WO2019023997A1 - Procédé d'actionnement et appareil d'actionnement pour boîte de dialogue dans un terminal intelligent - Google Patents

Procédé d'actionnement et appareil d'actionnement pour boîte de dialogue dans un terminal intelligent Download PDF

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Publication number
WO2019023997A1
WO2019023997A1 PCT/CN2017/095649 CN2017095649W WO2019023997A1 WO 2019023997 A1 WO2019023997 A1 WO 2019023997A1 CN 2017095649 W CN2017095649 W CN 2017095649W WO 2019023997 A1 WO2019023997 A1 WO 2019023997A1
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Prior art keywords
airflow
parameter data
smart terminal
dialog box
sample
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PCT/CN2017/095649
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English (en)
Chinese (zh)
Inventor
李钊
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深圳传音通讯有限公司
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Priority to PCT/CN2017/095649 priority Critical patent/WO2019023997A1/fr
Publication of WO2019023997A1 publication Critical patent/WO2019023997A1/fr

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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F3/00Input 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
    • G06F3/01Input arrangements or combined input and output arrangements for interaction between user and computer
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F3/00Input 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
    • G06F3/01Input arrangements or combined input and output arrangements for interaction between user and computer
    • G06F3/048Interaction techniques based on graphical user interfaces [GUI]
    • G06F3/0487Interaction 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

Definitions

  • the present invention relates to the field of intelligent terminals, and in particular, to a method and an operation device for operating a dialog box in an intelligent terminal.
  • a smart terminal such as a mobile phone
  • manual operations such as when a user performs manual operations such as meals, ceramics, and the like, and needs to use an electronic device for inquiry or other operations.
  • a voice control scheme In order to achieve no manual operation, a voice control scheme is usually adopted.
  • the above voice control scheme can only perform linear control operations, and the user voice and other voices cannot be recognized in the voice environment where the electronic device is located, so that the user's electronic device may be controlled by other voices and perform some operation, so that the user is using the electronic The device is disturbed and reduces the user experience.
  • the manner in which the user selects the operation dialog box is mostly performed by means of touch, wherein the specific method includes touching the physical button and touching the screen, but in some cases due to When the hands are inconvenient for the touch operation selection, the effective operation cannot be performed, but when the hands are inconvenient to operate, the user needs to operate the options popped up by the smart terminal.
  • an object of the present invention is to provide an operation method and an operation device for a dialog box in an intelligent terminal.
  • the invention discloses a method for operating a dialog box in a smart terminal, characterized in that the operation method comprises:
  • the step of storing the first parameter data of the first airflow in the smart terminal comprises:
  • Parsing the first airflow sample to form the first parameter data wherein the first parameter data includes one or more of an intensity of a gas flow and a duration of a gas flow; or
  • the smart terminal is in communication connection with a cloud server
  • the first parameter data is downloaded and stored.
  • collecting a second airflow sample that is blown to the smart terminal includes:
  • the smart terminal When the smart terminal needs to prompt a dialog box during the execution of an operation, the smart terminal prompts a dialog box in the display area of the smart terminal;
  • a message prompting the user to perform an operation is displayed in the dialog box.
  • collecting a second airflow sample that is blown to the smart terminal includes:
  • an airflow detecting device When the dialog box is displayed in the display area of the smart terminal, an airflow detecting device is activated;
  • the second airflow sample blown to the smart terminal is monitored according to the airflow detecting device.
  • comparing the second parameter data with the first parameter data, when the second parameter data matches the first parameter data, performing the operation action on the dialog box comprises:
  • the dialog box is kept displayed in the display area of the smart terminal.
  • the invention also discloses a
  • the operation device of the dialog box in the smart terminal comprises: a storage module, an association module, an acquisition module, a detection module, and an execution module, wherein
  • the storage module is configured to store, in the smart terminal, first parameter data corresponding to the first airflow sample
  • the association module is communicatively coupled to the storage module for associating the first airflow sample with an operational action
  • the collecting module is connected to the storage module, and is configured to collect a second airflow sample that is blown to the smart terminal when the display area of the smart terminal displays a dialog box;
  • the detecting module is connected to the collecting module for analyzing the second airflow sample to form a second parameter data
  • the execution module is in communication with the detection module, configured to compare the second parameter data with the first parameter data, and when the second parameter data matches the first parameter data, the session is The box performs the operational action.
  • the storage module includes:
  • An acquisition unit configured to collect a first airflow sample
  • a parsing unit configured to communicate with the collecting unit, configured to parse the first airflow sample to form the first parameter data, wherein the first parameter data includes one of an intensity of a gas flow and a duration of a gas flow or Multiple
  • a communication unit configured to communicate with a cloud server, and upload the first parameter data to the cloud server;
  • a downloading unit configured to communicate with the cloud server, to download the first parameter data and store the data through the storage unit.
  • the collecting module comprises:
  • a prompting unit configured to prompt a dialog box in the display area of the smart terminal and start when the smart terminal needs to prompt a dialog box during the execution of an operation
  • a message prompting the user to perform an operation is displayed in the dialog box.
  • the collecting module further includes:
  • control unit configured to start an airflow detecting device when the dialog box is displayed in a display area of the smart terminal
  • a monitoring unit in communication with the control unit, configured to monitor the second airflow sample blown to the smart terminal according to the airflow detecting device.
  • the execution module includes:
  • An analyzing unit configured to calculate a difference between the second airflow parameter data and the first airflow parameter data
  • An execution unit configured to be in communication with the analysis unit, configured to cancel the dialog box and close a display interface of the display area of the smart terminal when the difference is a positive number;
  • the execution unit is further configured to keep the dialog box displayed in a display area of the smart terminal when the difference is a negative number.
  • FIG. 1 is a schematic flow chart of a method for operating a dialog box in a smart terminal according to a preferred embodiment of the present invention
  • step 101 of a method for operating a dialog box in a smart terminal according to a preferred embodiment of the present invention
  • step 103 is a schematic flowchart of step 103 of an operation method of a dialog box in a smart terminal according to a preferred embodiment of the present invention
  • step 103 is a schematic flow chart of step 103 of a method for operating a dialog box in a smart terminal according to a preferred embodiment of the present invention
  • step 105 is a schematic flowchart of step 105 of an operation method of a dialog box in a smart terminal according to a preferred embodiment of the present invention
  • FIG. 6 is a schematic structural diagram of an operation device of a dialog box in a smart terminal according to a preferred embodiment of the present invention.
  • FIG. 7 is a schematic structural diagram of an operation device of a dialog box in a smart terminal according to a preferred embodiment of the present invention.
  • FIG. 8 is a schematic structural diagram of an operation device of a dialog box in a smart terminal according to a preferred embodiment of the present invention.
  • FIG. 9 is a schematic structural diagram of an operation device of a dialog box in a smart terminal according to a preferred embodiment of the present invention.
  • 10-Operation device 20-storage module, 30-association module, 40-acquisition module, 50-detection module, 60-execution module:
  • the smart terminal used herein includes a device of a wireless signal receiver, a device having only a wireless signal receiver without a transmitting capability, and a device for receiving and transmitting hardware. It has a device capable of receiving and transmitting hardware for two-way communication over a two-way communication link.
  • Such devices may include cellular or other communication devices having a single line display or a multi-line display or a cellular or other communication device without a multi-line display; PCS (Personal Communications Service), which may combine voice, data Processing, fax, and/or data communication capabilities; PDA (Personal Digital Assistant), which can include radio frequency receivers, pagers, Internet/Intranet access, web browsers, notepads, calendars, and/or GPS (Global Positioning System (Global Positioning System) receiver; conventional laptop and/or palmtop computer or other device having a conventional laptop and/or palmtop computer or other device that includes and/or includes a radio frequency receiver.
  • PCS Personal Communications Service
  • PDA Personal Digital Assistant
  • terminal may be portable, transportable, installed in a vehicle (aviation, sea and/or land), or adapted and/or configured to operate locally, and/or Run in any other location on the Earth and/or space in a distributed form.
  • the "device” and “smart terminal” used herein may also be a communication device, an internet device, a music/video playback device, such as a PDA, a MID (Mobile Internet Device), and/or have a music/video playback.
  • Functional mobile phones can also be smart TVs, set-top boxes and other devices.
  • a flow diagram consistent with a preferred embodiment of the present invention includes:
  • Step 101 Store, in the smart terminal, first parameter data corresponding to the first airflow sample.
  • Step 102 Associate the first airflow sample with an operation action
  • the parameter information of the first airflow is preset, for example, the generated airflow parameter data can be acquired through a microphone.
  • the microphone When the microphone is used to detect the airflow parameter, the microphone captures the sound generated by the airflow change.
  • the airflow parameter is the electric signal converted by the sound captured by the microphone, and the condition that the first airflow parameter needs to satisfy may be the amplitude of the electrical signal.
  • the preset size and/or the preset position of the sound source obtained from the electrical signal. It is also possible to further obtain a moving direction or a moving path of the airflow change according to the obtained first airflow parameter.
  • the preset first airflow parameter data can be obtained by comparing, the obtained relative temperature data is obtained by a sensor and sent to the smart terminal, and the smart terminal is further configured to: receive the airflow parameter data, the Relative temperature data.
  • the airflow parameter data is data formed by characteristics such as a human body and an environment having a variation, and includes: general noise data, heartbeat data, user air blowing data, and accidental noise data.
  • Relative temperature data is posted
  • the data formed by the temperature changes generated by the human body mainly include: the body surface temperature of the human body obtained by real-time detection; the difference of the body surface temperature has an influence on the detection of the air blowing, and therefore the algorithm used for the surface temperature correction filtering is required. Filter coefficient, perfect multi-level filtering algorithm.
  • the first noise filtering is the filtering of common noise data, and the series filtering method is adopted, and the air blowing vector data is obtained after filtering; the air blowing vector data is vector data with a relatively obvious direction (for example, air blowing and heartbeat are obvious). Amplitude and frequency).
  • the user-based data is data with specific directivity entered by the user; the specific directivity refers to the amplitude and frequency range of different user-based data corresponding to different set features (in the algorithm, the difference in filter coefficients).
  • Similar filtering is the filtering of heartbeat data, using theoretical, actual amplitude and frequency comparison; because the amplitude and frequency of heartbeat and insufflation are similar, the comparison method is used to determine which is the amplitude of the heartbeat and The frequency is filtered out in a targeted manner, and the remaining feature data necessarily includes the user's insufflation data.
  • the first airflow parameter data can be obtained by the cloud server or directly stored in the chip built in the smart terminal, that is, the information can be directly retrieved from the cloud server.
  • Step 103 When the display area of the smart terminal displays a dialog box, collect a second airflow sample that is blown to the smart terminal;
  • the pop-up mechanism of a dialog box prompts a dialog box in the display area of the smart terminal, and the dialog box displays a prompting user to perform the dialog box. operating.
  • the second inspiratory airflow data of the user is obtained through the sensor integrated device, in order to avoid interference of the environmental noise on the acquisition and detection process, so as to improve the accuracy of airflow detection and classification in the air blowing, the invention is implemented
  • the collected airflow data is first denoised by low-pass filtering to eliminate the influence of environmental noise on the original signal, and then, filtering.
  • the inspiratory data in the airflow data because the noise usually occurs in the inhalation phase, so it is necessary to accurately find the inspiratory sound source and the insufflation sound source from the airflow data to determine the start time and end time of the inhalation data. .
  • the flow curve of the inspiratory data of the preset time period is selected, and the characteristic parameters of the flow curve are analyzed and calculated to realize the detection and classification of the pair.
  • the sensor integrated device monitors the airflow of the smart terminal in real time while prompting the dialog box.
  • the sensor integrated device collects the airflow of the blow air and passes the detection and analysis. Storing the intensity of the airflow; the sensor integrated device includes more than one sensor, and the position of the sensor in the smart terminal and the number of sensors can be set or adjusted according to different internal or external structures of the smart terminal; for example, it can be set in The location of the smart terminal microphone.
  • the parameter data of the first airflow that can be stored in an embodiment of the present invention may include a strong airflow.
  • the data is as follows.
  • the method for obtaining the airflow intensity by the sensor integrated device is as follows: the sensor integrated device has a circular air hole, and the sensor integrated device further has a spherical circuit board and a suspended object inside, and the spherical circuit board covers the sensor.
  • the suspended object is suspended in the fixed position A inside the sensor when there is no airflow into the intelligent terminal, and the method for ensuring that the suspended object is suspended inside the sensor integrated device is to set a magnet on the suspended object, and the sensor integrated device A magnet is also arranged inside, and the suspended object can be suspended due to the repulsive force of the magnetic pole between the magnets; when there is airflow through the intelligent terminal, the airflow will enter the inside of the sensor through the circular air hole of the sensor integrated device, and the suspended object is subjected to the airflow. Pushing the movement inside the sensor will touch the spherical circuit board.
  • the position of the touch point is B. According to position B and position A, it can be judged that the direction of the air flow can be expressed as A to B, and at the same time, according to position B and position A. The time period between changes, while also calculating the strong airflow Duration and data flow.
  • the parameter data of the preset first airflow is acquired, and after the second airflow is collected, the parameter data of the second airflow generated due to the airflow change is acquired.
  • the sensor integrated device of the smart terminal monitors the airflow of the smart terminal in real time, and when the second airflow is detected, the sensor integrated device sends the second airflow parameter data generated by the second airflow change to the smart through the detection and analysis interface.
  • the operating system of the terminal and the operating system sends the second airflow parameter data to the storage device of the smart terminal through the detection and analysis interface and stores the data.
  • the first airflow parameter data refers to the first airflow parameter data preset in the smart terminal, and the first airflow parameter data can include the airflow intensity and the airflow duration At least one of the time.
  • the second airflow parameter data refers to a current airflow that is detected by the smart terminal in real time through the sensor integrated device of the smart terminal when displaying a dialog box, and the second airflow parameter data includes at least one of airflow intensity and airflow duration. .
  • the sensor integrated device of the smart terminal sets the first airflow parameter data and the second airflow parameter data when collecting There are measures to filter out the interference information.
  • a sound having a human vocal characteristic is emitted, and the sound generated when the natural wind flows is extremely small, and the sound color is different from the human vocalization (including mechanical sound), and is set in the smart terminal.
  • the sensor integrated device collects the sound closer to it and collects the sound when the natural wind flows, thereby shielding the current airflow pair by identifying the sound color type as the natural wind sound or the mechanical sound when the sound parameter is recognized.
  • the influence generated by the electronic device does not acquire and detect the current airflow; on the contrary, if the sound color type in the sound parameter is recognized as a human voice, it is determined that the current airflow directed to the smart terminal speaks or exhales for the user (blowing Produced by gas Airflow, at this time, the target airflow parameter data corresponding to the current airflow is collected and detected.
  • the present embodiment uses the airflow parameter data while the sensor integrated device acquires
  • the sensor integrated device simultaneously acquires sound parameters, and distinguishes the attribute of the target airflow by identifying the type of sound color in the sound parameter, which is generated by the user, or is it natural wind or other airflow type, and shields the airflow in the electronic device from the outside air such as natural wind. Controlled interference.
  • Step 104 Parsing the second airflow sample to form a second parameter data.
  • Step 105 Compare the second parameter data with the first parameter data, and when the second parameter data matches the first parameter data, perform the operation action on the dialog box;
  • the airflow entering the smart terminal includes two situations, one is a flow generated by a user's air blow, and the other is a flow generated by the air flow, and the smart terminal only generates airflow generated by the user.
  • the airflow generated by the air flow does not need to perform the canceling operation, and in step 102, although the sensor integrated device is provided to filter and remove the natural wind airflow, in order to ensure accuracy, if only the preset threshold is The comparison of the airflow parameter data determines whether to perform the cancel operation according to the comparison result, and it is impossible to distinguish the airflow generated by the user's air blow and the airflow generated by the air flow, thereby causing the error rate and uncertainty of canceling the operation, and easily causing misoperation.
  • the smart terminal When distinguishing the airflow generated by the user's air blow and the airflow generated by the air flow, it is necessary to determine whether the airflow is generated by blowing air toward the smart terminal according to the airflow parameter data, and when the airflow is generated toward the smart terminal, the smart terminal is located.
  • the air in the environment cannot be generated when the air flows, so the airflow generated by the user's air blow can be distinguished from the airflow generated by the air flow based on the principle, so that the smart terminal can accurately accurately when the user blows the air to the smart terminal in the blow-off unlocked position. Cancel the dialog.
  • the performing the canceling operation includes: after receiving the first airflow parameter data stored by the sensor integrated device and the second airflow parameter data stored and detected by the operating system of the smart terminal, calculating a difference between the first airflow parameter data and the second airflow parameter data, Comparing the calculated difference with the preset threshold, if the difference between the first airflow parameter data and the second airflow parameter data is greater than or equal to a preset threshold, performing a cancel operation; if the first airflow parameter data and the second The difference between the airflow parameter data is less than the preset threshold, and the cancel operation is not performed.
  • the difference between the first airflow parameter data and the second airflow parameter data is: the airflow intensity of the first airflow minus the airflow intensity of the second airflow, and/or the airflow duration of the first airflow minus the second airflow. Airflow duration.
  • first, second, third, etc. may be used in the present disclosure to describe various information, such information should not be limited to these terms. These terms are only used to distinguish the same type of information from each other.
  • first information may also be referred to as second information without departing from the scope of the present disclosure.
  • second information may also be referred to as first information.
  • word "if” as used herein may be interpreted as "when” or "when” or "in response to determination.”
  • the operating device for the dialog box in the smart terminal may be implemented by an operating device 10, including: a storage module 20, an association module 30, an acquisition module 40, and a detection module. 50. Execution module 60.
  • the parameter information of the first airflow is preset, for example, the generated airflow parameter data can be acquired through a microphone.
  • the microphone When the microphone is used to detect the airflow parameter, the microphone captures the sound generated by the airflow change.
  • the airflow parameter is the electric signal converted by the sound captured by the microphone, and the condition that the first airflow parameter needs to satisfy may be the amplitude of the electrical signal.
  • the preset size and/or the preset position of the sound source obtained from the electrical signal. It is also possible to further obtain a moving direction or a moving path of the airflow change according to the obtained first airflow parameter.
  • the preset first airflow parameter data can be obtained by comparing, the acquisition unit obtains and sends the relative temperature data to the smart terminal by using a sensor, and the parsing unit further configures the smart terminal to: receive the Airflow parameter data, the relative temperature data.
  • the airflow parameter data is data formed by characteristics such as a human body and an environment having a variation, and includes: general noise data, heartbeat data, user air blowing data, and accidental noise data.
  • the relative temperature data is the data formed by the temperature change generated when close to the human body, mainly including: the body surface temperature of the human body obtained by real-time detection; the difference of the body surface temperature has an influence on the detection of the insufflation, so it is necessary to filter through the body surface temperature correction.
  • the filter coefficients of the algorithm used at the time to perfect the multi-level filtering algorithm are the filtering of common noise data, and the series filtering method is adopted, and the air blowing vector data is obtained after filtering; the air blowing vector data is vector data with a relatively obvious direction (for example, air blowing and heartbeat are obvious). Amplitude and frequency).
  • the user-based data is data with specific directivity entered by the user; the specific directivity refers to the amplitude and frequency range of different user-based data corresponding to different set features (in the algorithm, the difference in filter coefficients).
  • Similar filtering is the filtering of heartbeat data, using theory, The actual amplitude and frequency comparison method; because the amplitude and frequency of the heartbeat and insufflation are similar, use the comparison method to determine which is the amplitude and frequency of the heartbeat, and filter it out in a targeted manner.
  • the characteristic data of the user must include the user's insufflation data.
  • the communication unit enables the first airflow parameter data to be acquired by the cloud server or directly stored in the chip built in the smart terminal, that is, the download unit can directly retrieve the information from the cloud server.
  • the pop-up mechanism of a dialog box prompts a dialog box in the display area of the smart terminal, and the dialog box displays a prompting user to perform the dialog box. operating.
  • the prompting unit prompts the dialog box to obtain the second blowing airflow data of the user through the sensor integrated device, in order to avoid interference of the environmental noise on the collection and detection process, so as to improve the accuracy of airflow detection and classification in the air blowing,
  • the collected airflow data is first denoised by low-pass filtering to eliminate the influence of the environmental noise on the original signal, and then, Find the inspiratory data from the filtered airflow data, because the noise usually occurs in the inhalation phase, so it is necessary to accurately find the inspiratory sound source and the insufflation sound source from the airflow data to determine the start time of the inhalation data and End Time.
  • the flow curve of the inspiratory data of the preset time period is selected, and the characteristic parameters of the flow curve are analyzed and calculated to realize the detection and classification of the pair.
  • the control unit controls the sensor integrated device to monitor the airflow of the smart terminal in real time, and when it is detected that the airflow is blown toward the smart terminal and the second airflow is generated, the sensor integrated device collects the airflow of the blow air and passes the airflow.
  • the intensity of the airflow is stored after the analysis and analysis; the sensor integrated device includes more than one sensor, and the position of the sensor in the smart terminal and the number of sensors can be set or adjusted according to internal or external structures of different smart terminals; for example, It can be placed near the microphone position of the smart terminal.
  • the parameter data of the first airflow that can be stored in an embodiment of the present invention may include the intensity data of the airflow.
  • the method for obtaining the airflow intensity by the sensor integrated device is as follows: the monitoring unit makes the sensor integrated device have The circular air hole, the sensor integrated device also has a spherical circuit board and a suspended object inside.
  • the spherical circuit board covers the area of the inner surface of the sensor except the circular air hole, and the suspended object is suspended inside the sensor when no airflow enters the intelligent terminal.
  • the fixed position A ensures that the suspended object is suspended inside the sensor integrated device by placing a magnet on the suspended object, and a magnet is also arranged inside the sensor integrated device, and the suspended object can be suspended due to the repulsive force between the magnetic poles of the magnet;
  • the airflow passes through the intelligent terminal, the airflow will pass through the sensor integrated device
  • the circular air hole enters the inside of the sensor, and the suspended object moves inside the sensor due to the airflow, and will touch the spherical circuit board.
  • the position of the touch point is B. According to the position B and the position A, the direction of the airflow can be judged. It can be expressed as A to B, and at the same time, according to the time period between the position B and the position A, the intensity data of the airflow and the duration of the airflow can be calculated at the same time.
  • the parameter data of the preset first airflow is acquired, and after the second airflow is collected, the parameter data of the second airflow generated due to the airflow change is acquired.
  • the sensor integrated device of the smart terminal monitors the airflow of the smart terminal in real time, and when the second airflow is detected, the sensor integrated device sends the second airflow parameter data generated by the second airflow change to the smart through the detection and analysis interface.
  • the operating system of the terminal and the operating system sends the second airflow parameter data to the storage device of the smart terminal through the detection and analysis interface and stores the data.
  • the first airflow parameter data refers to the first airflow parameter data preset in the smart terminal, and the first airflow parameter data can include the airflow intensity and the airflow duration At least one of the time.
  • the second airflow parameter data refers to a current airflow that is detected by the smart terminal in real time through the sensor integrated device of the smart terminal when displaying a dialog box, and the second airflow parameter data includes at least one of airflow intensity and airflow duration. .
  • the sensor integrated device of the smart terminal sets the first airflow parameter data and the second airflow parameter data when collecting There are measures to filter out the interference information.
  • a sound having a human vocal characteristic is emitted, and the sound generated when the natural wind flows is extremely small, and the sound color is different from the human vocalization (including mechanical sound), and is set in the smart terminal.
  • the sensor integrated device collects the sound closer to it and collects the sound when the natural wind flows, thereby shielding the current airflow pair by identifying the sound color type as the natural wind sound or the mechanical sound when the sound parameter is recognized.
  • the influence generated by the electronic device does not acquire and detect the current airflow; on the contrary, if the sound color type in the sound parameter is recognized as a human voice, it is determined that the current airflow directed to the smart terminal speaks or exhales for the user (blowing The airflow generated by the gas is collected and detected at the target airflow parameter data corresponding to the current airflow.
  • the present embodiment uses the airflow parameter data while the sensor integrated device acquires
  • the sensor integrated device simultaneously acquires sound parameters, and distinguishes the attribute of the target airflow by identifying the type of sound color in the sound parameter, which is generated by the user, or is it natural wind or other airflow type, and shields the airflow in the electronic device from the outside air such as natural wind. Controlled interference.
  • the airflow entering the smart terminal includes two situations, one is a flow generated by a user's air blow, and the other is a flow generated by the air flow, and the smart terminal only generates airflow generated by the user.
  • cancel operation the airflow generated by the air flow does not need to be canceled.
  • the sensor integrated device is provided to filter out the natural wind airflow, in order to ensure accuracy, only the preset threshold and airflow parameter data are used. Comparison, according to the comparison result to decide whether to perform the cancel operation, it will be impossible to distinguish the airflow generated by the user's air blow and the airflow generated by the air flow, thereby causing the error rate and uncertainty of canceling the operation, and easily causing misoperation.
  • the analysis unit distinguishes the airflow generated by the user's air blow and the airflow generated by the air flow, it is necessary to determine whether the airflow is generated by blowing air toward the smart terminal according to the airflow parameter data, and is intelligent when blowing air toward the smart terminal to generate airflow.
  • the air in the environment in which the terminal is located cannot be generated when the air flows. Therefore, based on the principle, the airflow generated by the user's air blow can be distinguished from the airflow generated by the air flow, so that when the user blows the air to the smart terminal in the air blowing unlocking position, the smart terminal Can cancel the dialog accurately.
  • the performing unit performs the canceling operation, after receiving the first airflow parameter data stored by the sensor integrated device from the operating system of the smart terminal and detecting the second airflow parameter data analyzed, calculating a difference between the first airflow parameter data and the second airflow parameter data. a value, comparing the calculated difference with a preset threshold, if the difference between the first airflow parameter data and the second airflow parameter data is greater than or equal to a preset threshold, performing a cancel operation; if the first airflow parameter data and The difference between the second airflow parameter data is less than a preset threshold, and the cancel operation is not performed.
  • the difference between the first airflow parameter data and the second airflow parameter data is: the airflow intensity of the first airflow minus the airflow intensity of the second airflow, and/or the airflow duration of the first airflow minus the second airflow. Airflow duration.
  • an embodiment of the present invention further provides a computer readable storage medium having stored therein computer executable instructions, such as a non-volatile memory such as an optical disk, a hard disk, or a flash memory.
  • computer executable instructions are for causing a computer or the like to perform various operations in the above-described operation method of the dialog box.
  • the present invention includes apparatus related to performing one or more of the operations described herein. These devices may be specially designed and manufactured for the required purposes, or may also include known devices in a general purpose computer. These devices have computer programs stored therein that are selectively activated or reconfigured.
  • Such computer programs may be stored in a device (eg, computer) readable medium or in any type of medium suitable for storing electronic instructions and separately coupled to a bus, including but not limited to any Types of disks (including floppy disks, hard disks, optical disks, CD-ROMs, and magneto-optical disks), ROM (Read-Only Memory), RAM (Random Access Memory), EPROM (Erasable) Programmable Read-Only Memory, EEPROM (Electrically Erasable Programmable Read-Only Memory), flash memory, magnetic card or light card.
  • a readable medium includes any medium that is stored or transmitted by a device (eg, a computer) in a readable form.

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  • User Interface Of Digital Computer (AREA)

Abstract

L'invention concerne un procédé d'actionnement et un appareil d'actionnement pour une boîte de dialogue dans un terminal intelligent. Le procédé d'actionnement est caractérisé en ce qu'il consiste à : stocker des premières données de paramètre correspondant à un premier échantillon d'écoulement d'air dans un terminal intelligent (101); associer le premier échantillon d'écoulement d'air à une action d'opération (102); lorsqu'une boîte de dialogue est affichée dans une région d'affichage du terminal intelligent, recueillir un deuxième échantillon d'écoulement d'air soufflant vers le terminal intelligent (103); analyser le deuxième échantillon d'écoulement d'air pour former des deuxièmes données de paramètre (104); et comparer les deuxièmes données de paramètre avec les premières données de paramètre, et lorsque les deuxièmes données de paramètre correspondent aux premières données de paramètre, effectuer l'action d'opération sur la boîte de dialogue (105). Une opération nécessaire sur un dispositif électronique est mise en œuvre lorsqu'un utilisateur ne peut pas commander directement et manuellement le dispositif électronique, puis l'objectif de commande du dispositif électronique grâce à un flux d'air est atteint.
PCT/CN2017/095649 2017-08-02 2017-08-02 Procédé d'actionnement et appareil d'actionnement pour boîte de dialogue dans un terminal intelligent WO2019023997A1 (fr)

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CN106572252A (zh) * 2016-10-28 2017-04-19 上海传英信息技术有限公司 一种非接触式智能终端及其控制方法
CN106681489A (zh) * 2016-11-16 2017-05-17 珠海格力电器股份有限公司 一种设备控制方法、装置及电子设备
CN106775355A (zh) * 2016-12-28 2017-05-31 珠海市魅族科技有限公司 通过气体来控制终端设备的方法及系统

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US20150043311A1 (en) * 2013-08-09 2015-02-12 Your Voice S.P.A. Execution of commands in an electronic device
CN105975062A (zh) * 2016-04-27 2016-09-28 上海斐讯数据通信技术有限公司 移动终端的信息查看系统与信息查看方法
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