification numbers of the pressure sensors with output values on the right frame are discontinuous, the first determining module 302 may determine that the stressed areas on the left frame are continuously distributed and the stressed areas on the right frame include a plurality of sub-areas which are distributed at intervals, and determine that the terminal is in the left-hand single-hand operation mode.
If it is detected that the identification numbers of the pressure sensors with the output values on the right frame are kept continuous and the identification numbers of the pressure sensors with the output values on the left frame are not continuous, the second determining module 303 determines that the stressed areas on the right frame are continuously distributed, and the stressed areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determines that the terminal is in a right-hand single-hand operation mode.
In one embodiment, the first obtaining module 301 may further be configured to: a first number of pressure sensors having output values on the left frame and a second number of pressure sensors having output values on the right frame are obtained.
Then, the first determination module 302 may be configured to: and if the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, and the first number is greater than the second number, the stress areas on the left frame are determined to be continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
The second determining module 303 may be configured to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second number is greater than the first number, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
For example, after acquiring the identification number corresponding to the pressure sensor having the output value on the left frame and the identification number of the pressure sensor having the output value on the right frame, the first acquiring module 301 may further acquire the number of the pressure sensors having the output value on the left frame, that is, the first number, and the number of the pressure sensors having the output value on the right frame, that is, the second number.
Then, the terminal may detect whether the identification numbers of the pressure sensors having the output values on the left frame acquired by the terminal are kept continuous, and detect whether the identification numbers of the pressure sensors having the output values on the right frame acquired by the terminal are kept continuous.
Meanwhile, the terminal may also detect whether the first number is greater than the second number.
If it is detected that the identification numbers of the pressure sensors having output values on the left frame are kept continuous and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the terminal may obtain the comparison result of the first number and the second number.
If the first number is greater than the second number, the first determining module 302 may determine that the terminal is in a left-handed single-handed operation mode.
If it is detected that the identification numbers of the pressure sensors having output values on the right frame are kept continuous and the identification numbers of the pressure sensors having output values on the left frame are not continuous, the terminal can also obtain the comparison result of the first number and the second number.
If the second number is greater than the first number, the second determining module 302 may determine that the terminal is in the right-handed one-handed operation mode.
Referring to fig. 9, fig. 9 is another schematic structural diagram of the operation mode determining apparatus according to the embodiment of the present invention. In an embodiment, the operation mode determining apparatus 300 may further include: a recording module 304, a second acquisition module 305, and a third acquisition module 306.
The recording module 304 is configured to: recording a touch position corresponding to each touch operation in the preset times of touch operations; determining a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the terminal; counting a first frequency of touch operation of a touch area in the preset first area, and calculating a first proportional value of the first frequency and the preset frequency; counting a second frequency of touch operation of a touch area in the preset second area, and calculating a second proportional value of the second frequency and the preset frequency;
the first determination module 302 may be configured to: and if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than a preset proportion threshold value, determining that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a left-hand single-hand operation mode.
The second determining module 303 may be configured to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is greater than a preset proportion threshold value, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
For example, the terminal may record a touch position corresponding to each touch operation in the preset 20 touch operations. The terminal may then determine the touch area to which each touch location belongs. The touch area may include a preset first area and a preset second area. The touch screen area of the terminal may be composed of the preset first area and the preset second area. For example, the preset first area may be a left half screen of the touch screen, and the preset second area may be a right half screen of the touch screen. Then, the terminal may determine whether each touch position belongs to the left half screen or the right half screen.
After determining the touch area to which each touch position belongs, the terminal may count a first number of times of touch operations in which the touch area is a preset first area, and calculate a first ratio value between the first number of times and the preset number of times. For example, after determining the touch area to which each touch position belongs, the terminal may count a first number of times of touch operations of the left half-screen of which the touch area is a preset number, and calculate a first ratio value between the first number of times and a preset number of 20 times.
Then, the terminal may detect whether the first ratio value is greater than a preset ratio threshold.
If it is detected that the first ratio is greater than the preset ratio threshold, and it is detected that the identification numbers of the pressure sensors with output values on the left frame are continuous, and the identification numbers of the pressure sensors with output values on the right frame are discontinuous, the first determining module 302 may determine that the terminal is in the left-handed single-handed operation mode.
For example, the terminal detects that the touch position belongs to the preset touch operation of the left half screen for 18 times in 20 touch operations, and then the first ratio is 90%. For example, the preset proportion threshold is 80%. Then, the first scale value is greater than the preset scale threshold. In this case, if it is detected that the identification numbers of the pressure sensors having output values on the left frame are kept continuous and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the first determining module 302 may determine that the terminal is in the left-handed single-handed operation mode.
It can be understood that when the user operates the terminal with one hand using the left hand, the touch operation is generally performed with the left thumb, and when the touch operation is performed with the left thumb, the touch position corresponding to the touch operation is biased to the left (especially when the terminal screen is large). Therefore, the ratio of the first count to the predetermined number is high. When the first ratio of the first frequency to the preset frequency is detected to be greater than the preset ratio threshold, the terminal can be considered to be in the left-hand single-hand operation mode.
For another example, after determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset second area, and calculate a second ratio value between the second number and the preset number. For example, after determining the touch area to which each touch position belongs, the terminal may count a second number of touch operations of which the touch area is a preset right half screen, and calculate a second ratio value between the second number and a preset 20 number.
Then, the terminal may detect whether the second ratio value is greater than a preset ratio threshold.
If it is detected that the second ratio value is greater than the preset ratio threshold, and it is detected that the identification numbers of the pressure sensors having the output values on the right frame are kept continuous, and the identification numbers of the pressure sensors having the output values on the left frame are not continuous, the second determining module 303 may determine that the terminal is in the right-hand one-hand operation mode.
For example, the terminal detects that the touch position belongs to 17 touch operations of the preset right half screen in 20 touch operations, and then the second ratio value is 85%. For example, the preset proportion threshold is 80%. Then the second ratio value is greater than the preset ratio threshold. In this case, if it is detected that the identification numbers of the pressure sensors having output values on the right frame are kept continuous and the identification numbers of the pressure sensors having output values on the left frame are not continuous, the second determining module 303 may determine that the terminal is in the right-hand one-handed operation mode.
It can be understood that when the user operates the terminal with one hand using the right hand, the touch operation is generally performed with the thumb of the right hand, and when the touch operation is performed with the thumb of the right hand, the touch position corresponding to the touch operation is biased to the right side (especially when the terminal screen is large). Therefore, the ratio of the second number to the predetermined number is high. When the second ratio value of the second frequency to the preset frequency is detected to be greater than the preset ratio threshold, the terminal can be considered to be in the right-hand one-hand operation mode.
The second obtaining module 305 is configured to: and respectively acquiring the pressure output values of the pressure sensors on the left frame and the right frame, and respectively calculating a first average pressure output value corresponding to the left frame and a second average pressure output value corresponding to the right frame according to the pressure output values.
Then, the first obtaining module 302 may be configured to: and if the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, the first average pressure output value is larger than the second average pressure output value, the stress areas on the left frame are determined to be continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
The second determination module 303 may be configured to: and if the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are detected to be discontinuous, the second average pressure output value is larger than the first average pressure output value, the stress areas on the right frame are determined to be continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a right-hand single-hand operation mode.
For example, after detecting whether the identification numbers of the pressure sensors having output values on the left frame and the right frame of the terminal are continuous, the second obtaining module 305 may further obtain the output values of the pressure sensors on the left frame and the output values of the pressure sensors on the right frame of the terminal.
Then, the second obtaining module 305 may calculate a first average pressure output value corresponding to the left frame according to the output values of the pressure sensors on the left frame. Meanwhile, the second obtaining module 305 may calculate a second average pressure output value corresponding to the right frame according to the output value of each pressure sensor on the right frame.
For example, if there are 14 pressure sensors on the left frame having output values, the terminal may obtain the output values of the 14 pressure sensors and calculate the sum of the output values of the 14 pressure sensors. For example, if the sum of the output values of the 14 pressure sensors is 140 newtons (N), then the first average pressure output value for the left frame is 140/30= 4.67N.
And 6 pressure sensors on the right frame have output values, the terminal can acquire the output values of the 6 pressure sensors and calculate the sum of the output values of the 6 pressure sensors. For example, the sum of the output values of these 6 pressure sensors is 50 newtons (N), and the second average pressure output value corresponding to the right frame is 50/30= 1.67N.
Under the condition that the first average pressure output value is greater than the second average pressure output value, if the identification numbers of the pressure sensors having output values on the left frame are kept continuous, and the identification numbers of the pressure sensors having output values on the right frame are not continuous, the first determining module 302 may determine that the stressed areas on the left frame are continuously distributed, and the stressed areas on the right frame include a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a left-hand one-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand, the interface between the palm of the user's left hand and the left rim will take up most of the weight of the terminal, whereas the interface between the fingers of the left hand and the right rim generally serves only as an auxiliary support. Therefore, the output value of the pressure sensor of the left frame of the terminal is larger, and the output value of the pressure sensor of the right frame is smaller. That is, the first average pressure output value is greater than the second average pressure output value.
For example, 12 pressure sensors on the right frame have output values, and the terminal may acquire the output values of the 12 pressure sensors and calculate the sum of the output values of the 12 pressure sensors. For example, if the sum of the output values of the 12 pressure sensors is 155 newtons (N), the second average pressure output value corresponding to the right frame is 155/30= 5.167N.
And 6 pressure sensors on the left frame have output values, the terminal can acquire the output values of the 6 pressure sensors and calculate the sum of the output values of the 6 pressure sensors. For example, the sum of the output values of these 6 pressure sensors is 55 newtons (N), and the first average pressure output value corresponding to the left frame is 55/30= 1.83N.
Under the condition that the second average pressure output value is greater than the first average pressure output value, if the identification number of the pressure sensor with the output value on the right frame is kept continuous, and the identification number of the pressure sensor with the output value on the left frame is not continuous, the second determining module 303 may determine that the stressed area on the right frame is continuously distributed, and the stressed area on the left frame includes a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in the right-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by a user with one hand in the right hand, the contact surface between the palm of the user's right hand and the right rim bears most of the weight of the terminal, while the contact surface between the fingers of the right hand and the left rim generally only serves as an auxiliary support. Therefore, the output value of the pressure sensor on the right frame of the terminal is larger, and the output value of the pressure sensor on the left frame is smaller. That is, the second average pressure output value is greater than the first average pressure output value.
The third obtaining module 306 is configured to: and acquiring an output value of the gyroscope, and determining the posture of the terminal held by the user according to the output value of the gyroscope. And judging whether the horizontal height of the left frame of the terminal is higher than that of the right frame or not according to the posture.
Then the first determination module 302 may be configured to: and if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, the horizontal height of the left frame of the terminal is lower than the horizontal height of the right frame, stress areas on the left frame are determined to be distributed continuously, the stress areas on the right frame comprise a plurality of sub-areas distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode.
The second determination module 303 may be configured to: and if the identification number of the pressure sensor with the output value on the right frame is detected to be continuous, the identification number of the pressure sensor with the output value on the left frame is detected to be discontinuous, and the horizontal height of the left frame of the terminal is higher than that of the right frame, determining that the stress area on the right frame is continuously distributed, the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
For example, after detecting whether the identification numbers of the pressure sensors having output values on the left frame and the right frame of the terminal are continuous, the third obtaining module 306 may further obtain the output value of a gyroscope (sensor), and determine the gesture of the terminal held by the user according to the output value of the gyroscope. Then, the third obtaining module 306 may determine whether the horizontal height of the left frame is higher than the horizontal height of the right frame according to the gesture.
Under the condition that the horizontal height of the left frame is lower than that of the right frame, if the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous, the first determining module 302 may determine that the stressed areas on the left frame are continuously distributed and the stressed areas on the right frame include a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a left-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand in the left hand, the screen of the terminal will generally be directed laterally to the user, and therefore the level of the left frame will generally be lower than the level of the right frame.
Under the condition that the horizontal height of the right frame is lower than that of the left frame, if the identification numbers of the pressure sensors with the output values on the right frame are kept continuous and the identification numbers of the pressure sensors with the output values on the left frame are not continuous, the second determining module 303 may determine that the stress areas on the right frame are continuously distributed and the stress areas on the left frame include a plurality of sub-areas which are distributed at intervals, and further determine that the terminal is in a right-hand single-hand operation mode.
It will be appreciated that when the terminal is operated by the user with one hand in the right hand, the screen of the terminal will typically be directed laterally to the user, and therefore the level of the right frame will typically be lower than the level of the left frame.
Embodiments of the present invention provide a computer-readable storage medium on which a computer program is stored, which, when executed on a computer, causes the computer to execute an operation mode determination method provided by an embodiment of the present invention.
The embodiment of the invention also provides electronic equipment which comprises a memory, a processor and pressure sensors, wherein the left frame and the right frame of the electronic equipment are respectively provided with the plurality of pressure sensors, and the processor is used for executing the operation mode determining method provided by the embodiment of the invention by calling the computer program stored in the memory.
Referring to fig. 10, fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the invention.
The mobile electronic device 400 may include components such as a memory 401, a processor 402, and the like. Those skilled in the art will appreciate that the mobile electronic device configuration shown in fig. 10 does not constitute a limitation of the mobile electronic device and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components.
The memory 401 may be used to store applications and data. The memory 401 stores applications containing executable code. The application programs may constitute various functional modules. The processor 402 executes various functional applications and data processing by running an application program stored in the memory 401.
The processor 402 is a control center of the mobile electronic device, connects various parts of the entire mobile electronic device using various interfaces and lines, and performs various functions of the mobile electronic device and processes data by running or executing an application program stored in the memory 401 and calling data stored in the memory 401, thereby performing overall monitoring of the mobile electronic device.
In this embodiment, the processor 402 in the mobile electronic device may, by calling a computer program stored in the memory 401, perform:
when the electronic equipment is detected to be operated, first stress information of a left frame and second stress information of a right frame of the electronic equipment are respectively obtained.
And if the stress areas on the left frame are detected to be continuously distributed according to the first stress information and the stress areas on the right frame are detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stress information, determining that the electronic equipment is in a left-hand single-hand operation mode.
And if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is continuously distributed according to the second stress information, determining that the electronic equipment is in a right-hand single-hand operation mode.
In addition, referring to fig. 11, the mobile electronic device 400 may further include an input unit 404, an output unit 405, and a pressure sensor 406.
The input unit 404 may be used to receive input numbers, character information, or user characteristic information, such as a fingerprint, and generate keyboard, mouse, joystick, optical, or trackball signal inputs related to user settings and function control. In an embodiment, the input unit 404 may include a touch-sensitive surface as well as other input devices. Touch sensitive surfaces, also known as touch display screens or touch pads.
The output unit 405 may be used to display information input by or provided to a user and various graphical user interfaces of the mobile electronic device, which may be made up of graphics, text, icons, video, and any combination thereof. The output unit may include a display panel.
The pressure sensor 406 is a sensor that can convert pressure into an electrical signal output. Pressure sensors are generally composed of a spring-sensitive element and a displacement-sensitive element.
In one embodiment, the left and right frames of the electronic device each include a plurality of pressure sensors, and the processor 402 performs: and acquiring information of pressure sensors with output values on a left frame and a right frame of the electronic equipment, wherein the information of the pressure sensors with the output values on the left frame is used for representing first stress information, and the information of the pressure sensors with the output values on the right frame is used for representing second stress information. And if the continuous distribution of the stress area on the left frame is detected according to the information of the pressure sensor with the output value on the left frame, and the stress area on the right frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the right frame, determining that the electronic equipment is in a left-hand single-hand operation mode. And if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the left frame and the stress area on the right frame is continuously distributed according to the information of the pressure sensor with the output value on the right frame, determining that the electronic equipment is in a right-hand single-hand operation mode.
In one embodiment, each of the pressure sensors on the left and right frames is assigned a corresponding identification number, and the identification numbers of adjacent pressure sensors are consecutive in value, and the processor 402 performs the following steps: and respectively acquiring identification numbers of the pressure sensors with output values on the left frame and the right frame of the electronic equipment. And if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous is detected, the fact that the stress areas on the left frame are continuously distributed is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a left-hand single-hand operation mode is determined. And if the fact that the identification numbers of the pressure sensors with the output values on the right frame are kept continuous and the identification numbers of the pressure sensors with the output values on the left frame are not continuous is detected, the fact that the stress areas on the right frame are continuously distributed is determined, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a right-hand single-hand operation mode is determined.
In one embodiment, processor 402 may perform: a first number of pressure sensors having output values on the left frame and a second number of pressure sensors having output values on the right frame are obtained. If the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, and the first number is larger than the second number, the stress areas on the left frame are determined to be continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the electronic equipment is determined to be in a left-hand single-hand operation mode. And if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second number is greater than the first number, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a right-hand single-hand operation mode.
In one embodiment, processor 402 may perform: and recording the touch position corresponding to each touch operation in the preset times of touch operations.
Determining a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the electronic equipment.
And counting a first frequency of touch operation of a touch area in the preset first area, and calculating a first proportional value of the first frequency and the preset frequency.
And counting a second frequency of touch operation of the touch area in the preset second area, and calculating a second proportional value of the second frequency and the preset frequency.
If the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than a preset proportion threshold value, it is determined that the stress areas on the left frame are distributed continuously, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and it is determined that the electronic equipment is in a left-hand single-hand operation mode.
If the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is larger than a preset proportion threshold value, the stress areas on the right frame are determined to be continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the electronic equipment is determined to be in a right-hand single-hand operation mode.
In one embodiment, processor 402 may perform: the method comprises the steps of obtaining an output value of a gyroscope, and determining the posture of the electronic equipment held by a user according to the output value of the gyroscope.
And judging whether the horizontal height of the left frame of the electronic equipment is higher than that of the right frame or not according to the posture.
And if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, the horizontal height of the left frame of the electronic equipment is lower than the horizontal height of the right frame, the fact that the stress areas on the left frame are distributed continuously is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a left-hand single-hand operation mode is determined.
And if the fact that the identification numbers of the pressure sensors with the output values on the right frame are kept continuous is detected, the identification numbers of the pressure sensors with the output values on the left frame are discontinuous, and the horizontal height of the left frame of the electronic equipment is higher than that of the right frame, determining that the stress areas on the right frame are continuously distributed, wherein the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a right-hand single-hand operation mode.
In the above embodiments, the descriptions of the embodiments have respective emphasis, and parts that are not described in detail in a certain embodiment may refer to the above detailed description of the operation mode determination method, and are not described herein again.
The operation mode determining apparatus provided in the embodiment of the present invention and the operation mode determining method in the above embodiments belong to the same concept, and any one of the methods provided in the embodiments of the operation mode determining method may be run on the operation mode determining apparatus, and a specific implementation process thereof is described in the embodiment of the operation mode determining method in detail, and is not described herein again.
It should be noted that, for the operation mode determining method according to the embodiment of the present invention, it can be understood by those skilled in the art that all or part of the process of implementing the operation mode determining method according to the embodiment of the present invention can be completed by controlling the relevant hardware through a computer program, where the computer program can be stored in a computer readable storage medium, such as a memory, and executed by at least one processor, and during the execution, the process of the embodiment of the operation mode determining method can be included as described above. The storage medium may be a magnetic disk, an optical disk, a Read Only Memory (ROM), a Random Access Memory (RAM), or the like.
For the operation mode determination apparatus according to the embodiment of the present invention, each functional module may be integrated into one processing chip, or each module may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware mode, and can also be realized in a software functional module mode. The integrated module, if implemented in the form of a software functional module and sold or used as a stand-alone product, may also be stored in a computer readable storage medium, such as a read-only memory, a magnetic or optical disk, or the like.
The foregoing describes in detail an operation mode determining method, apparatus, storage medium, and electronic device provided in the embodiments of the present invention, and specific examples are applied herein to explain the principles and implementations of the present invention, and the description of the foregoing embodiments is only used to help understand the method and the core idea of the present invention; meanwhile, for those skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.
Claims (20)
- An operation mode determination method, the method is suitable for a terminal, wherein the method comprises the following steps:when the terminal is detected to be operated, respectively acquiring first stress information of a left frame and second stress information of a right frame of the terminal;if the stress area on the left frame is detected to be continuously distributed according to the first stress information and the stress area on the right frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stress information, determining that the terminal is in a left-hand single-hand operation mode;and if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is continuously distributed according to the second stress information, determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 1, wherein each of left and right borders of the terminal includes a plurality of pressure sensors, the method comprising:acquiring information of pressure sensors with output values on a left frame and a right frame of the terminal, wherein the information of the pressure sensors with the output values on the left frame is used for representing first stress information, and the information of the pressure sensors with the output values on the right frame is used for representing second stress information;if the continuous distribution of the stress area on the left frame is detected according to the information of the pressure sensor with the output value on the left frame, and the stress area on the right frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a left-hand single-hand operation mode;and if the stressed area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the left frame, and the stressed area on the right frame is continuously distributed according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 2, wherein each of the pressure sensors on the left and right frames is assigned a corresponding identification number, and the identification numbers of the pressure sensors located adjacently are consecutive in value;the acquiring information of the pressure sensors with output values on the left frame and the right frame of the terminal comprises the following steps: respectively acquiring identification numbers of pressure sensors with output values on the left frame and the right frame of the terminal;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous is detected, the fact that stress areas on the left frame are distributed continuously is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the terminal is in a left-hand single-hand operation mode is determined;and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, and the identification numbers of the pressure sensors with the output values on the left frame are not continuous, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 3, wherein the method further comprises:acquiring a first number of pressure sensors with output values on the left frame and a second number of pressure sensors with output values on the right frame;if the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, and the first number is greater than the second number, the stress areas on the left frame are determined to be continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode;and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second number is greater than the first number, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 3, wherein the method further comprises:recording a touch position corresponding to each touch operation in the preset times of touch operations;determining a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the terminal;counting a first frequency of touch operation of a touch area in the preset first area, and calculating a first proportional value of the first frequency and the preset frequency;counting a second frequency of touch operation of a touch area in the preset second area, and calculating a second proportional value of the second frequency and the preset frequency;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than a preset proportion threshold value, it is determined that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode;and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is greater than a preset proportion threshold value, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 3, wherein the method further comprises:respectively obtaining pressure output values of each pressure sensor on the left frame and the right frame, and respectively calculating a first average pressure output value corresponding to the left frame and a second average pressure output value corresponding to the right frame according to the pressure output values;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first average pressure output value is larger than the second average pressure output value, it is determined that the stressed areas on the left frame are continuously distributed, the stressed areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode;and if the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are detected to be discontinuous, the second average pressure output value is larger than the first average pressure output value, the stress areas on the right frame are determined to be continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a right-hand single-hand operation mode.
- The operation mode determination method according to claim 3, wherein the method further comprises:acquiring an output value of a gyroscope, and determining the posture of the terminal held by a user according to the output value of the gyroscope;judging whether the horizontal height of the left frame of the terminal is higher than that of the right frame or not according to the posture;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the horizontal height of the left frame of the terminal is lower than that of the right frame, determining that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a left-hand single-hand operation mode;and if the identification number of the pressure sensor with the output value on the right frame is detected to be continuous, the identification number of the pressure sensor with the output value on the left frame is detected to be discontinuous, and the horizontal height of the left frame of the terminal is higher than that of the right frame, determining that the stress area on the right frame is continuously distributed, the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- An operation mode determination apparatus, the apparatus being adapted for a terminal, wherein the apparatus comprises:the first acquisition module is used for respectively acquiring first stress information of a left frame and second stress information of a right frame of the terminal when the terminal is detected to be operated;a first determining module, configured to determine that the terminal is in a left-hand single-hand operation mode if it is detected that the stressed areas on the left frame are continuously distributed according to the first stress information and it is detected that the stressed area on the right frame includes a plurality of sub-areas that are distributed at intervals according to the second stress information;and the second determining module is used for determining that the terminal is in a right-hand single-hand operation mode if the stress area on the left frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is detected to be continuously distributed according to the second stress information.
- The operation mode determination apparatus according to claim 8, wherein each of left and right rims of the terminal includes a plurality of pressure sensors;the first obtaining module is configured to: acquiring information of pressure sensors with output values on a left frame and a right frame of the terminal, wherein the information of the pressure sensors with the output values on the left frame is used for representing first stress information, and the information of the pressure sensors with the output values on the right frame is used for representing second stress information;the first determination module is to: if the continuous distribution of the stress area on the left frame is detected according to the information of the pressure sensor with the output value on the left frame, and the stress area on the right frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a left-hand single-hand operation mode;the second determination module is to: and if the stressed area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the left frame, and the stressed area on the right frame is continuously distributed according to the information of the pressure sensor with the output value on the right frame, determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determining apparatus according to claim 9, wherein each of the pressure sensors on the left and right rims is assigned a corresponding identification number, and the identification numbers of the pressure sensors located adjacently are consecutive in value;the first obtaining module is configured to: respectively acquiring identification numbers of pressure sensors with output values on the left frame and the right frame of the terminal;the first determination module is to: if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous is detected, the fact that stress areas on the left frame are distributed continuously is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the terminal is in a left-hand single-hand operation mode is determined;the second determination module is to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, and the identification numbers of the pressure sensors with the output values on the left frame are not continuous, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination apparatus according to claim 10,the first obtaining module is configured to: acquiring a first number of pressure sensors with output values on the left frame and a second number of pressure sensors with output values on the right frame;the first determination module is to: if the identification numbers of the pressure sensors with the output values on the left frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the right frame are detected to be discontinuous, and the first number is greater than the second number, the stress areas on the left frame are determined to be continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode;the second determination module is to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second number is greater than the first number, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- The operation mode determination apparatus according to claim 10, wherein the apparatus further comprises:the recording module is used for: recording a touch position corresponding to each touch operation in the preset times of touch operations; determining a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the terminal; counting a first frequency of touch operation of a touch area in the preset first area, and calculating a first proportional value of the first frequency and the preset frequency; counting a second frequency of touch operation of a touch area in the preset second area, and calculating a second proportional value of the second frequency and the preset frequency;the first determination module is to: if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than a preset proportion threshold value, it is determined that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the terminal is determined to be in a left-hand single-hand operation mode;the second determination module is to: and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is greater than a preset proportion threshold value, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the terminal is in a right-hand single-hand operation mode.
- A storage medium having stored thereon a computer program, wherein the computer program, when executed on a computer, causes the computer to execute the operation mode determination method according to any one of claims 1 to 7.
- An electronic device comprising a memory, a processor, wherein the processor is operable to execute, by invoking a computer program stored in the memory:when the electronic equipment is detected to be operated, respectively acquiring first stress information of a left frame and second stress information of a right frame of the electronic equipment;if the stress areas on the left frame are detected to be continuously distributed according to the first stress information and the stress areas on the right frame are detected to comprise a plurality of sub-areas which are distributed at intervals according to the second stress information, determining that the electronic equipment is in a left-hand single-hand operation mode;and if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the first stress information and the stress area on the right frame is continuously distributed according to the second stress information, determining that the electronic equipment is in a right-hand single-hand operation mode.
- The electronic device of claim 14, wherein a left bezel and a right bezel of the electronic device each include a plurality of pressure sensors, the processor to perform:acquiring information of pressure sensors with output values on a left frame and a right frame of the electronic equipment, wherein the information of the pressure sensors with the output values on the left frame is used for representing first stress information, and the information of the pressure sensors with the output values on the right frame is used for representing second stress information;if the continuous distribution of the stress area on the left frame is detected according to the information of the pressure sensor with the output value on the left frame, and the stress area on the right frame is detected to comprise a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the right frame, determining that the electronic equipment is in a left-hand single-hand operation mode;and if the stress area on the left frame comprises a plurality of sub-areas which are distributed at intervals according to the information of the pressure sensor with the output value on the left frame and the stress area on the right frame is continuously distributed according to the information of the pressure sensor with the output value on the right frame, determining that the electronic equipment is in a right-hand single-hand operation mode.
- The electronic device of claim 15, wherein each pressure sensor on the left and right borders is assigned a corresponding identification number, the identification numbers of adjacently located pressure sensors being consecutive in value, the processor being configured to perform:respectively acquiring identification numbers of pressure sensors with output values on the left frame and the right frame of the electronic equipment;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are not continuous is detected, the fact that stress areas on the left frame are distributed continuously is determined, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a left-hand single-hand operation mode is determined;and if the fact that the identification numbers of the pressure sensors with the output values on the right frame are kept continuous and the identification numbers of the pressure sensors with the output values on the left frame are not continuous is detected, the fact that the stress areas on the right frame are continuously distributed is determined, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a right-hand single-hand operation mode is determined.
- The electronic device of claim 16, wherein the processor is configured to perform:acquiring a first number of pressure sensors with output values on the left frame and a second number of pressure sensors with output values on the right frame;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, the fact that the first number is larger than the second number is determined, stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and the fact that the electronic equipment is in a left-hand single-hand operation mode is determined;and if the identification numbers of the pressure sensors with the output values on the right frame are continuously detected, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second number is greater than the first number, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a right-hand single-hand operation mode.
- The electronic device of claim 16, wherein the processor is configured to perform:recording a touch position corresponding to each touch operation in the preset times of touch operations;determining a touch area to which each touch position belongs, wherein the touch area comprises a preset first area and a preset second area, and the preset first area and the preset second area form a touch screen area of the electronic equipment;counting a first frequency of touch operation of a touch area in the preset first area, and calculating a first proportional value of the first frequency and the preset frequency;counting a second frequency of touch operation of a touch area in the preset second area, and calculating a second proportional value of the second frequency and the preset frequency;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the first proportion value is larger than a preset proportion threshold value, it is determined that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and it is determined that the electronic equipment is in a left-hand single-hand operation mode;if the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are not continuous, and the second proportion value is larger than a preset proportion threshold value, the stress areas on the right frame are determined to be continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and the electronic equipment is determined to be in a right-hand single-hand operation mode.
- The electronic device of claim 16, wherein the processor is configured to perform:respectively obtaining pressure output values of each pressure sensor on the left frame and the right frame, and respectively calculating a first average pressure output value corresponding to the left frame and a second average pressure output value corresponding to the right frame according to the pressure output values;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are continuous is detected, the fact that the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, the fact that the first average pressure output value is larger than the second average pressure output value is detected, it is determined that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and it is determined that the electronic equipment is in a left-hand single-hand operation mode;and if the identification numbers of the pressure sensors with the output values on the right frame are detected to be continuous, the identification numbers of the pressure sensors with the output values on the left frame are detected to be discontinuous, and the second average pressure output value is larger than the first average pressure output value, determining that the stress areas on the right frame are continuously distributed, the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a right-hand single-hand operation mode.
- The electronic device of claim 16, wherein the processor is configured to perform:acquiring an output value of a gyroscope, and determining the posture of the electronic equipment held by a user according to the output value of the gyroscope;judging whether the horizontal height of the left frame of the electronic equipment is higher than that of the right frame or not according to the posture;if the fact that the identification numbers of the pressure sensors with the output values on the left frame are kept continuous and the identification numbers of the pressure sensors with the output values on the right frame are discontinuous is detected, and the horizontal height of the left frame of the electronic equipment is lower than that of the right frame, determining that the stress areas on the left frame are continuously distributed, the stress areas on the right frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a left-hand single-hand operation mode;and if the fact that the identification numbers of the pressure sensors with the output values on the right frame are kept continuous is detected, the identification numbers of the pressure sensors with the output values on the left frame are discontinuous, and the horizontal height of the left frame of the electronic equipment is higher than that of the right frame, determining that the stress areas on the right frame are continuously distributed, wherein the stress areas on the left frame comprise a plurality of sub-areas which are distributed at intervals, and determining that the electronic equipment is in a right-hand single-hand operation mode.
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CN104252292A (en) * | 2014-08-29 | 2014-12-31 | 惠州Tcl移动通信有限公司 | Display method and mobile terminal |
US20150301698A1 (en) * | 2014-04-17 | 2015-10-22 | Capgemini Ts France | Systems, methods and computer-readable media for enabling information technology transformations |
CN105487755A (en) * | 2015-11-27 | 2016-04-13 | 努比亚技术有限公司 | One-hand operation method and apparatus and mobile terminal |
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CN106484284B (en) * | 2016-09-22 | 2020-01-10 | 北京小米移动软件有限公司 | Method and device for switching single-hand mode |
CN106445351A (en) * | 2016-11-19 | 2017-02-22 | 奇酷互联网络科技(深圳)有限公司 | Interface control method and device |
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CN104252292A (en) * | 2014-08-29 | 2014-12-31 | 惠州Tcl移动通信有限公司 | Display method and mobile terminal |
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