WO2018191938A1 - 一键开机处理方法及终端 - Google Patents

一键开机处理方法及终端 Download PDF

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Publication number
WO2018191938A1
WO2018191938A1 PCT/CN2017/081378 CN2017081378W WO2018191938A1 WO 2018191938 A1 WO2018191938 A1 WO 2018191938A1 CN 2017081378 W CN2017081378 W CN 2017081378W WO 2018191938 A1 WO2018191938 A1 WO 2018191938A1
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WO
WIPO (PCT)
Prior art keywords
terminal
power
biometric
button
pressed
Prior art date
Application number
PCT/CN2017/081378
Other languages
English (en)
French (fr)
Inventor
廖晓君
王兵
孙文彬
青小刚
Original Assignee
深圳市汇顶科技股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 深圳市汇顶科技股份有限公司 filed Critical 深圳市汇顶科技股份有限公司
Priority to EP17906610.5A priority Critical patent/EP3531796A4/en
Priority to PCT/CN2017/081378 priority patent/WO2018191938A1/zh
Priority to CN202110730064.7A priority patent/CN113392390B/zh
Priority to CN201780000251.1A priority patent/CN107223250B/zh
Publication of WO2018191938A1 publication Critical patent/WO2018191938A1/zh
Priority to US16/421,464 priority patent/US11216543B2/en

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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F21/00Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
    • G06F21/30Authentication, i.e. establishing the identity or authorisation of security principals
    • G06F21/31User authentication
    • G06F21/32User authentication using biometric data, e.g. fingerprints, iris scans or voiceprints
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F1/00Details not covered by groups G06F3/00 - G06F13/00 and G06F21/00
    • G06F1/26Power supply means, e.g. regulation thereof
    • G06F1/28Supervision thereof, e.g. detecting power-supply failure by out of limits supervision
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F21/00Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
    • G06F21/70Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer
    • G06F21/81Protecting specific internal or peripheral components, in which the protection of a component leads to protection of the entire computer by operating on the power supply, e.g. enabling or disabling power-on, sleep or resume operations
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06VIMAGE OR VIDEO RECOGNITION OR UNDERSTANDING
    • G06V40/00Recognition of biometric, human-related or animal-related patterns in image or video data
    • G06V40/10Human or animal bodies, e.g. vehicle occupants or pedestrians; Body parts, e.g. hands
    • G06V40/12Fingerprints or palmprints
    • G06V40/13Sensors therefor

Definitions

  • the embodiments of the present invention relate to the field of electronic technologies, and in particular, to a one-key boot processing method and a terminal.
  • a fingerprint login option appears on the operating system lock screen and the login interface, and the user is
  • the fingerprint feature recognition module slides or presses the registered finger to unlock or log in, thereby completing the whole process of the terminal booting.
  • the fingerprint feature recognition module is generally disposed at the lower left side of the keyboard of the notebook computer.
  • the user needs to press the power button to start the device, and then press the fingerprint feature recognition.
  • the module performs fingerprint login, thereby causing the user to perform at least two pressing operations during the booting process of the terminal, thereby affecting the booting efficiency of the terminal and the user experience is poor.
  • the purpose of the embodiment of the present application is to provide a one-key boot processing method and terminal, which are used to solve at least the above problems in the prior art.
  • the embodiment of the present application provides a one-key boot processing method, the method is applied to a terminal having a power button, and the terminal includes a biometric recognition module for operating the main body Collecting biometric data of the operating body during pressing of the power button, the method comprising:
  • the embodiment of the present application further provides a terminal, including a power button, a biometric module, and a microprocessor.
  • the biometric module is disposed on a power button for collecting an operation of pressing the power button.
  • the biometric data of the main body, the microprocessor is configured to determine, when the biometric module detects that the power button is pressed at a current moment, whether the power button is pressed at a current moment or not to trigger the terminal to perform a key activation And submitting the biometric data collected by the biometric identification module to the operating system of the terminal to perform a one-button boot process when the terminal is triggered to perform one-button booting.
  • the biometric module when the operating body presses the power button, can collect the biometric data of the operating body, and when it is detected that the power button is pressed at the current time, determine that the power button is currently Whether the moment is pressed to trigger the terminal to perform one-button power-on, and if yes, submit the biometric data collected by the biometric identification module to an operating system of the terminal to perform one-button boot processing, thereby enabling During the boot process of the terminal, the user only needs to perform a pressing operation to complete the process of booting the terminal, which increases the convenience and effectively improves the user experience of the terminal.
  • FIG. 2 is a schematic flowchart of a method for processing a one-key boot in the second embodiment of the present application
  • FIG. 3 is a schematic flowchart of a method for processing a one-key booting in the third embodiment of the present application
  • FIG. 4 is a schematic flow chart of a method for processing a key in the fourth embodiment of the present invention.
  • FIG. 5 is a schematic flowchart of a method for processing a one-key boot in the fifth embodiment of the present invention.
  • FIG. 6 is a schematic structural diagram of a terminal in Embodiment 6 of the present application.
  • FIG. 8 is a schematic diagram of a process of a key-on login phase in the eighth embodiment of the present application.
  • the biometric module when the operating body presses the power button, can collect biometric data of the operating body, and when it is detected that the power button is pressed at the current time, determine whether the power button is pressed at the current time. Triggering the terminal to perform one-button booting, and if yes, submitting the biometric data collected by the biometric identification module to the operating system of the terminal for one-button boot processing, so that the user needs to perform a pressing operation during the booting process of the terminal. The process of starting the terminal is completed, which increases the convenience and effectively improves the user experience.
  • FIG. 1 is a schematic flowchart of a method for processing a one-key booting in the first embodiment of the present invention; as shown in FIG. 1 , in the embodiment, the method is applied to a terminal having a power button, and the terminal includes a biometrics module.
  • the method specifically includes:
  • the application of the one-key boot to the notebook computer is taken as an example.
  • the biometric identification module takes the fingerprint feature recognition module as an example, and the power button and the fingerprint feature recognition module are disposed at the same position of the notebook, so that When the power button is pressed, the fingerprint feature recognition module is touched at the same time. For example, at the power button setting position of the existing notebook computer, the fingerprint feature recognition module is pasted on the upper surface of the power button, thereby ensuring the realization of one-button booting. . Similarly, a similar scheme can be adopted in the design of the power button of the desktop, and details are not described in detail.
  • step S101 when it is detected in step S101 that the power button is pressed at the current time, it is possible to detect whether a power button is pressed at the current time according to monitoring the pre-registered pressing event. For example, before the current moment is pressed, the fingerprint feature recognition module is pre-registered.
  • the pressing event is such that when a finger is directly pressed on the fingerprint feature recognition module and indirectly pressed onto the power button, the registration pressing event reflects the action of finger pressing.
  • the detection power button is pressed at the current time and is limited to the manner in which the pressing event can only be registered in advance, and can also be implemented by other hardware or a combination of hardware and software.
  • step S102 Determine whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on; if yes, execute step S103; otherwise, disable one-button power-on processing.
  • step S102 when it is determined in step S102 whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on, it is specifically determined whether the power-on and power-on signal is enabled during the set time, and is powered on within the set time.
  • the electromechanical signal is enabled, it is determined that the power button is pressed at the current moment to trigger the terminal to perform one-button power-on.
  • the power-on and power-on signal may be specifically whether the output signal of the embedded controller (Embedded Contronller, EC for short) is raised in the set time, for example, Within 2s, whether the output signal of the embedded controller is pulled up to the level, if yes, it is determined that the power-on and power-on signal is enabled, and then it can be determined that the power button is pressed at the current moment to trigger the terminal to perform one-button power-on; Otherwise, it is determined that the power button is pressed at the current time and the terminal is not triggered to perform one-button power-on.
  • the embedded controller Embedded Contronller, EC for short
  • the collected biometric data is not submitted to the operating system of the terminal.
  • the system may prompt the biometric data to be collected again in the terminal login interface, that is, it needs to be pressed again.
  • the power button enables the biometric module to perform re-collection of biometric data.
  • the biometric data may be a fingerprint image, and if it is a palm print, it may be a palm print image or the like. In other embodiments, the biometric data may also be blood sample data or heart rate data.
  • the terminal may set a corresponding biometric identification module above the power button according to the detection of the actual biometric data, or the biometric identification module may simultaneously support the collection of two or more biometric data. And testing.
  • the biometric data collected by the biometric identification module may be submitted to the operating system of the terminal according to the biometric data verification request.
  • the presence of the biometric data verification request automatically triggers the submission of the biometric data so that
  • the operating system calls the biometric driver to match the biometric data, that is, the data legality authentication. If the legality authentication is applied to the verification of the login authority of the laptop, it is determined whether the current user has the legal authority to log in and use the terminal. .
  • FIG. 2 is a schematic flowchart of a method for processing a key in the second embodiment of the present application; as shown in FIG. 2, the method specifically includes:
  • step S201 is similar to step S101 in FIG. 1 described above, and details are not described herein again.
  • the biometric identification module collects biometric data.
  • the biometrics module when the biometric identification module collects the biometric data in step S202, the biometrics module may be called by the operating system of the terminal to enable the biometric identification module to collect biometric data.
  • the biometric data may be a fingerprint image or blood sample data or heart rate data or the like.
  • step S201 the step of collecting biometric data is added between step S201 and step S203, and it is necessary to perform temporary storage processing on the collected biometric data.
  • step S203 Determine whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on. If yes, execute step S204; otherwise, disable one-button power-on processing.
  • step S203 is similar to step S102 in the above embodiment of FIG. 1, but different from the above embodiment, the real-time collection of biometric data is completed before determining whether to trigger a key to be turned on.
  • the power is submitted in step S204.
  • the button is biometric data collected by the biometric module to the operating system of the terminal
  • the stored biometric data can be directly pulled and submitted to the operating system of the terminal.
  • the pulling of the biometric data to the operating system of the terminal is initiated by means of an interruption.
  • FIG. 3 is a schematic flowchart of a method for processing a one-key booting in the third embodiment of the present invention; as shown in FIG. 3, the method specifically includes:
  • step S302. Determine whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on; if yes, execute step S303; otherwise, disable one-button power-on processing.
  • the biometric identification module collects biometric data.
  • the biometric data is collected after determining that the current moment of the power button is pressed to trigger the terminal to perform one-button power-on. Therefore, the collected biometric data may not be temporarily suspended.
  • the data is directly submitted to the operating system of the terminal by step S304, thereby improving the timeliness of data processing.
  • step S303 and step S304 are not performed.
  • FIG. 4 is a schematic flowchart of a method for processing a key in the fourth embodiment of the present invention; as shown in FIG. 4, the method specifically includes:
  • step S401 is similar to step S101 in the foregoing embodiment of FIG. 1, and details are not described herein again.
  • step S402. Determine whether there is a power state corresponding to the terminal when the terminal is in a sleep state or a sleep state or a power-off state; if yes, execute step S403; otherwise, disable one-button power-on processing.
  • the power state of the terminal is indicated by S3; if the terminal is in the sleep state, the power state of the terminal is represented by S4; if the terminal is in the shutdown state, the power state of the terminal is indicated by S5.
  • S3 the power state of the terminal
  • S4 the power state of the terminal
  • S5 the power state of the terminal
  • the power supply supplies power to the hard disk, and then the power supply stops supplying to the memory, the hard disk, and the CPU.
  • the power supply directly stops supplying power to the CPU, memory, and hard disk.
  • step S401 when it is detected in step S401 that the power button is pressed at the current time, the current determination is initially determined. Pressing the power button at any time may cause the terminal to wake up from the sleep state or the sleep state or the power-off state to cause the terminal to enter a key-on process. Therefore, in this embodiment, before the current time is pressed to press the power button to make the terminal enter the sleep state or the sleep state or the shutdown state is completed, the corresponding power state is stored, so that when a press is detected, whether Trigger the initial judgment of a key to start.
  • step S402 if it is determined in step S402 that there is no power state corresponding to the terminal entering the sleep state or the sleep state or the power-off state, it indicates that the pressing of the power button at the current time is an erroneous operation, and does not need to enter a key-on startup process, therefore, Directly prohibit one-button boot processing.
  • whether to store the power button before the current time is pressed to make the terminal enter the sleep state or the power state corresponding to the sleep state or the power-off state can be set on the terminal, and if the terminal needs to be stored, it indicates that the subsequent S403 is determined.
  • the result is YES, it can enter a key to start processing, otherwise, it means that when the power button is pressed, it is not necessary to enter a key to start processing.
  • whether the power state corresponding to the sleep state or the sleep state or the power-off state of the storage terminal can be customized by performing a one-button power-on processing function.
  • step S403. Determine whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on; if yes, execute step S404; otherwise, disable one-button power-on processing.
  • whether the power-on signal is enabled by the power-on signal can be used to determine whether a key-on is triggered.
  • determining whether the power button is pressed at the current time or not, triggering the terminal to perform one-button power-on can be determined by enabling the power-off signal of the operating system to be turned off. If the power-off signal is enabled, the power button can be indirectly determined at the current moment. If the power is turned off, the power-on signal is disabled, and then the power-on signal is enabled in the first embodiment. Whether to trigger the terminal to perform one-button boot.
  • step S404 is similar to the foregoing embodiment, and details are not described herein again.
  • step S404 when it is detected that the power button is pressed at the current time and whether the triggering of the one-button power-on process is added, it is determined whether there is a power state corresponding to the sleep state or the sleep state or the power-off state, that is, the first judgment is Whether to customize the one-button boot processing function for the terminal, and then determine whether the trigger condition of the one-button boot processing is satisfied. If the one-button boot processing is customized and the trigger condition is satisfied, step S404 is performed; otherwise, one-button boot processing is prohibited.
  • step S502 Determine whether the power button is pressed at the current time to trigger the terminal to perform one-button power-on; if yes, execute step S503; otherwise, disable one-button power-on processing.
  • step S503 Determine whether there is a corresponding power state when the terminal is in a sleep state or a sleep state or a power-off state; if yes, execute step S504; otherwise, disable one-button power-on processing.
  • the one-key boot processing method may further include: If there is no corresponding power state when the terminal is in a sleep state or a sleep state or a power-off state, the biometric data collected by the biometrics module is discarded while the one-button power-on processing is prohibited.
  • the operating system if the operating system has not been started, wait for the operating system of the terminal to start, and then submit the collected by the biometric identification module after the operating system of the terminal is started.
  • the biometric data is sent to an operating system of the terminal for a one-button boot process.
  • FIG. 6 is a schematic structural diagram of a terminal according to Embodiment 6 of the present application; as shown in FIG. 6, the power button 601, the microprocessor 602, and the biometric identification module 603 are included in the biometric identification module 603.
  • the biometric module 603 is configured to collect biometric data of an operation body that presses the power button;
  • the microprocessor 602 is configured to detect the power in the biometric module 603.
  • the button 601 is pressed at the current time, it is determined whether the power button 601 is pressed at the current time to trigger the terminal to perform one-button power-on and submit the biometric data collected by the biometric identification module 603 when the terminal is triggered to perform one-button power-on.
  • the microprocessor 602 and the biometric identification module 603 communicate through a Serial Peripheral Interface (SPI) mode, or communicate through a Universal Serial Bus (USB) mode. .
  • SPI Serial Peripheral Interface
  • USB Universal Serial Bus
  • the microprocessor 602 is further configured to determine that the power button 601 is pressed at the current time to trigger the terminal to perform one-button power-on when the power-on signal is enabled within the set time.
  • the microprocessor 602 is further configured to submit the biometric data collected by the biometric identification module 603 to the operating system of the terminal according to the biometric data verification request.
  • the microprocessor 602 is further configured to enable the biometric identification module 603 to collect biometric data.
  • the operating system of the terminal invokes biometric driving to enable the biometric identification module 603 to collect biometric data.
  • the biometrics drive pull biometric data stored by the microprocessor 602 for submission to the operating system of the terminal.
  • the biometric drive notifies the microprocessor 602 of the stored biometric data from the microprocessor 602 by way of an interrupt.
  • the microprocessor 602 is configured to be used by the biometric module when the power button 601 is pressed at the current time and the untriggered terminal is turned on. Biometric data collected by group 603.
  • the microprocessor 602 is further configured to determine whether the terminal is in a sleep state or a sleep state or shut down before determining whether the power button is pressed at the current moment to trigger the terminal to perform one-button power-on. The corresponding power state in the state; if If yes, it is determined whether the power button 601 is pressed at the current time to trigger the terminal to perform one-button power-on;
  • the microprocessor 602 is further configured to: after determining whether the power button is pressed at the current time to trigger the terminal to perform a key-on, determine whether there is a corresponding power state when the terminal is in a sleep state or a sleep state or a shutdown state; If so, the biometric data collected by the biometric module 603 is submitted to the operating system of the terminal.
  • the microprocessor 602 is further configured to discard the biological data collected by the biometric identification module 603 when there is no corresponding power state when the terminal is in a sleep state or a sleep state or a shutdown state. Feature data.
  • the biometric identification module 603 can be implemented based on the principle of light emission, or can be implemented based on the principle of capacitive effect.
  • fingerprint characteristic data is formed by different degrees of reflection of light rays from the valley ridge of the fingerprint, and in the fingerprint feature module based on the principle of capacitance effect, the estimated convexities and concaves of the fingerprint are formed into different sizes. Capacitance to form fingerprint feature data.
  • FIG. 7 is a schematic flowchart of a seven-key boot pre-processing stage according to an embodiment of the present application; that is, a series of processes in a process in which a notebook computer enters a sleep state or a sleep state or a shutdown state, as shown in FIG. 7, which includes:
  • Fingerprint feature recognition driver registers the EvtDeviceDOExit event callback function.
  • the operating system (OS) of the notebook calls EvtDeviceDOExit (call EvtDeviceDOExit), and calls the WdfDeviceGetSystemPowerAction function in the EvtDeviceDOExit event callback function to obtain the power state Sx of the terminal (S3 or S4). Or S5);
  • the fingerprint feature recognition driver sends the power state to the microprocessor for storage (send power state Sx);
  • the microprocessor registers the power button pressed event with the fingerprint feature recognition module, so that the fingerprint feature recognition module detects the power button pressed event in real time to detect whether the power button is pressed;
  • the microprocessor enters a switch low power mode, such as entering a sleep mode.
  • FIG. 8 is a schematic diagram of a process of a key-on login phase in the eighth embodiment of the present application; as shown in FIG. 8, the method includes:
  • the user currently presses the power button/fingerprint feature recognition module to generate a power on event to enter the awake state (resume from S3/S4/S5);
  • the fingerprint feature recognition module detects that there is a detected finger-down.
  • the fingerprint feature recognition module notifies the microprocessor (MCU) that the power button has been pressed in the form of an interrupt, and wakes up the microprocessor in the sleep state;
  • the microprocessor determines whether the power button is pressed at the current time or not to trigger the terminal to perform one-button power-on;
  • the microprocessor sends the stored fingerprint feature data to the fingerprint fingerprint identification image (send fingerprint image) and is stored by the fingerprint feature recognition drive (save Fingerprint image)
  • the fingerprint feature recognition driver registers the EvtDeviceDOEntry callback function, after the operating system recovers from the power state S3/S4/S5, the EvtDeviceDOEntry will be called once, and the EvtDeviceDOEntry function fingerprint feature recognition driver can establish communication with the microprocessor. Query whether there is stored fingerprint feature data, and submit the queried fingerprint feature data to the fingerprint feature recognition driver.
  • the operating system sends a fingerprint feature data request (send capture request) to the fingerprint feature recognition driver;
  • the operating system of the terminal invokes an engine adapter to match the fingerprint feature data
  • the matching engine returns a result of the legality verification to the operating system (complete capture request with Fingerprint image);
  • FIG. 9 is a schematic diagram of a software architecture in the ninth embodiment of the present application; as shown in FIG. 9 , in the embodiment, the architecture of the technical solution of the foregoing embodiment is implemented on the windows 10, and the hardware includes: the biometric identification device and the micro
  • the processor and the windows software layer include: Biometric Application, Windows biometric api, Windows biometric service, and User mode driver framework process (WUDFhost.exe).
  • the Biometric Application includes login using fingerprint feature data.
  • the Windows biometric service involves a biosensor collection (finger sensor), a biometric matching (engine adapter), a biometric data storage database, and a user mode driver.
  • the program framework process includes biometrics driver (such as fingerprint device drive), user mode driver architecture (wudf framework support), simple peripheral bus I/O interface (Simplified Peripheral Bus I/O target, SPB I/O target), simple Peripheral bus (Simple Peripheral Bu s, referred to as SPB).
  • biometrics driver such as fingerprint device drive
  • user mode driver architecture such as user mode driver architecture
  • simple peripheral bus I/O interface Simple Peripheral Bus I/O target, SPB I/O target
  • simple Peripheral bus Simple Peripheral Bu s, referred to as SPB
  • the simple peripheral bus I/O interface can be used by the microprocessor to interact with the biometric drive based on the Serial Peripheral Interface (SPI).
  • SPI Serial Peripheral Interface
  • the user mode driver framework is The fingerprint device drive has been added to the process and the fingerprint feature has been added to the Windows biometric service.
  • the device embodiments described above are merely illustrative, wherein the modules described as separate components may or may not be physically separate, and the components displayed as modules may or may not be physical modules, ie may be located in one place. Or it can be distributed to multiple network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the embodiment. Those of ordinary skill in the art can understand and implement without deliberate labor.
  • a machine-readable medium includes read only memory (ROM), random access memory (RAM), magnetic disk storage media, optical storage media, flash storage media, electrical, optical, acoustic, or other forms of propagation signals (eg, carrier waves) , an infrared signal, a digital signal, etc., etc., the computer software product comprising a number of instructions for causing a computer device (which may be a personal computer, server, or network device, etc.) to perform portions of various embodiments or embodiments .
  • ROM read only memory
  • RAM random access memory
  • magnetic disk storage media e.g., magnetic disks, magnetic disk storage media, optical storage media, flash storage media, electrical, optical, acoustic, or other forms of propagation signals (eg, carrier waves) , an infrared signal, a digital signal, etc., etc.
  • the computer software product comprising a number of instructions for causing a computer device (which may be a personal computer, server, or network device, etc.) to perform portions of various embodiment
  • the computer program instructions can also be stored in a computer readable memory that can direct a computer or other programmable data processing device to operate in a particular manner, such that the instructions stored in the computer readable memory produce an article of manufacture comprising the instruction device.
  • the device is implemented in a flow chart A function specified in a block or blocks of a process or multiple processes and/or block diagrams.
  • These computer program instructions can also be loaded onto a computer or other programmable data processing device such that a series of operational steps are performed on a computer or other programmable device to produce computer-implemented processing for execution on a computer or other programmable device.
  • the instructions provide steps for implementing the functions specified in one or more of the flow or in a block or blocks of a flow diagram.

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Abstract

本申请实施例提供一种一键开机处理方法及终端,所述方法包括:在检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机;若是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理,从而使得在终端的开机过程用户只需要进行一次按压操作便可完成终端开机的过程,增加了便利性,且有效提高终端的用户体验。

Description

一键开机处理方法及终端 技术领域
本申请实施例涉及电子技术领域,尤其涉及一种一键开机处理方法及终端。
背景技术
随着移动终端引入指纹特征识别技术,指纹认证代替了传统的密码认证、手势动作认证等,使得认证不再需要其他操作,只需要手指与传感器接触即可,在保证电子终端安全的同时,极大地增加了移动终端使用的便利性,从而使得指纹特征识别功能成了电子终端甚至是传统的电子产品的标配。
以将上述指纹特征识别技术应用到笔记本电脑上为例,首先通过指纹注册过程注册指纹,成功注册一个指纹后,在开机启动之后,在操作系统锁屏和登录界面出现一个指纹登录选项,用户在指纹特征识别模组上滑动或按压注册过的手指,即可实现解锁或登录,从而完成终端的开机全过程。
但是,对于传统使用指纹技术进行操作系统登录的场景,指纹特征识别模组一般设置在笔记本电脑的键盘右侧靠下位置,在使用过程中用户需要首先按压电源按键进行开机,再按压指纹特征识别模组进行指纹登录,由此导致终端的开机过程用户需要进行至少两次按压操作,因此影响终端开机效率且用户体验较差。
发明内容
本申请实施例的目的在于提供一种一键开机处理方法及终端,用以至少解决现有技术中的上述问题。
为实现本申请实施例的目的,本申请实施例提供了一种一键开机处理方法,所述方法应用于具有电源按键的终端,且所述终端包括生物特征识别模组,用于在操作主体按压所述电源按键过程中对所述操作主体的生物特征数据进行采集,所述方法包括:
在检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机;
若是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
本申请实施例还提供一种终端,其包括电源按键、生物特征识别模组、微处理器;其中,所述生物特征识别模组设置在电源按键上,用于采集按压所述电源按键的操作主体的生物特征数据,所述微处理器用于在生物特征识别模组检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机,并在触发所述终端进行一键开机时提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
本申请实施例中,在操作主体对电源按键按压时生物特征识别模组可采集到操作主体的生物特征数据,在检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机,若是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理,从而使得在终端的开机过程用户只需要进行一次按压操作便可完成终端开机的过程,增加了便利性,且有效提高终端的用户体验。
附图说明
图1为本申请实施例一中一键开机处理方法的流程示意图;
图2为本申请实施例二中一键开机处理方法的流程示意图;
图3为本申请实施例三中一键开机处理方法的流程示意图;
图4为发明实施例四中一键开机处理方法的流程示意图;
图5为发明实施例五中一键开机处理方法的流程示意图;
图6为本申请实施例六中一种终端的结构示意图;
图7为本申请实施例七一键开机预处理阶段的流程示意图;
图8为本申请实施例八中一键开机登录阶段的过程示意图;
图9为本申请实施例九中的软件架构示意图。
具体实施方式
以下将配合图式及实施例来详细说明本申请的实施方式,藉此对本申请如何应用技术手段来解决技术问题并达成技术功效的实现过程能充分理解并据以实施。
本申请实施例中,在操作主体对电源按键按压时生物特征识别模组可采集到操作主体的生物特征数据,在检测到电源按键在当前时刻被按压时,判断电源按键在当前时刻被按压是否触发终端进行一键开机,若是,则提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理,从而使得在终端的开机过程用户需要进行一次按压操作便可完成终端开机的过程,增加了便利性且有效提高用户体验。
本申请下述实施例中,生物特征识别模组和电源按键在终端上的设置位置可以实现在按压电源按键时,生物特征识别模组可以同时采集到操作主体的生物特征数据,比如,将生物特征识别模组直接贴在电源按键上或者以其他形式安装到电源按键,设置在终端的同一位置处,从而实现用户只要按压一次,即可完成终端的开机和登录,此过程可理解为一键开机,无需如现有技术中必须分别按压电源按键和指纹特征识别模组而需要用户执行至少两次按压操作。
图1为本申请实施例一中一键开机处理方法的流程示意图;如图1所示,本实施例中,所述方法应用于具有电源按键的终端,且所述终端包括生物特征识别模组,用于在操作主体按压所述电源按键过程中对所述操作主体的生物特征数据进行采集,方法具体包括:
S101、检测到电源按键在当前时刻被按压;
本实施例中,以将一键开机应用到笔记本电脑上为例,生物特征识别模组以指纹特征识别模组为例,电源按键与指纹特征识别模组设置在笔记本的同一位置处,使得在触压电源按键时,同时触压在指纹特征识别模组上,比如在现有笔记本电脑的电源按键设置位置处,将指纹特征识别模组粘贴在电源按键上表面,从而确保一键开机的实现。类似地,在台式机的电源按键设计上也可以采用类似方案,详细不再赘述。
本实施例中,在步骤S101中检测电源按键在当前时刻被按压时,可以根据对预先注册有按压事件进行监控从而检测是否有电源按键在当前时刻被按压。比如,在当前时刻被按压之前,向指纹特征识别模组预先注册按 压事件,以当有手指直接按压在指纹特征识别模组上同时间接按压到电源按键上,注册按压事件反映有手指按压的动作发生。但是,需要说明的是,检测电源按键在当前时刻被按压并局限于只能通过预先注册按压事件的方式,还可以通过其他硬件或者软硬结合的方式来实现。
S102、判断电源按键在当前时刻被按压是否触发终端进行一键开机;若是,则执行步骤S103;否则,禁止一键开机处理。
本实施例中,在步骤S102中判断电源按键在当前时刻被按压是否触发终端进行一键开机时,具体可以判断设定时间内上电开机电信号是否被使能,在设定时间内上电开机电信号被使能时,判定电源按键在当前时刻被按压触发了终端进行一键开机。
本实施例中,在windows操作系统的终端上,上电开机电信号可具体是嵌入式控制器(Embedded Contronller,简称EC)的输出信号在设定的时间内是否电平是否被拉高,比如在2s内,嵌入式控制器的输出信号是否被拉高至电平,如果是,判定上电开机电信号被使能,进而可判定电源按键在当前时刻被按压触发了终端进行一键开机;否则,则判定电源按键在当前时刻被按压未触发终端进行一键开机。
本实施例中,禁止一键开机后,采集到的生物特征数据并不会被提交给终端的操作系统,比如,系统可以在终端登录界面中提示再次进行生物特征数据的采集,即需要再次按压电源按键,从而使得生物特征识别模组进行生物特征数据的再次采集。
S103、提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理。
本实施例中,如果操作主体是手指,则生物特征数据可以是指纹图像,如果是掌纹,则可以是掌纹图像等。在其他实施例中,生物特征数据比如还可以血样数据或者心率数据。在具体实现上,终端可以根据实际生物特征数据的检测需要在电源按键上方设置相应的生物特征识别模组,或者,所述生物特征识别模组也可以同时支持两种以上的生物特征数据的采集和检测。
本实施例中,在步骤S103中,可以具体根据生物特征数据验证请求,提交被生物特征识别模组采集到的生物特征数据至终端的操作系统。生物特征数据验证请求的存在从而自动触发了生物特征数据的提交,以使得在 开机的过程中操作系统调用生物特征驱动对生物特征数据进行匹配,即进行数据合法性认证,如果合法性认证应用到笔记本电脑登录权限的验证,即确定当前用户是否具有合法的权限登录并使用终端。
图2为本申请实施例二中一键开机处理方法的流程示意图;如图2所示,方法具体包括:
S201、检测到电源按键在当前时刻被按压;
本实施例中,步骤S201类似上述图1中的步骤S101,在此不再赘述。
S202、生物特征识别模组采集生物特征数据;
本实施例中,步骤S202中生物特征识别模组在采集生物特征数据时,具体可以通过终端的操作系统调用生物特征驱动从而使生物特征识别模组采集生物特征数据。如前,生物特征数据可以是指纹图像或者血样数据或者心率数据等。
与上述图1实施例不同的是,本实施例中,在步骤S201和步骤S203之间增加了生物特征数据的采集步骤,需要说明的是,对采集到的生物特征数据进行暂存处理,以在步骤S204中提交给终端的操作系统。
S203、判断电源按键在当前时刻被按压是否触发终端进行一键开机,若是,则执行步骤S204;否则,禁止一键开机处理。
本实施例中,步骤S203类似上述图1实施例中的步骤S102,但与上述实施例不同的是,在判断是否触发一键开机之前完成了生物特征数据的实时采集。
S204、提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理。
本实施例中,如前,由于在检测到电源按键被按压和判断是否触发一键开机之间完成了生物特征数据的采集以及暂时存储,因此,在本实施例中,步骤S204中在提交电源按键被生物特征识别模组采集到的生物特征数据至终端的操作系统时,可以直接拉取(pull)存储的生物特征数据并提交至终端的操作系统。具体地,在通过中断的方式启动生物特征数据至终端的操作系统的拉取。
在上述图2实施例的基础上,还可以包括:若电源按键在当前时刻被按压未触发终端进行一键开机,则在禁止一键开机处理的同时,抛弃电源 按键在当前时刻被按压时被生物特征识别模组采集到的生物特征数据。
图3为本申请实施例三中一键开机处理方法的流程示意图;如图3所示,方法具体包括:
S301、检测到电源按键在当前时刻被按压;
S302、判断电源按键在当前时刻被按压是否触发终端进行一键开机;若是,则执行步骤S303;否则,禁止一键开机处理。
S303、生物特征识别模组采集生物特征数据;
S304、提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理。
本实施例中,与上述图2实施例不同的是,在判定电源按键当前时刻被按压触发了终端进行一键开机之后再进行生物特征数据的采集,因此,可以不对采集的生物特征数据进行暂存,而直接由步骤S304提交给终端的操作系统,从而提高了数据处理的时效性。
在图3实施例的基础上,如果判断电源按键在当前时刻被按压未触发终端进行一键开机,则可以禁止一键开机处理,同时,不再执行步骤S303和步骤S304。
图4为发明实施例四中一键开机处理方法的流程示意图;如图4所示,方法具体包括:
S401、检测到电源按键在当前时刻被按压;
本实施例中,步骤S401类似上述图1实施例中步骤S101,在此不再赘述。
S402、判断是否存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则执行步骤S403;否则,禁止一键开机处理。
本实施例中,如果终端处于睡眠状态,则终端的电源状态用S3表示;如果终端处于休眠状态,则终端的电源状态用S4表示;如果终端处于关机状态,则终端的电源状态用S5表示。以笔记本电脑为例,进入睡眠状态时硬盘关闭,内存处于活动状态,操作系统状态保存在内存中,电源在持续不断地给内存供电;进入休眠状态时,操作系统把内存里的所有数据存放在硬盘上,此时电源在给硬盘供电,之后电源停止向内存、硬盘、CPU供 电;进入关机状态时,电源直接停止向CPU、内存、硬盘供电。
本实施例中,在当前时刻之前对电源按键进行按压或者通过其他方式使得终端进入睡眠状态或者休眠状态或者关机状态完成之后,当通过步骤S401检测到电源按键在当前时刻被按压,则初步判定当前时刻对电源按键的按压可能要将终端从睡眠状态或者休眠状态或者关机状态中唤醒使得终端进入一键开机处理。为此,本实施例中,在当前时刻之前对电源按键进行按压以使得终端进入睡眠状态或者休眠状态或者关机状态完成之后,将对应的电源状态进行存储,以在检测到有按压时,进行是否触发一键开机的初步判断。
进一步地,如果通过步骤S402判定不存在终端进入睡眠状态或者休眠状态或者关机状态对应的电源状态,则表明当前时刻对电源按键的按压属于误操作,并不需要进入一键开机处理,因此,可直接禁止一键开机处理。
另外,是否存储当前时刻之前对电源按键进行按压以使得终端进入睡眠状态或者休眠状态或者关机状态对应的电源状态可在终端上进行设置,如果在终端上设置了需要存储,则表明当后续S403判断结果为是的时候,可进入一键开机处理,否则,表明当电源按键被按压时不需要进入一键开机处理。换句话,通过存储终端进入睡眠状态或者休眠状态或者关机状态对应的电源状态可以是否需要进行一键开机处理功能进行定制。
S403、判断电源按键在当前时刻被按压是否触发终端进行一键开机;若是,则执行步骤S404;否则,禁止一键开机处理。
本实施例中,如前,可以通过上电开机信号是否被使能从而判断是否触发了一键开机。
进一步地,判断电源按键在当前时刻被按压是否触发终端进行一键开机可以通过操作系统关机掉电信号的使能来判定,如果关机掉电信号被使能,则可间接判定电源按键在当前时刻被按压未触发终端进行一键开机,直接禁止一键开机处理;若通过操作系统关机掉电信号未被使能,则再结合上述实施例一中的开机上电信号是否被使能,从而判断是否触发终端进行一键开机。
S404、提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理。
本实施例中,步骤S404类似上述实施例记载,在此不再赘述。
本实施例中,在检测到电源按键在当前时刻被按压和判断是否触发一键开机处理之间增加了判断是否存在对应睡眠状态或者休眠状态或者关机状态时对应的电源状态,即相当于首先判断是否给终端定制了一键开机处理功能,再判断是否满足一键开机处理的触发条件,如果定制了一键开机处理且满足触发条件,则执行步骤S404;否则,禁止一键开机处理。
图5为发明实施例五中一键开机处理方法的流程示意图;如图5所示,方法具体包括:
S501、检测到电源按键在当前时刻被按压;
S502、判断电源按键在当前时刻被按压是否触发终端进行一键开机;若是,则执行步骤S503;否则,禁止一键开机处理。
S503、判断是否存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则执行步骤S504;否则,禁止一键开机处理。
S504、提交被生物特征识别模组采集到的生物特征数据至终端的操作系统以进行一键开机处理。
本实施例中,与上述图4实施例不同的是,在判断是否触发一键开机之后,提交生物特征数据之前增加了判断是否存在睡眠状态或者休眠状态或者关机状态时对应的电源状态,如前,相当于首先判断是否满足一键开机处理的触发条件,再判断是否定制了一键开机处理功能。
如果参照图2、图3实施例中在上述图4、图5的实施例中增加了采集生物特征数据,则在图4、图5的实施例基础上,一键开机处理方法还可以包括:如果不存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态,则在禁止一键开机处理的同时抛弃被生物特征识别模组采集到的生物特征数据。
需要说明的是,在上述方法实施例中,如果操作系统还没启动,则等待所述终端的操作系统启动,在所终端的操作系统启动之后再提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
图6为本申请实施例六中一种终端的结构示意图;如图6所示,其包括电源按键601、微处理器602、生物特征识别模组603,其中,所述生物特征识别模组603比如设置在电源按键601上,所述生物特征识别模组603用于采集按压所述电源按键的操作主体的生物特征数据;所述微处理器602用于在生物特征识别模组603检测到电源按键601在当前时刻被按压时,判断电源按键601在当前时刻被按压是否触发终端进行一键开机并在触发所述终端进行一键开机时提交被生物特征识别模组603采集到的生物特征数据至终端的操作系统以进行一键开机处理。本实施例中,微处理器602与生物特征识别模组603通过串行外设接口(Serial Peripheral Interface,SPI)方式进行通信,或者,通过通用串行总线(Universal Serial Bus,USB)方式进行通信。
本实施例或其他任一实施例中,微处理器602进一步用于在设定时间内上电开机电信号被使能时,判定电源按键601在当前时刻被按压触发了终端进行一键开机。
本实施例或其他任一实施例中,微处理器602进一步用于根据生物特征数据验证请求,提交被生物特征识别模组603采集到的生物特征数据至终端的操作系统。
本实施例或其他任一实施例中,微处理器602进一步用于使能生物特征识别模组603采集生物特征数据。
本实施例或其他任一实施例中,终端的操作系统调用生物特征驱动以使生物特征识别模组603采集生物特征数据。
本实施例或其他任一实施例中,生物特征驱动拉取微处理器602存储的生物特征数据以提交至终端的操作系统。
本实施例或其他任一实施例中,生物特征驱动通过中断的方式通知微处理器602以从微处理器602拉取存储的生物特征数据。
本实施例或其他任一实施例中,微处理器602用于在电源按键601在当前时刻被按压未触发终端进行一键开机时,抛弃电源按键601在当前时刻被按压时被生物特征识别模组603采集到的生物特征数据。
本实施例或其他任一实施例中,微处理器602进一步用于在判断所述电源按键在当前时刻被按压是否触发终端进行一键开机之前,判断是否存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果 是,则再判断电源按键601在当前时刻被按压是否触发终端进行一键开机;
或者,微处理器602进一步用于在判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之后,判断是否存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则提交被生物特征识别模组603采集到的生物特征数据至终端的操作系统。
本实施例或其他任一实施例中,微处理器602还用于在不存在终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态时,抛弃被生物特征识别模组603采集到的生物特征数据。
本实施例中,生物特征识别模组603可以基于光线发射原理来实现,也可以基于电容效应原理来实现。在基于光线发射原理的指纹特征模组中,通过指纹的谷脊对光线的反射程度不同形成指纹特征数据,而在基于电容效应原理的指纹特征模组中,通过指纹的估计凸凹形成大小不同的电容以形成指纹特征数据。
下面以具体应用示例,对上述方法、操作系统实施例在笔记本电脑上使用指纹实现一键开机场合进行直观的说明。为此,为了便于清楚的解释,将一键开机在产品上的具体实现过程示例性地分为两个阶段来进行说明:一键开机预处理阶段和一键开机登录阶段。
图7为本申请实施例七一键开机预处理阶段的流程示意图;即在笔记本电脑记本电脑进入睡眠状态或者休眠状态或者关机状态过程中的一系列处理,如图7所示,其包括:
(1)用户(user)按压电源按键/指纹特征识别装置,产生断电power off事件,从而使得笔记本电脑进入睡眠状态或者休眠状态或者关机状态,对应的电源状态为S3或S4或S5(enter S3/S4/S5);
(2)指纹特征识别驱动注册EvtDeviceDOExit事件回调函数,笔记本电脑的操作系统(OS)调用EvtDeviceDOExit(call EvtDeviceDOExit),在EvtDeviceDOExit事件回调函数中调用WdfDeviceGetSystemPowerAction函数,从而获取终端对应的电源状态Sx(S3或S4或S5);
(3)指纹特征识别驱动将电源状态发送给微处理器进行存储(send power state Sx);
(4)微处理器向指纹特征识别模组注册电源按键被按压事件,以使得指纹特征识别模组实时检测电源按键被按压事件从而检测电源按键是否被按压;
(5)微处理器进入低功耗模式(switch low power mode),比如进入睡眠模式。
通过上述图7的过程,当笔记本电脑进入睡眠状态或者休眠状态或者关机状态时,存储对应睡眠状态或者休眠状态或者关机状态的电源状态,同时,提供了一种注册电源按键被按压事件的方式,以在检测电源按键被再次按压的发生。
图8为本申请实施例八中一键开机登录阶段的过程示意图;如图8所示,其包括:
(1)用户(user)当前时刻按压电源按键/指纹特征识别模组,产生power on事件,以进入唤醒状态(resume from S3/S4/S5);
由于图7预处理时微处理器向指纹特征识别模组注册电源按键被按压事件,因此,指纹特征识别模组检测到有电源按键被按压(detected finger-down)。
(2)指纹特征识别模组以中断的形式通知微处理器(MCU)已检测到有电源按键被按压,将处于睡眠状态的微处理器唤醒;
(3)MCU控制指纹特征识别模组去采集指纹特征数据,比如一帧指纹特征数据,并获取并存储采集到的指纹特征数据。
(4)微处理器判断电源按键在当前时刻被按压是否触发终端进行一键开机;
指纹特征识别模组(5)指纹特征识别驱动从微处理器处获取存储的指纹特征数据如指纹图像(query Fingerprint image);
(5)微处理器将存储的指纹特征数据发送给指纹特征识别驱动(send Fingerprint image)并由指纹特征识别驱动进行存储(save Fingerprint image)
由于指纹特征识别驱动注册EvtDeviceDOEntry回调函数,操作系统从电源状态S3/S4/S5恢复后,将调用一次EvtDeviceDOEntry,可以通过EvtDeviceDOEntry函数指纹特征识别驱动与微处理器建立通信,微处理器 查询是否有存储的指纹特征数据,并将查询到的指纹特征数据提交给指纹特征识别驱动。
(6)操作系统(os)向指纹特征识别驱动发送指纹特征数据请求(send capture request);
比如通过IOCTL_BIOMETRIC_CAPTURE_DATA发送指纹特征数据请求。
(7)指纹特征识别驱动响应发送指纹特征数据请求,待终端的操作系统启动之后将指纹特征数据提交给终端的操作系统;
(8)终端的操作系统调用匹配引擎(engine adapter)对对指纹特征数据进行匹配;
(9)匹配引擎向操作系统返回合法性验证通过的结果(complete capture request with Fingerprint image);
(10)笔记本电脑完成登录。
如前所述,其另外一具体实施场景中,也可以先判断是否存在合法性认证触发条件,如果存在,再采集指纹特征数据,之后再进行指纹特征数据的存储和获取,详细不再赘述。
图9为本申请实施例九中的软件架构示意图;如图9所示,本实施例中以在windows 10上实现上述实施例技术方案的架构,从硬件上包括:上述生物特征识别装置以及微处理器,windows软件层面上包括:生物特征应用(Biometric Application)、windows biometric api(windows生物特征api接口)、windows生物特征服务(windows biometric service)、用户模式驱动程序框架进程(WUDFhost.exe),生物特征应用(Biometric Application)包括利用指纹特征数据进行登录,windows生物特征服务涉及到生物特征采集(finger sensor)、生物特征匹配(engine adapter)、生物特征数据的存储数据库(database),用户模式驱动程序框架进程包括生物特征识别驱动(如fingerprint device drive)、用户模式驱动架构(wudf framework support)、简单外围总线I/O接口(Simple Peripheral Bus I/O target,简称SPB I/O target),简单外围总线(Simple Peripheral Bus,简称SPB)。简单外围总线I/O接口可用于微处理器与生物特征识别驱动进行基于串行外设接口总线(Serial Peripheral Interface,SPI)的交互。
需要说明的是,为了实现本申请的目的,在用户模式驱动程序框架进 程中增加了指纹特征识别驱动(fingerprint device drive)以及在windows生物特征服务增加了指纹特征匹配(engine adapter)。
以上所描述的装置实施例仅仅是示意性的,其中作为分离部件说明的模块可以是或者也可以不是物理上分开的,作为模块显示的部件可以是或者也可以不是物理模块,即可以位于一个地方,或者也可以分布到多个网络模块上。可以根据实际的需要选择其中的部分或者全部模块来实现本实施例方案的目的。本领域普通技术人员在不付出创造性的劳动的情况下,即可以理解并实施。
通过以上的实施方式的描述,本领域的技术人员可以清楚地了解到各实施方式可借助软件加必需的通用硬件平台的方式来实现,当然也可以通过硬件。基于这样的理解,上述技术方案本质上或者说对现有技术做出贡献的部分可以以软件产品的形式体现出来,该计算机软件产品可以存储在计算机可读存储介质中,计算机可读记录介质包括用于以计算机(例如计算机)可读的形式存储或传送信息的任何条件。例如,机器可读介质包括只读存储器(ROM)、随机存取存储器(RAM)、磁盘存储介质、光存储介质、闪速存储介质、电、光、声或其他形式的传播信号(例如,载波、红外信号、数字信号等)等,该计算机软件产品包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行各个实施例或者实施例的某些部分的方法。
本申请是参照根据本申请实施例的方法、装置(设备)和计算机程序产品的流程图和/或方框图来描述的。应理解可由计算机程序指令实现流程图和/或方框图中的每一流程和/或方框、以及流程图和/或方框图中的流程和/或方框的结合。可提供这些计算机程序指令到通用计算机、专用计算机、嵌入式处理机或其他可编程数据处理设备的处理器以产生一个机器,使得通过计算机或其他可编程数据处理设备的处理器执行的指令产生用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的装置。
这些计算机程序指令也可存储在能引导计算机或其他可编程数据处理设备以特定方式工作的计算机可读存储器中,使得存储在该计算机可读存储器中的指令产生包括指令装置的制造品,该指令装置实现在流程图一个 流程或多个流程和/或方框图一个方框或多个方框中指定的功能。
这些计算机程序指令也可装载到计算机或其他可编程数据处理设备上,使得在计算机或其他可编程设备上执行一系列操作步骤以产生计算机实现的处理,从而在计算机或其他可编程设备上执行的指令提供用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的步骤。
尽管已描述了本申请的优选实施例,但本领域内的技术人员一旦得知了基本创造性概念,则可对这些实施例作出另外的变更和修改。所以,所附权利要求意欲解释为包括优选实施例以及落入本申请范围的所有变更和修改。显然,本领域的技术人员可以对本申请进行各种改动和变型而不脱离本申请的精神和范围。这样,倘若本申请的这些修改和变型属于本申请权利要求及其等同技术的范围之内,则本申请也意图包含这些改动和变型在内。

Claims (22)

  1. 一种一键开机处理方法,其特征在于,所述方法应用于具有电源按键的终端,且所述终端包括生物特征识别模组,用于在操作主体按压所述电源按键过程中对所述操作主体的生物特征数据进行采集,所述方法包括:
    在检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机;
    若是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
  2. 根据权利要求1所述的处理方法,其特征在于,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机包括:在设定时间内上电开机电信号被使能时,判定所述电源按键在当前时刻被按压触发了所述终端进行一键开机。
  3. 根据权利要求1所述的处理方法,其特征在于,提交被生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统包括:
    根据生物特征数据验证请求,提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统。
  4. 根据权利要求1所述的处理方法,其特征在于,还包括:
    在检测到所述电源按键在当前时刻被按压之后,且判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之前,所述生物特征识别模组采集所述生物特征数据;
    或者,在当前时刻被按压触发了所述终端进行开机之后,提交所述生物特征数据至所述终端的操作系统之前,所述生物特征识别模组采集所述生物特征数据。
  5. 根据权利要求4所述的处理方法,其特征在于,所述生物特征识别模组采集所述生物特征数据包括:
    所述终端的操作系统调用生物特征驱动以使所述生物特征识别模组采集所述生物特征数据。
  6. 根据权利要求1所述的处理方法,其特征在于,提交所述电源按键被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统包括:拉取存储的所述生物特征数据并提交至所述终端的操作系统。
  7. 根据权利要求6所述的处理方法,其特征在于,通过中断的方式启动所述生物特征数据至所述终端的操作系统的拉取。
  8. 根据权利要求1-7任一项所述的处理方法,还包括:若所述电源按键在当前时刻被按压未触发所述终端进行一键开机,则抛弃所述电源按键在当前时刻被按压时被所述生物特征识别模组采集到的所述生物特征数据。
  9. 根据权利要求1所述的处理方法,其特征在于,还包括:在判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之前,判断是否存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则再判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机;
    或者,在判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之后,判断是否存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统。
  10. 根据权利要求9所述的处理方法,其特征在于,还包括:如果不存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态,则抛弃被所述生物特征识别模组采集到的所述生物特征数据。
  11. 根据权利要求1所述的处理方法,其特征在于,所述电源按键和所述生物特征识别模组组合在一起并设置在所述终端的同一位置上。
  12. 根据权利要求1所述的处理方法,其特征在于,还包括:等待所述终端的操作系统启动,在所终端的操作系统启动之后再提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
  13. 一种终端,其特征在于,包括电源按键、生物特征识别模组和微处理器;其中,所述生物特征识别模组设置在电源按键上,用于采集按压所述电源按键的操作主体的生物特征数据;所述微处理器用于在所述生物特征识别模组检测到所述电源按键在当前时刻被按压时,判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机,并在触发所述终端进行一键开机时提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统以进行一键开机处理。
  14. 根据权利要求13所述的终端,其特征在于,所述微处理器进一步用于在设定时间内上电开机电信号被使能时,判定所述电源按键在当前时刻被按压触发了所述终端进行一键开机。
  15. 根据权利要求13所述的终端,其特征在于,所述微处理器进一步用于根据生物特征数据验证请求,提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统。
  16. 根据权利要求13所述的终端,其特征在于,所述微处理器进一步用于使能所述生物特征识别模组采集所述生物特征数据。
  17. 根据权利要求16所述的终端,其特征在于,所述终端的操作系统调用生物特征驱动以使所述生物特征识别模组采集所述生物特征数据。
  18. 根据权利要求17所述的终端,其特征在于,生物特征驱动拉取所述微处理器存储的所述生物特征数据以提交至所述终端的操作系统。
  19. 根据权利要求18所述的终端,其特征在于,所述生物特征驱动通过中断的方式通知所述微处理器以从所述微处理器拉取存储的所述生物特征数据。
  20. 根据权利要求13-19任一项所述的终端,所述微处理器还用于在所述电源按键在当前时刻被按压未触发所述终端进行一键开机时,抛弃所述电源按键在当前时刻被按压时被所述生物特征识别模组采集到的所述生物特征数据。
  21. 根据权利要求13所述的终端,其特征在于,所述微处理器进一步用于在判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之前,判断是否存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则再判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机;
    或者,所述微处理器进一步用于在判断所述电源按键在当前时刻被按压是否触发所述终端进行一键开机之后,判断是否存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态;如果是,则提交被所述生物特征识别模组采集到的所述生物特征数据至所述终端的操作系统。
  22. 根据权利要求21所述的终端,其特征在于,所述微处理器还用于在不存在所述终端处于睡眠状态或者休眠状态或者关机状态时对应的电源状态时,抛弃被所述生物特征识别模组采集到的所述生物特征数据。
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