JP2018064173A - Portable terminal device and method of controlling screen state and power state - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow for transition to a user's intended screen state or power state in response to one touch operation of an operation button.SOLUTION: A system 200 transits to any one of multiple screen states and power states. A fingerprint scanner 101 and an operation switch 105 are built in an operation button 100, and fingerprint authentication results are generated by one-touch operation and the operation switch generates a power signal. An authentication unit 203 changes the screen state of the system according to the authentication results. A power block 207 changes the power state of the system according to the power signal. When one-touch operation was performed in a prescribed screen state, a power controller 209 checks transmission of the power signal to the power block. With such an arrangement, the power state can be prevented from being changed before the authentication unit changes the screen state by one-touch operation.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a technique for controlling a screen state and a power state of a mobile terminal device using operation buttons.

  Smartphones and tablet terminals have operation buttons such as a power button and a home button for changing the power state and the screen state. The screen state includes a lock screen state, a power off state, and a home screen state. The power state includes a power-on state, a power-off state, and a low power state. Some smartphones allow a transition to the home screen state by performing fingerprint authentication when in the lock screen state. In recent years, an operation button that incorporates a fingerprint scanner for fingerprint authentication has appeared. Such an operation button is hereinafter referred to as a fingerprint authentication (FPA) built-in button.

  Patent Document 1 discloses an invention in which a pseudo start signal is generated to start a computer when fingerprint authentication is successful in a fingerprint authentication device. Patent Document 2 discloses an invention in which a display state is changed by an activation button provided in a mobile communication terminal. Patent document 3 discloses the invention which changes the display mode of a screen with the power button provided in the smart phone. Non-Patent Document 1 discloses a smartphone in which a power key, a screen lock key, and a fingerprint sensor are stored in one button. By operating the button, it is possible to perform power activation, control to a sleep state, screen lock, unlock by fingerprint authentication, and the like.

JP 2010-146048 A JP 2014-239478 A JP 2014-187415 A

docomo, “XPERIA Z5 User's Manual”, [online], February 2016, [Search September 5, 2016], Internet <URL: https://www.nttdocomo.co.jp/support/trouble/ manual / download / so01h / index.html>

  The FPA built-in button performs fingerprint authentication when a finger is placed on the operation surface, and generates a power signal when pressed. Therefore, when the FPA built-in button is pressed, a result of fingerprint authentication and a power signal are generated. The power signal is generated as soon as the switch of the FPA built-in button is made, but it takes a certain time from the time when the fingerprint is scanned until the result of fingerprint authentication is generated. Also, the fingerprint authentication time becomes longer when there is an influence of the condition of the finger surface or the contamination of the fingerprint scanner, leading to authentication failure in some cases.

  When the FPA built-in button is pressed quickly, a power signal may be generated first, followed by a fingerprint authentication result. In addition, when the FPA built-in button is pushed slowly, a result of fingerprint authentication is generated first, and then a power signal may be generated. For example, when in the lock screen state, the user expects to perform fingerprint authentication and transition to the home screen state. At this time, if the FPA built-in button is operated by a careless or unfamiliar user, there may be a transition to the low power state.

  Further, if the power signal continues when the home screen state is changed, the home screen state may change to the low power state or the power off state. A similar problem occurs when the FPA built-in button is operated in the home screen state requiring fingerprint authentication. An object of the present invention is to solve the problems that occur in the operation of the FPA built-in button as described above.

  In one aspect of the invention, the system transitions to any of a plurality of screen states and power states. The operation button can generate a result of fingerprint authentication by one-touch operation and further generate a power signal. The authentication unit changes the screen state of the system according to the result of fingerprint authentication. The power block changes the power state of the system according to the power signal. The controller prevents transmission of a power signal to the power block when a one-touch operation in a predetermined screen state is performed.

  The power controller can be configured with a hardware layer located in the lower layer of the system. The power block and the authentication unit may change the power state and the screen state asynchronously with each other. The power controller can prevent transmission of the power signal when it receives a signal indicating a standby state for fingerprint authentication. The transition source of the screen state can be the lock screen state or the home screen state, and the corresponding transition destination can be the home screen state or the authentication success screen state.

  The power block can transition the system to a low power state when the reception time of the power signal is less than the first threshold, and can transition the system to the power off state when the reception time is greater than or equal to the first threshold. At this time, the power controller can block the transmission of the power signal for a time corresponding to a second threshold value smaller than the first threshold value. At this time, the power block can transition the system to the power-off state when the reception time after the transmission of the power signal is canceled is equal to or greater than the first threshold.

  In another aspect of the present invention, the mobile terminal device includes an operation button and a power button. The operation button generates a result of fingerprint authentication by a one-touch operation and further generates a first power signal. The authentication unit changes the system from the first screen state to the second screen state in accordance with the result of fingerprint authentication. The power button outputs a second power signal when pressed. The power block changes the power state of the system according to the first power signal and the second power signal. The switch element prevents transmission of the first power signal to the power block when a one-touch operation in the first screen state is performed.

  The first screen state can be a lock screen state that prohibits execution of the application program, and the second screen state can be a home screen state that allows execution of the application program. Further, the first screen state can be a home screen state that requires fingerprint authentication, and the second screen state can be a successful authentication screen state. The power block may transition the system to a low power state or a power off state when receiving a second power signal in the first screen state.

  According to the present invention, it is possible to transit to a screen state or a power state intended by the user in accordance with an operation of an operation button including an operation switch for generating a fingerprint scanner and a power signal. Furthermore, according to the present invention, the above-described problems can be solved by hardware alone without changing the system.

It is the top view and side view which show the external shape of the smart phone 10 which is an example of a portable terminal device. 2 is a diagram illustrating an example of a functional block diagram of a smartphone 10. FIG. It is a state transition diagram for demonstrating the power state and screen state of the smart phone. It is a figure for demonstrating the transition conditions in the state transition diagram of FIG. 6 is a diagram for explaining a relationship between power state transition and a reception time tx of a power signal received by a power block 207. FIG. It is a flowchart which shows the process sequence when one-touch operation is performed to the operation button 100 in the lock screen state. It is a flowchart which shows the process sequence when one-touch operation is performed to the operation button 100 in the home screen state which performs a specific application. It is the top view and side view which show the external shape of the smart phone 50 which comprised the home button with the FPA built-in button. It is a figure which shows an example of the functional block diagram of the smart phone.

[Mobile terminal device]
The present invention can be applied to portable terminal devices such as smartphones, tablet terminals, and laptop portable computers. FIG. 1 is a plan view and a side view showing an outer shape of a smartphone 10 which is an example of a mobile terminal device. In the present specification, the same reference numerals are given to the elements that are the same or can be interpreted as the same in understanding the present invention. Since the external shape of the smartphone 10 is well known, only typical elements are shown in FIG. A touch screen 11, a front camera lens 21, a speaker 17, and a microphone 19 are arranged on the surface of the smartphone 10. Further, an LED 103, an operation button 100, a volume button 13, and a camera button 15 are arranged on the side surface.

  FIG. 2 is a diagram illustrating an example of a functional block diagram of the smartphone 10. The application processing unit 201 executes an application and an OS in cooperation with the input / output device 202. When the application executed in the home screen state 307 (FIG. 3) requires user authentication, the application processing unit 201 requests password authentication or fingerprint authentication from the authentication unit 203. The input / output device 202 includes a wireless module, a GPS module, and the like in addition to the touch screen 11, the speaker 17, the microphone 19, the volume button 13, the camera button 15, and the like.

  The authentication unit 203 authenticates a passcode (PIN) for shifting from the lock screen state 305 (FIG. 3) to the home screen state 307. The authentication unit 203 performs password authentication based on a request from an application executed in the home screen state 307. The authentication unit 203 authenticates the user by comparing the PIN and password registered in advance with the PIN and password input from the touch screen 11 constituting the input / output device 202.

  The authentication unit 203 can authenticate the user by receiving the PIN or password from the fingerprint authentication device 213 instead of inputting the PIN or password. The authentication unit 203 sends an authentication request to the fingerprint authentication device 213 when the system 200 requires fingerprint authentication. The application processing unit 201 and the authentication unit 203 are well-known elements configured by hardware such as a CPU, a system memory, and an I / O controller, and software such as an OS, an application program, and a device driver. The application processing unit 201, the input / output device 202, and the authentication unit 203 constitute a system 200 of the smartphone 10.

  The operation button 100 is an FPA built-in button in which the fingerprint scanner 101 and the operation switch 105 are combined. The fingerprint scanner 101 scans the fingerprint of the finger touching the operation button 100 and outputs a fingerprint image to the fingerprint authentication device 213. The fingerprint scanner 101 may be either a touch type that touches a finger or a swipe type that swipes a finger. In this embodiment, the touch type is described as an example. The one-touch operation refers to an operation of scanning the fingerprint by one operation and operating the operation switch 105.

  The one-touch operation includes an operation in which only the fingerprint scanning is performed and the operation switch 105 is not operated. Also, one-touch fingerprint authentication may fail. One-touch operation of the operation button 100 including the touch type fingerprint scanner 101 is a series of operations from pressing the operation button 100 to making the contact of the operation switch 105 for a predetermined time or releasing the finger without making the contact. This is an operation. When the operation button 100 is lightly touched with a finger, the operation switch 105 does not operate and only fingerprint scanning is performed.

  In the one-touch operation when the fingerprint scanner 101 is a swipe type, the operation button 105 can be configured to operate with the finger to be swiped. The operation switch 105 outputs a power signal to the power block 207 via the power controller 209. The time during which the operation switch 105 outputs the power signal is referred to as a pressing time or duration t. In the one-touch operation, the time from when the finger touches the operation button 100 until the finger is released is not constant, and the time required for fingerprint authentication is not constant depending on the state of the finger surface or the scanner surface. When directly transmitted to the power block 207, the timing at which the authentication unit 203 receives the result of fingerprint authentication and the timing at which the power block 207 receives the power signal are not constant.

  The fingerprint authentication device 213 operates the fingerprint scanner 101 when receiving an authentication request from the authentication unit 203, and further turns on the LED 103 to notify the user that fingerprint authentication is possible. When the LED 103 is lit, a masking signal is output to the power controller 209. The fingerprint authentication device 213 outputs the PIN or password registered by the user to the authentication unit 203 when the fingerprint image received from the fingerprint scanner 101 matches the fingerprint image registered in advance and matches, and when they do not match, the fingerprint authentication device 213 Outputs an event indicating failure.

  The interface 205 controls data transfer between the fingerprint authentication device 213, the system 200, and the power controller 209. The interface 205 can employ a USB controller in one example, but need not be particularly limited. The interface 205 sends the PIN and password received from the fingerprint authentication device 213 to the authentication unit 203.

  The power controller 209 can be configured by a hardware logic circuit such as a logic element or a gate element. The power controller 209 sends the power signal received from the operation switch 105 to the power block 207 via the switch 215. The switch 215 can be incorporated into the power controller 209 or the power block 207. The power controller 209 controls the switch 215 with the masking signal received from the fingerprint scanner 101 and the duration t of the power signal.

  When there is no masking signal and the switch 215 is on, the power controller 209 directly transmits the power signal output from the operation switch 105 to the power block 207 so as not to cause a time delay. When the masking signal is received and switch 215 is off, the power signal to power block 207 is blocked. The power controller 209 generates a pseudo power signal from the sleep event received from the application processing unit 201 and outputs the pseudo power signal to the power block 207 when the system 200 is in an idle state. The power controller 209 uses the timer 211 to measure the duration t of the power signal generated by the operation switch 105. The timer 211 may be incorporated in the power controller 209.

  The power block 207 includes a battery, a charger, a voltage regulator, and the like, and supplies power to each element of the smartphone 100 at a predetermined voltage according to the power state. The power block 207 controls the power state of the smartphone 10 based on the power signal reception time tx received from the power controller 209 and the power state at that time.

  If a one-touch operation is performed while the switch 215 is in the ON state, the power signal duration t and the reception time tx coincide. If the switch 215 is turned on via the off state while the power signal is being generated, the reception time tx becomes shorter than the duration t. As shown in FIG. 5, the power block 207 controls the transition between the power-off state 301 and the power-on state 303 under the condition of tx ≧ t2 (t ≧ t3). In addition, the power block 207 controls transition between the power-on state 303 and the low power state 313 under the condition of 0 <tx <t2 or 0 <tx <t2-t1. The operation of the power block 207 will be described with reference to FIG.

  Since the control of the power state by the power block 207 and the control of the screen state by the authentication unit 203 are performed independently and asynchronously, the following problems occur unless the power signal masking described in the procedure of FIGS. Will occur. For example, when the authentication unit 203 first obtains the result of the authentication process in the one-touch operation, the state transits to the home screen state 307 or the authentication success screen state 311. When the power block 207 subsequently receives a power signal during the same one-touch operation, the home screen state transitions to the low power state 313 or the power off state 301 via the home screen state 307 or the authentication success screen state 311. The user's intention to operate the application cannot be realized.

  Further, when the power block 207 first receives a power signal, the power block 207 transits to the low power state 313 and cannot transit to the home screen state 307 or the authentication success screen state 311. Further, if the authentication unit 203 receives the PIN and the power block 207 receives the power signal, the operation may become unstable. A similar problem occurs when executing an application that requires fingerprint authentication in the home screen state 307.

  FIG. 2 is merely an example for explaining the present embodiment. A person skilled in the art also arbitrarily selects a plurality of blocks described in the figure as one integrated circuit or device, or conversely, a block is divided into a plurality of integrated circuits or devices. Is included in the scope of the present invention. Moreover, the connection method between each device is only an example, and is included in the scope of the present invention as long as those skilled in the art can arbitrarily select.

  For example, other elements may be inserted on the line connecting the elements without changing the essence of the signal to be transmitted. The fingerprint authentication device 213 can also be realized by processing a fingerprint image with software and a CPU incorporated in the authentication unit 203. Further, the fingerprint authentication device 213 may be incorporated in the operation button 100. The fingerprint scanner 101 and the operation switch 105 do not necessarily need to be physically integrated so long as they are configured so that one-touch operation can be performed.

  The masking signal may be a signal indicating a state in which the fingerprint authentication device 213 is operating or a state in which the fingerprint scanner 101 is waiting for fingerprint scanning, and it is not necessary to use the signal of the LED 103. The LED 103 is not essential for realizing the present invention and may be omitted. The power controller 209 may be composed of a processor and firmware.

[Power State and Screen State]
FIG. 3 is a state transition diagram for explaining the power state and the screen state of the smartphone 10. Each state element is composed of a set of a power state and a screen state. In the state elements including the power-off state 301 and the low-power state 313, since the screen state is the screen-off state, it is indicated by the power state.

  Further, since the state elements constituting the power-on state 303 include a plurality of screen states, they are indicated by screen states. In one example, the power state includes a power off state 301, a low power state 313, and a power on state 303. The touch screen 11 stops in the screen off state in the power off state 301 and the low power state 313.

  In one example, the power-on state 303 includes a lock screen state 305, a home screen state 307, a password (PW) input screen state 309, and an authentication success screen state 311. The screen state changes the operations of the application processing unit 201, the authentication unit 203, and the touch screen 11. The power-off state 301 is a state in which the power consumption is the lowest, and the supply of power is stopped except for the minimum devices necessary for starting the system. In the low power state 313, the power consumption is the second lowest after the power off state 301. In one example, the supply of power is stopped except for the minimum devices necessary for storing the operation state of the immediately preceding system.

  In the power-on state 303, power is supplied to all devices unless an individual stop operation is performed. In the power off state 301 and the low power state 313, power is supplied to the power controller 209 that controls the power state, but the operation of the fingerprint authentication device 213 stops and the masking signal also stops. The lock screen state 305 corresponds to the first screen state when transitioning from the power-off state 301 or the low-power state 313 to the power-on state 303.

  In the lock screen state 305, when a PIN is set, a transition is made to the home screen state 307 by PIN input or fingerprint authentication. In the lock screen state 305, when the PIN is not set, it is possible to transit to the home screen state 307 without performing user authentication. 3 and 4 show examples in which a PIN is set. In the lock screen state 305, a specific application such as voice input or audio streaming may be executed.

  The home screen state 307 corresponds to a screen state in which an application can be executed. The home screen state 307 can be transitioned by inputting a PIN from the touch screen 11 in the lock screen state 305 or by performing fingerprint authentication with the fingerprint authentication device 213. In one example, in the home screen state 307, a large number of activation icons associated with the application are displayed, and the application can be executed by touching the activation icon.

  The PW input screen state 309 corresponds to a screen state that transits to input a PIN or password from the touch screen 11. The PW input screen state 309 includes fingerprint authentication when fingerprint authentication fails in the lock screen state 305 and when an application (hereinafter referred to as a specific application) for accessing a transaction site for shopping or depositing is executed in the home screen state 307 Can be transitioned when fails.

  The authentication success screen state 311 corresponds to a screen state displayed when password authentication or fingerprint authentication succeeds when executing a specific application in the home screen state 307. Although typical examples of the power state and the screen state have been described here, all of the screen states in the power-on state 303 are not necessarily illustrated here, and other state elements may be included. It is not necessary to limit the power state to three, and a plurality of low power states with different power consumption and the state of the system 200 may be set.

  FIG. 4 is a diagram for explaining the transition conditions in the state transition diagram of FIG. FIG. 4 shows the presence / absence of a masking signal, the application state of fingerprint authentication, and the range of duration t when transitioning between state elements. The masking signal is generated when fingerprint authentication is required at the transition source. A symbol NA shown as an application state of fingerprint authentication indicates a state in which fingerprint authentication is not performed even if the finger is placed on the fingerprint scanner 101 because there is no authentication request or the fingerprint authentication apparatus 213 is stopped. At this time, the masking signal stops.

  Further, the symbol DC shown as the application state of fingerprint authentication indicates that fingerprint authentication is performed because there is an authentication request, but this is performed according to the duration t regardless of the result. The threshold values t1, t2, and t3 of the duration t are in a relationship of t1 <t2 <t3. The symbol NA indicating the application state of the duration t indicates that there is no one-touch operation on the operation button 100 because the screen state is changed by the touch operation on the touch screen 11. Processing of state transition from a transition source for which fingerprint authentication is required will be described with reference to FIGS.

  FIG. 5 is a diagram for describing a typical example of the relationship between power state transition and the reception time tx of the power signal received by the power block 207. In FIG. 5, the durations (pressing times) t1 to t3 correspond to the time when the power signal is generated at time 0. The reception time tx when the masking signal is generated is shorter than the duration t or becomes zero. Transition 1 from the power-off state 301 to the power-on state 303 occurs when the power signal reception time tx is tx ≧ t2. Transition 6 from the home screen state 307 to the low power state 313 occurs when 0 <tx <t2. The transition 11 from the home screen state 307 to the power-off state 301 occurs when tx ≧ t2.

  The transition 12 from the low power state 313 to the lock screen state 305 occurs when 0 <t <t2. In transitions 1, 6, 11, and 12, since the transition source does not request fingerprint authentication, the pressing time and the reception time match. In the transition 2 from the lock screen state 305 requiring fingerprint authentication to the home screen state 307, a masking signal is generated. The duration t1 corresponds to a time during which the masking signal is blocked (masking time). Transition 2 occurs between 0 ≦ t <t1 by the processing of the authentication unit 203. Transition 3 from the lock screen state 305 to the low power state 313 occurs when 0 <tx <(t2-t1). At this time, the pressing time is longer than when there is no masking signal.

  The power signal for transitioning to the low power state 313 has a maximum reception time tx of t2-t1 after the masking is released. The reception time tx at this time is a transition from the same power-on state 303. 6 is within the range of 0 <tx <t2. Transition 4 from the lock screen state 305 to the power-off state 301 occurs when the reception time tx is tx ≧ t2 when the masking time t1 is added and the duration t is t ≧ t3 (t3 = t1 + t2). . Therefore, even when the power signal is masked, the power block 207 transits to the low power state 313 when 0 <tx <t2 or 0 <tx <(t2−t1), and powers off when tx ≧ t2. Since it is possible to transit to the state 301, it is not necessary to change the operation mode depending on the presence or absence of masking.

[Transition from lock screen state]
FIG. 6 is a flowchart showing a procedure for processing transitions 2 to 5 from the lock screen state 305 by a one-touch operation. As shown in FIGS. 3 and 4, from the lock screen state 305, the system 200 transitions to any one of the home screen state 307, the low power state 313, and the power off state 301 by a one-touch operation on the operation button 100. Furthermore, when fingerprint authentication fails, the process transits to the PW input screen state 309.

  Upon receiving the PIN from the fingerprint authentication device 213, the authentication unit 203 causes the system 200 to transition to the home screen state 307 by a process independent of the power block 207. When the power block 207 receives the power signal, the power block 207 determines only the reception time tx independently of the operation of the authentication unit 203 and makes the system 200 transition to the power-off state 301 or the low power state 313.

  In block 401, the smartphone 10 has transitioned from the power-off state 301 or the low-power state 313 to the lock screen state 305 via the transition 1 or the transition 12. The user can transition the system 200 to the intended state element by performing a one-touch operation so that the duration t of the operation switch 105 becomes the time shown in FIG. 4 as described below.

  The authentication unit 203 that has recognized the transition to the power-on state 303 sends an authentication request to the fingerprint authentication device 213 in block 403 when a PIN is set. In block 405, the fingerprint authentication device 213 turns on the LED 103 of the fingerprint scanner 101 and outputs a masking signal to the power controller 209. The power controller 209 that has received the masking signal turns off the switch 215. In block 407, the user performs a one-touch operation on the operation button 100.

  The user communicates the intention of transition 2 to the home screen state 307 as a press time of 0 ≦ t <t1, conveys the intention of transition 3 to the low power state 313 as a press time of t1 ≦ t <t2, and further powers off The intention of the transition 4 to the state 301 can be transmitted as a pressing time of t ≧ t3. The user expects fingerprint authentication to be performed at the transition to the home screen state 307, and operates without worrying about the success or failure of the fingerprint authentication at the transition to the low power state 313 and the power off state 301. can do.

  In block 407a, the operation switch 105 operates to output a power signal. The power controller 209 causes the timer 211 to measure the duration t of the power signal. In step 407b, the fingerprint authentication apparatus 213 that has received the fingerprint image from the fingerprint scanner 101 starts fingerprint authentication. When fingerprint authentication is successful, the fingerprint authentication device 213 outputs a PIN to the authentication unit 203 via the interface 205.

  The power controller 209 determines the duration t at block 409. When the duration t is 0 ≦ t <t1, the process proceeds to block 411, and when t ≧ t1, the process proceeds to block 451. The transition to block 409 includes a case where the operation switch 105 does not operate by lightly touching the operation button 100 to perform only fingerprint authentication. When the process proceeds to block 411, the power signal is not supplied to the power block 207 because the switch 215 is in the OFF state. Therefore, the system can maintain the power-on state 303, and can secure time for fingerprint authentication by the authentication unit 203 that operates independently from the control of the power state of the power block 207.

  In block 411, when the fingerprint authentication is successful, the authentication unit 203 receives a PIN from the fingerprint authentication device 213. In block 413, the authentication unit 203 collates the received PIN with the previously registered PIN and causes the system 200 to transition to the home screen state 307 (transition 2). When the authentication unit 203 that recognizes that the authentication is successful stops the authentication request, the masking signal is stopped and the switch 215 is turned on.

  If fingerprint authentication fails in block 411, the process moves to block 471. In block 471, the fingerprint authentication device 213 sends an event indicating an authentication failure to the authentication unit 203. The authentication unit 203 displays a prompt for prompting authentication again on the touch screen 11. The authentication unit 203 maintains an authentication request to the fingerprint authentication device 213 until fingerprint authentication is successful. If the user does not transit to the home screen state 307 by the first one-touch operation, the user recognizes the failure of the fingerprint authentication and performs the one-touch operation again in block 473. Even during the retry, the power signal is blocked by the switch 215 so that the system 200 does not transition to the low power state.

  When the authentication unit 203 recognizes that the fingerprint authentication has failed a predetermined number of times in block 471, the authentication unit 203 transitions the system 200 to the PW input screen state 309 in block 475 (transition 5). When a PIN is input from the touch screen 11 in the PW input screen state 309, the authentication unit 203 causes the system 200 to transition to the home screen state 307 (transition 8).

  When the power controller 209 recognizes that the duration t is t ≧ t1, the block 451 turns on the switch 215. As a result, the masking is stopped and a power signal after time t 1 is sent to the power block 207. At this point, the authentication unit 203 may have transitioned the screen state to the home screen state 307 by fingerprint authentication. In block 453, if the transition is made to the home screen state 307, the process proceeds to block 461, and if not, the process proceeds to block 455.

  In block 455, the power block 207 determines a power signal reception time tx. When the reception time of the power signal corresponding to the operation time of t ≧ t3 is tx ≧ t2, the power block 207 proceeds to block 463 and transitions the system 200 to the power-off state 301 (transition 4). The power block 207 proceeds to block 457 when the reception time of the power signal corresponding to the operation time of t1 ≦ t <t2 is 0 <tx <(t2−t1), and the system 200 enters the low power state 313. Transition (transition 3). In block 461, the power block 207 transitions to the low power state 313 or the power off state 301 under the same conditions as the blocks 455, 457, and 463.

  In the above procedure, the user can tell the intended transition destination from the lock screen state 305 as a press time of a one-touch operation with relatively easy skill. The power controller 209 adjusts the timing for transmitting the power signal to the power block 207 so as to be the transition destination intended by the user according to the operation time. Since the present invention can be realized by a hardware layer positioned below the system 200, there is no need to change the system configuring the authentication unit 203 and the application processing unit 201, and the application is flexible.

[Transition from home screen state]
FIG. 7 is a flowchart showing a procedure when the transitions 6a, 7, 9, and 11a from the home screen state 307 for executing the specific application are processed. As shown in FIGS. 3 and 4, from the home screen state 307 for executing a specific application, the system 200 performs a PW input screen state 309, an authentication success screen state 311, a low power state 313, and the like by a one-touch operation on the operation button 100. Transition to one of the power-off states 301.

  In block 501, the smartphone 10 transitions from the lock screen state 305, the PW input screen state 309, or the authentication success screen state 311 to the home screen state 307 via transitions 2, 8, and 10. The procedure of transition 2 is as described with reference to FIG. Transitions 8 and 10 are performed by a touch operation on the touch screen 11. In the home screen state 307, the user executes a specific application for accessing a transaction site for which a password has been previously registered in block 502.

  The registered password is held by the authentication unit 203. In block 503, the authentication unit 203 sends an authentication request to the fingerprint authentication device 213 in response to a specific application request. In block 505, the fingerprint authentication device 213 turns on the LED 103 of the fingerprint scanner 101 and outputs a masking signal to the power controller 209. In response to the masking signal, the power controller 209 turns off the switch 215.

  In the home screen state 307 for executing the specific application, if the fingerprint authentication is successful by the one-touch operation, the authentication unit 203 sends the password registered in the transaction site and makes the system 200 transition to the authentication success screen state 311 (transition 9). On the other hand, from the home screen state 307 for executing a specific application, a transition to the low power state 313 (transition 6a) or the power off state 301 (transition 11a) is also possible with a one-touch operation. The user transmits the state element of the transition destination to the system 200 by a one-touch operation on the operation button 100.

  In block 507, the user performs a one-touch operation on the operation button 100. The user informs the system of the intended transition destination by pressing time. The user transmits the intention of transition 9 to the authentication success screen state 311 when there is an authentication request as a pressing time of 0 ≦ t <t1, and the intention of transition 11a to the power-off state 301 is the pressing time of t ≧ t3. The intention of the transition 6a to the low power state 313 can be transmitted as t1 ≦ t <t2. Note that the user transmits the intention of the transition 6 from the home screen state 307 to the low power state 313 when there is no authentication request with a pressing time of 0 <t <t2, and the intention of the transition 11 to the power off state t ≥t2 can be transmitted.

  The processing of blocks 507a, 507b, 509, and 551 is the same as the processing of blocks 407a, 407b, 409, and 451 in FIG. If the fingerprint authentication is successful in block 511, the authentication unit 203 receives a password from the fingerprint authentication device 213 in block 513. The authentication unit 203 collates the received password with a previously registered password and causes the system 200 to transition to the authentication success screen state 311 (transition 9). When the authentication unit 203 that recognizes that the authentication is successful stops the authentication request, the masking signal is stopped and the switch 215 is turned on.

  If fingerprint authentication fails in block 511, the process moves to block 571. The processing of blocks 571 and 573 conforms to the processing of blocks 471 and 473. If the authentication unit 203 recognizes that the fingerprint authentication has failed a predetermined number of times in block 571, the authentication unit 203 causes the system 200 to transition to the PW input screen state 309 in block 575 (transition 7). When a password is input from the touch screen 11 in the PW input screen state 309, the system 200 transitions to an authentication success screen state 311 (transition 13).

  The procedure after block 551 conforms to the procedure after block 451 in FIG. At block 557, the transition is made to the low power state 313 at transition 6a, and at block 563, the transition is made to the power off state 301 at transition 11a. In block 561, transition is made to the low power state 313 or the power off state 301 according to the conditions of blocks 555, 557, and 563.

[Example of application to home button]
FIG. 8 is a plan view and a side view showing the outer shape of the smartphone 50 in which the home button is configured with an FPA built-in button. Since the configuration of the smartphone 50 is similar to the smartphone 10 in many parts, the following description will focus on differences from the smartphone 10. The smartphone 50 includes a home button 51 corresponding to an FPA built-in button and a power button 55. FIG. 9 is a diagram illustrating an example of a functional block diagram of the smartphone 50.

  A switch 63 is connected between the operation switch 105 and the power block 207, and a controller for controlling the switch 63 is provided in the circuit of the LED 103. Further, the power button 55 is directly connected to the power block 207. The switch 63 and the controller 61 may be incorporated in the home button 51 or in the power block 207.

  Since the power signal output from the power button 55 is directly transmitted to the power block 207, the duration t and the reception time tx always coincide. The power block 207 controls transition between the power-off state 301 and the power-on state 303 when the reception time of the power signal output from the power button 55 is tx ≧ t2. The power block 207 controls transition between the low power state 313 and the power on state 303 when the reception time of the power signal output from the power button 55 is 0 <tx <t2.

  Note that the threshold value t <b> 2 can be a value different from that of the smartphone 10. The power block 207 causes the system 200 to transition from the power-on state 303 to the low power state 313 when the reception time of the power signal received from the operation switch 105 via the switch 63 is tx> 0. The power block 207 does not shift the system 200 from the power-on state 303 to the power-off state 301 with the power signal received from the operation switch 105.

  When a one-touch operation is performed on the home button 51 in the lock screen state 305 in which the authentication request is generated, the home screen state 307 or the PW input screen state 309 can be changed depending on the result of fingerprint authentication. Similarly, the home screen state 307 for executing the specific application can be transited to the PW input screen state 309 or the authentication success screen state 311.

  If the switch 63 is not present, when the home button 51 is touched in the lock screen state 305, the authentication unit 203 temporarily changes the system 200 to the home screen state 307, and immediately after that, the power block 207 is in the low power state 313. There is a case to make a transition. Further, even when a one-touch operation is performed with the intention of transition to the home screen state 307, the power block 207 may transition to the low power state 313 first. Even when a one-touch operation is performed in the home screen state 307 for executing a specific application, the same phenomenon may occur through the authentication success screen state 311 or a transition to the low power state 313 may occur.

  In the present embodiment, the switch 63 masks the power signal of the operation switch 105 with the authentication request. The one-touch operation on the home button 51 in the lock screen state 305 can be processed by applying the procedure excluding blocks 409 and 451 and the subsequent steps in FIG. The one-touch operation on the home button 51 in the home screen state 307 for executing the specific application can be processed by applying the procedure excluding the blocks 509 and 551 in FIG.

  The controller 61 turns off the switch 63 when there is an authentication request from the authentication unit 203, and turns on the switch 63 when the authentication request is canceled. Therefore, the power signal output from the operation switch 105 is not transmitted to the power block 207 while there is an authentication request. The authentication unit 203 can transition to the home screen state 307, the authentication success screen state 311 or the PW input screen state 309 depending on the result of fingerprint authentication.

  The controller 61 can turn on the switch 63 after the power signal of the operation switch 105 stops. In the lock screen state 305 or the home screen state 307 where there is no authentication request, the switch 63 is on. Therefore, the home button 51 can be shifted to the low power state 313 by performing a one-touch operation with a pressing time corresponding to a reception time of tx> 0.

  Although the present invention has been described with the specific embodiments shown in the drawings, the present invention is not limited to the embodiments shown in the drawings, and is known so far as long as the effects of the present invention are achieved. It goes without saying that any configuration can be adopted.

10, 50 Smartphone 200 Smartphone system 11 Touch screen 51 Home button 55 Power button 100 Operation button 101 Fingerprint scanner 105 Operation switch 213 Fingerprint authentication device 301 Power-off state 303 Power-on state 305 Lock screen state 307 Home screen state 309 Password input screen state 311 Authentication success screen state 313 Low power state

Claims (20)

A system that transitions to one of multiple screen states or power states;
An operation button capable of generating a fingerprint authentication result and generating a power signal by one-touch operation,
An authentication unit that changes the screen state of the system according to a result of the fingerprint authentication;
A power block that changes the power state of the system in response to the power signal;
A portable terminal device comprising: a power controller that prevents transmission of the power signal to the power block when the one-touch operation is performed in the predetermined screen state.   The mobile terminal device according to claim 1, wherein the power controller is configured by a hardware layer located in a lower layer of the system.   The mobile terminal device according to claim 1, wherein the power block and the authentication unit change the power state and the screen state asynchronously with each other.   The portable terminal device according to claim 1, wherein the power controller prevents transmission of the power signal when receiving a signal indicating a standby state of the fingerprint authentication.   2. The portable terminal device according to claim 1, wherein the predetermined screen state is a lock screen state that prohibits execution of an application program, and the transition destination screen state is a home screen state in which the application program can be executed.   2. The mobile terminal device according to claim 1, wherein the predetermined screen state is a home screen state in which an application program can be executed, and the transition destination screen state is an authentication success screen state.   The power block causes the system to transition to a low power state when the reception time of the power signal is less than a first threshold, and causes the system to transition to a power off state when the power signal reception time is greater than or equal to the first threshold. The mobile terminal device according to claim 1.   The portable terminal device according to claim 7, wherein the power controller blocks transmission of the power signal for a time corresponding to a second threshold value smaller than the first threshold value.   The portable terminal device according to claim 8, wherein the power block causes the system to transition to the power-off state when the reception time after the transmission of the power signal is canceled is equal to or greater than the first threshold. A system that transitions to one of multiple screen states or power states;
An operation button capable of generating a result of fingerprint authentication by one-touch operation and further generating a first power signal;
An authentication unit capable of changing the system from the first screen state to the second screen state according to a result of the fingerprint authentication;
A power button for outputting a second power signal by pressing, and
A power block for changing a power state of the system according to the first power signal and the second power signal;
A portable terminal device comprising: a switch element that blocks transmission of the first power signal to the power block when the one-touch operation is performed in the first screen state.   11. The portable terminal device according to claim 10, wherein the first screen state is a lock screen state that prohibits execution of an application program, and the second screen state is a home screen state that allows execution of the application program.   The mobile terminal device according to claim 11, wherein the first screen state is the home screen state requesting fingerprint authentication, and the second screen state is an authentication success screen state.   The mobile terminal device according to claim 10, wherein the power block causes the system to transition to a low power state or a power off state when the second power signal is received in the first screen state. A method for controlling a screen state and a power state of a portable terminal device including an operation button including an operation switch for generating a fingerprint scanner and a power signal,
Transitioning to a blocking state to block transmission of the power signal to the power block in response to a fingerprint authentication request;
Generating a result of the fingerprint authentication and a power signal in response to a one-touch operation on the operation button;
Changing the screen state according to a result of the fingerprint authentication while transmission of the power signal is blocked.   The method according to claim 14, further comprising changing from a lock screen state that prohibits execution of an application program according to a result of the fingerprint authentication to a password input screen state while the power signal is blocked. Releasing the blocking state when the duration of the power signal exceeds a predetermined threshold;
Transmitting the power signal to the power block in response to release of the blocking state;
The method according to claim 14, further comprising: changing the power state to a low power state or a power off state according to a reception time of the power signal after the blocking state is released.   The method of claim 16, wherein the change to the low power state and the power off state is made via a home screen state that permits execution of an application program. A screen state of a portable terminal device including an operation button capable of one-touch operation including a fingerprint scanner and an operation switch for generating a first power signal, and a power button capable of generating a second power signal by a pressing operation; A method for controlling a power state,
Blocking transmission of the first power signal to a power block in response to a fingerprint authentication request;
Generating a result of the fingerprint authentication and the first power signal in response to a one-touch operation on the operation button;
Changing the screen state according to the result of the fingerprint authentication;
Generating a second power signal in response to a pressing operation on the power button;
The power block changing the power state in response to the second power signal. Unblocking the transmission with the change of the screen state;
The method of claim 18, wherein the power block changes the power state from a power-on state to a low power state in response to the first power signal.   The method of claim 18, wherein the power block changes the power state from a power-on state to a power-off state in response to the second power signal.

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