KR102105967B1 - Low power sensing device and method for displaying information - Google Patents

Abstract

The present invention relates to a low power sensing device and method for displaying information.
To this end, according to the present invention, when the mobile terminal is in the standby state, the low-power detection management unit drives the proximity detection sensor to drive the motion detection sensor when a proximity interrupt occurs, and determines the movement of the mobile terminal for a preset time to carry it for a preset time If there is no movement of the terminal, the proximity data for displaying the screen information is generated, and then the generated proximity data is transmitted to the application processor to display screen information desired by the user with low power.

Description

LOW POWER SENSING DEVICE AND METHOD FOR DISPLAYING INFORMATION for information display

The present invention relates to a low-power detection device and method, and particularly to a low-power detection device and method for displaying a predetermined screen information by sensing the proximity of a body part or an object with low power when the mobile terminal is in a standby state.

In general, when a user wants to check simple information of a portable terminal, the user presses the power-on button of the portable terminal to change the state of the portable terminal from a standby state to an activated state. The mobile terminal switched to the active state displays simple information, for example, battery status, charging status, current time, unconfirmed message, unconfirmed call, currently playing music information, content download information, and the like. Through this, the user can confirm the light displayed on the screen of the mobile terminal in the activated state.

In addition, the mobile terminal is equipped with a proximity sensor for detecting the proximity of the user's body part or object, and when the proximity of the user's body part or object is detected through the proximity sensor, simple information is displayed on the screen of the mobile terminal. Through this, the user can conveniently check simple information of the portable terminal without having to press the power-on button of the portable terminal.

As described above, when the conventional terminal wants to check simple information about the portable terminal, the operating state of the portable terminal is switched from the standby state to the activated state by using the power-on button or proximity sensing, and the portable terminal is switched to the activated state. Simple information was displayed on the screen.

However, in the related art, there is a hassle of pressing the power-on button of the portable terminal whenever the user wants to check simple information of the portable terminal.

In addition, in the related art, since the proximity sensing sensor of the portable terminal continuously operates and detects the proximity of a user's body part or an object, the portable terminal continuously consumes power in order to maintain the active state.

In addition, in the related art, even when the user detects an unwanted proximity through the proximity sensing sensor of the portable terminal, the state of the portable terminal is switched from the standby state to the activated state, thereby reducing the overall standby time of the portable terminal due to frequent switching. There are disadvantages.

Accordingly, the present invention provides a low power detection apparatus and method for detecting a user's desired proximity with low power and displaying preset screen information.

The present invention for achieving the above is a low-power sensing device for information display, the sensing sensor for detecting proximity or movement to the portable terminal, and when the proximity to the portable terminal is detected from the sensing sensor for a predetermined time It characterized in that it comprises a low-power management unit for determining the movement of the mobile terminal, and outputs data on the detected proximity if there is no movement of the mobile terminal for the preset time.

In addition, the present invention is a method for detecting information in a low power sensing device, comprising: determining whether proximity to the portable terminal is detected from a sensing sensor detecting proximity or movement to the portable terminal, and for the portable terminal And detecting the movement of the portable terminal for a preset time when proximity is detected, and outputting data on the detected proximity if there is no movement of the portable terminal for the preset time.

The present invention has an advantage in that power consumption of the portable terminal can be reduced by detecting only valid proximity data for displaying information of the portable terminal and switching the state of the portable terminal when checking simple information of the portable terminal.

In addition, the present invention has the advantage of reducing the frequent switching of the portable terminal and increasing the total waiting time of the portable terminal because the state of the portable terminal is switched by sensing only valid proximity data.

1 is a configuration diagram of a low power sensing device according to an embodiment of the present invention,
2 is an exemplary diagram for a motion detection signal received from the motion detection sensor by the low power management unit of the low power detection device according to an embodiment of the present invention;
3 to 4 are flowcharts illustrating a process in which a low power sensing device displays preset screen information through proximity sensing and motion sensing according to an embodiment of the present invention,
5 to 7 are flowcharts illustrating a process of displaying screen information according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and accompanying drawings, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

In the present invention, when the mobile terminal is in a standby state, the low-power detection management unit drives the proximity detection sensor to drive the motion detection sensor when a proximity interrupt occurs, determines the movement of the mobile terminal for a preset time, and detects the movement of the mobile terminal for a preset time. If there is no movement, after generating proximity data for displaying screen information, the generated proximity data is transmitted to the application processor, so that the user can display desired screen information with low power.

1 is a configuration diagram of a low power sensing device according to an embodiment of the present invention.

The mobile terminal of the present invention includes a low power detection device 100, an application processor 200, a display unit 210, an input unit 220, a proximity detection sensor 230, and a motion detection sensor 240.

First, the low power detection device 100 of FIG. 1 includes a low power management unit 110, an interrupt unit 120, a timer 130, a memory unit 140, a first bus 150, a second bus 160, and 3 bus 170.

The low power management unit 110 controls the overall operation of the low power detection device 100, in particular, drives the proximity detection sensor 230 while the application processor 200 is in the sleep mode, and generates a proximity interrupt from the interrupt unit 120 When this is detected, the motion detection sensor 240 is driven.

The low power management unit 110 determines whether the posture of the portable terminal satisfies a predetermined determination condition through the motion detection sensor 240. Here, the preset determination condition means a condition for determining whether the angles of the x-axis, y-axis, and z-axis of the portable terminal are included within a preset threshold range. At this time, in the embodiment of the present invention, the motion detection sensor 240 may be an acceleration sensor, and may calculate a rotation angle rotated according to the horizontal direction of the portable terminal. When the rotation angle calculated in this way is determined to be within a preset threshold range, and if the rotation angle is included within the preset threshold range, the low power management unit 110 determines that the preset determination condition is satisfied, and the rotation angle is preset threshold If it is not included in the range, it is determined that the predetermined judgment condition is not satisfied. For example, when the rotation angle rotated according to the horizontal direction of the portable terminal is 0 °, if this value is included within a preset threshold range, the low power management unit 110 may be considered to satisfy a preset determination condition.

When the posture of the portable terminal satisfies a preset determination condition, the low power management unit 110 determines whether a detection signal identified as a movement is included in a detection signal input from the motion detection sensor 240 for a preset time.

If the posture of the mobile terminal does not satisfy the preset determination condition, the low power management unit 110 stops driving the motion detection sensor and waits for the next proximity interrupt to occur. Through this, in the present invention, it is possible to prevent the state of the portable terminal from being switched from the standby state to the activated state when the situation is not a proximity situation but a proximity situation.

In other words, if it is determined that the detection signal input as a motion is included in the detection signal input from the motion detection sensor 240 for a predetermined time, the low power management unit 110 stops driving the motion detection sensor 240 and next Wait for the occurrence of a proximity interrupt.

If a detection signal identified as a movement is not included in the detection signal input from the motion detection sensor 240 for a preset time, the low power management unit 110 determines whether a preset time has elapsed.

Here, the process of determining the motion from the detection signal received from the motion sensor will be described in detail with reference to FIG. 2.

2 is an exemplary diagram of a motion detection signal received from a motion detection sensor by a low power management unit of a low power detection device according to an embodiment of the present invention.

According to FIG. 2, the low power management unit 110 divides a preset time period into a preset number for motion determination, and sets a value that is equal to or greater than a preset threshold value TH from a detection signal input for each divided time period. It is judged whether it has. At this time, the low power management unit 110 determines that there is motion when the detection signal is above the threshold value, and determines that there is no motion when the detection signal is below the threshold value. Also, the preset time period means a minimum time used by the motion detection sensor 240 to determine motion.

If the detection signal in a specific division time interval is greater than or equal to a threshold value, the low power management unit 110 divides the preset number of times from the next division time interval into a preset number of times, and the detection signal input for each divided time interval is a threshold value. Judging again if it is abnormal. At this time, the low power management unit 110 may compare the previous division time period and the current division time period to determine a division time period in which motion is detected.

For example, the low power management unit 110 divides the preset T10 time period into ten, and each of the ten divided time periods 0 to T1, T1 to T2, T2 to T3, T3 to T4, T4 to T5, and T5 It is determined whether the detection signals input to T6, T6 to T7, T7 to T8, T8 to T9, and T9 to T10 are greater than or equal to the threshold (TH). If the segmentation time periods T5 to T6 have a value equal to or greater than a threshold, the low power management unit 110 determines that motion has been detected. Subsequently, the low power management unit 110 divides the preset T time period into ten again after the divided time period in which the motion is detected, and determines whether the detection signal input to each of the ten divided time periods is greater than or equal to a threshold value (TH). Judge.

If motion is continuously detected within a preset time period, the low power management unit 110 stops driving the motion detection sensor and waits for the next proximity interrupt to occur.

If motion is not detected within a preset time period, the low power management unit 110 transmits proximity data for displaying screen information stored in the memory unit 140 to the application processor 200, and the motion detection sensor 240 and proximity The driving of the detection sensor 230 is stopped.

The application processor 200 that has received the proximity data displays screen information preset by the user through the display unit 210. Specifically, the application processor 200 may display screen information including terminal information such as the current time, date, missed call, missed message, battery level, and music being played on the portable terminal through the display unit 210. Here, the terminal information may further include information related to the set alarm, and may further include an alarm time and a remaining time from the current time to the alarm time. At this time, the application processor 200 may provide when the remaining time is less than a predetermined time.

In an embodiment of the present invention, the mobile terminal displays this screen information and may be switched to a standby state after a preset time.

In addition, in the embodiment of the present invention, the mobile terminal displays the terminal information on a screen such as a text or image, but may be provided using voice. For example, in the present invention, the application processor 200 may display terminal information by configuring it as a screen such as text or image, and output terminal information by configuring the terminal information as voice data. In another embodiment, in the present invention, the application processor 200 may configure and output terminal information only with voice data without displaying a separate screen. For example, when outputting information related to the alarm as voice data, the application processor 200 adjusts the volume of the voice data output in consideration of conditions such as the current time, the remaining time from the current time to the alarm time, and ambient brightness. You can.

The interrupt unit 120 detects an interrupt generated from the proximity sensor 230 or the motion sensor 240 and transmits it to the low power manager 110.

The timer 130 counts numbers at specific time intervals.

The memory unit 140 stores proximity data used for displaying screen information in advance. The proximity data is stored to correspond to screen information preset in the portable terminal.

The first bus 150 is an interface that connects the low power management unit 110 to the timer 130 and the memory unit 140.

The second bus 160 is an interface connecting the low power management unit 110 and the application processor 200.

The third bus 170 is an interface that connects the low power management unit 110 with the proximity sensor 230 and the motion sensor 240.

Next, the application processor 200 controls the overall operation of the portable terminal. In particular, when proximity data is received from the low power management unit 200, the preset screen information is displayed through the display unit 210.

The display unit 210 may be formed of a liquid crystal display (LCD), and visually provides a user with a menu, input data, function setting information, and various other information of the mobile terminal. The display unit 210 may be configured with various devices in addition to the LCD. The display 210 performs a function of outputting a boot screen, a standby screen, a display screen, a call screen, and other application execution screens of the mobile terminal.

The input unit 220 may include key input means including a plurality of keys for key input, pointing input means for pointing input such as a mouse, touch input means for touch input, and the like, and received input signals. To the application processor 200.

The proximity sensing sensor 230 outputs a detection signal when a person's body part or an object is approached before being touched. For example, the proximity sensor 230 may operate an infrared, laser, ultrasonic, illuminance sensor, or constant voltage touch screen.

The motion detection sensor 240 detects the movement of a person or an object and outputs a detection signal. For example, the motion detection sensor 240 may utilize acceleration, gyro, geomagnetic, and gravity sensors.

In addition, in an embodiment of the present invention, the low-power electronic device 100 further includes a sensor capable of detecting the surrounding environment, so that only an effective operation for switching the application processor from the standby state to the activated state can be detected.

As described above, in the embodiment of the present invention, the low power detection device 100 is described as being implemented separately from the application processor 200, but may be implemented by being included in a subcore in the application processor 200. In other words, a sub-core for the low power sensing device 100 may be added to the application processor 200, and the application processor 200 may perform communication between the low power sensing devices 100 through a bus or a register.

In the embodiment of the present invention described above, when an event for activating the portable terminal is detected in the standby state, the attitude of the portable terminal is determined, and when the determined attitude of the portable terminal satisfies the condition for activating the portable terminal, the portable terminal Activate it.

As another embodiment of the present invention, it is possible to determine whether the mobile terminal is connected to the cradle or whether the mobile terminal is running a specific application in the background in a standby state and display screen information associated with it.

First, the process of displaying screen information according to whether the mobile terminal is connected to the cradle will be described in detail. The low power management unit 110 determines whether the mobile terminal is connected to the cradle in the sleep mode of the mobile terminal to determine whether the mobile terminal is connected to the cradle. When connected to the cradle, the state of the mobile terminal is switched from the sleep mode to the active mode. Thereafter, the low power management unit 110 determines whether a proximity interrupt is generated by driving the proximity detection sensor 230 and transmits proximity data to the application processor 200 when the proximity interrupt occurs. The application processor 200 configures a screen for speech recognition and displays it through the display unit 210 while performing in a speech recognition mode for controlling the function of the portable terminal through speech recognition. For example, when the connection with the cradle in the vehicle is recognized, the low power management unit 110 may switch the state of the portable terminal to a driving mode for driving the user's vehicle.

In addition, when the mobile terminal in the music reproduction mode during music reproduction is recognized as a connection to a dock holder of the music reproduction device, the low power management unit 110 drives the proximity detection sensor 230 and determines whether a proximity interrupt is generated. If the connection to the cradle is not recognized, the low power management unit 110 maintains a music playback mode.

When a proximity interrupt occurs, the low power management unit 110 may transmit proximity data to the application processor 200, and the application processor 200 may configure a screen related to the music being played and display it through the display unit 210. At this time, the screen related to the music being played may include music information such as artists and lyrics related to music and an interface for controlling music playback. If a proximity interrupt is not generated, the low power management unit 110 continuously determines whether a proximity interrupt is generated.

Next, a process of displaying screen information according to whether a specific application is running in the background in a standby state will be described in detail. When a predetermined time elapses while the application processor 200 is executing a specific application, the portable terminal To enter the sleep mode. In this case, the specific application may be an application executable in the background, such as an application for data upload or download.

The low power management unit 110 may determine whether a proximity interrupt is generated by driving the proximity detection sensor 230, and when a proximity interrupt is generated, configure a screen related to an application running in the background and display it through the display unit 210. The screen related to the application running in the background may include progress information such as time for data upload or download, data capacity, etc. in the case of an application for data transmission and reception between a smartphone and another smartphone.

Through this, the present invention enables the mobile terminal to display preset screen information with low power by detecting only a valid operation for displaying screen information desired by the user.

3 to 4 are flowcharts illustrating a process in which a low power sensing device displays preset screen information through proximity sensing and motion sensing according to an embodiment of the present invention.

According to FIG. 3, in step 300, the low power management unit 110 determines whether the application processor 200 is in the sleep mode, and if the sleep mode is in progress, the process proceeds to step 301. Otherwise, in step 300, the application processor 200 continuously sleeps. It is determined whether or not the mode.

In step 301, the low power management unit 110 drives the proximity detection sensor 230, and in step 302, determines whether a proximity interrupt has occurred through the interrupt unit 120, and if a proximity interrupt occurs, the process proceeds to step 303, If an interrupt does not occur, it is continuously determined in step 302 whether a proximity interrupt has occurred.

In step 304, the low power management unit 110 determines whether the posture of the mobile terminal is included in the preset determination condition through the motion detection sensor 240, and if the preset determination condition is included, the process proceeds to step 306, and the preset determination condition If not included, the process proceeds to step 305 to stop driving of the motion detection sensor 240, and proceeds to step 302 to determine whether the next proximity interrupt occurs, and then performs step 304 to step 303.

In step 306, the low power management unit 110 determines whether there is movement for a preset time. In other words, the low power management unit 110 determines whether a detection signal identified as a movement is included in the detection signal input from the motion detection sensor 240.

As a result of the determination, if there is movement for a preset time, the low power management unit 110 proceeds to step 305 to stop driving the motion detection sensor 240, proceeds to step 302 to determine whether the next proximity interrupt occurs, and then step 303. Step 304 is performed.

If there is no movement for a predetermined time, the low power management unit 110 proceeds to step a and then performs step a after in FIG. 4.

According to FIG. 4, the low-power management unit 110 that proceeds from step a to step 400 determines whether a preset time has elapsed and proceeds to step 401 when a preset time has elapsed, and b if a preset time has not elapsed. Step 3 proceeds to step b of FIG. Thereafter, the low power management unit 110 proceeds to step 306 to determine whether there is movement for a predetermined time, and then performs the steps of FIG. 4.

The low power management unit 110 that proceeds from step 400 to step 401 transmits proximity data for displaying screen information to the application processor 200.

In operation 402, the low power management unit 110 stops driving the motion detection sensor 230, stops operation of the proximity detection sensor 230 in operation 403, and ends the proximity data transmission process by proximity detection.

5 to 7 are flowcharts illustrating a process of displaying screen information according to another embodiment of the present invention.

5 is a flowchart illustrating a process of displaying a screen according to whether it is connected to a vehicle holder according to another embodiment of the present invention.

In step 500, when the mobile terminal is in the sleep mode, the low power management unit 110 determines whether the mobile terminal is connected to the vehicle cradle in step 501 and proceeds to step 502 if the mobile terminal is connected to the vehicle cradle. It is continuously determined whether the terminal is connected to the vehicle cradle.

In step 502, the low power management unit 110 switches the state of the portable terminal to an activation mode.

In operation 503, the low power management unit 110 drives the proximity detection sensor 230 to determine whether a proximity interrupt is generated in operation 504.

When a proximity interrupt occurs, the application processor 200 executes a voice recognition mode in step 505, and if the proximity interrupt does not occur, continuously determines whether a proximity interrupt occurs in step 504. Specifically, when a proximity interrupt occurs, the low power management unit 110 transmits proximity data for executing the voice recognition mode to the application processor 200. Thereafter, the application processor 200 recognizes the user's voice and executes a voice recognition mode capable of controlling the portable terminal.

6 is a flowchart illustrating a process of displaying a screen according to whether or not it is connected to a dock holder of a music playback device when playing music according to another embodiment of the present invention.

In step 600, when the mobile terminal is in the music playback mode, the low power management unit 110 proceeds to step 602 if the mobile terminal is connected to the dock holder of the music playback device in step 601, otherwise it is connected to the dock holder of the music playback device. It continues to judge whether or not it is.

In operation 602, the low power management unit 110 drives the proximity detection sensor 230 to determine whether a proximity interrupt is generated in operation 603.

When a proximity interrupt occurs, the application processor 200 constructs a screen related to the music being played in step 604 and displays it through the display unit 210, and if the proximity interrupt does not occur, continuously determines whether a proximity interrupt occurs in step 603. Judge. Specifically, when a proximity interrupt occurs, the low power management unit 110 transmits proximity data for configuring a screen related to the music being played to the application processor 200. Thereafter, the application processor 200 configures a screen including an interface for controlling music information and music information including an artist, song name, lyrics, and playback time related to the music being played and can be displayed through the display unit 210. have.

7 is a flowchart illustrating a process of displaying a screen for an application running in the background according to another embodiment of the present invention.

In a state in which a specific application has been executed in step 700, the low power management unit 110 determines whether a preset time has elapsed, and if the preset time has elapsed, proceeds to step 702, and if the preset time has not elapsed, continuously in step 701. It is determined whether a preset time has elapsed.

In step 702, the low power management unit 110 switches the state of the portable terminal to the sleep mode.

In operation 703, the low power management unit 110 drives the proximity detection sensor 230 to determine whether a proximity interrupt is generated in operation 704.

When the proximity interrupt is generated, the low power management unit 110 proceeds to step 705, and if the proximity interrupt is not generated, continuously determines whether a proximity interrupt is generated in step 704.

In step 705, the application processor 200 may configure a screen related to a specific application running in the background and display it through the display unit 210. Specifically, when a proximity interrupt occurs, the low power management unit 110 transmits proximity data for configuring a screen for an application running in the background to the application processor 200. Thereafter, the application processor 200 may configure a screen including a name, description, and detailed information for an application running in the background and display it through the display unit 210. For example, when an application running in the background is an application for transmitting and receiving data between a smartphone and another smartphone, the displayed screen may include progress information such as time for data upload or download and data capacity.

At this time, the application that can be executed in the background includes an application for data transmission and reception, a pedometer application, etc. In the present invention, an application for data transmission and reception is described as an example, but all applications executed in the background may be included.

It will be appreciated that embodiments of the invention are feasible in the form of hardware, software or a combination of hardware and software. Any such software may be, for example, volatile or non-volatile storage, such as a storage device such as a ROM, or memory, such as a RAM, memory chip, device or integrated circuit, regardless of whether it is erasable or rewritable. Alternatively, it may be stored in a storage medium readable by a machine (eg, a computer) while being optically or magnetically recordable, for example, a CD, DVD, magnetic disk, or magnetic tape. The low power detection method of the present invention can be implemented by a computer or a portable terminal including a control unit and a memory, and the memory is read by a machine suitable for storing a program or programs including instructions for implementing embodiments of the present invention. It will be appreciated that this is an example of a possible storage medium. Accordingly, the present invention includes a program comprising code for implementing the apparatus or method described in any claim of the present specification and a storage medium readable by a machine (computer, etc.) storing the program. In addition, these programs can be transferred electronically through any medium, such as communication signals, transmitted over a wired or wireless connection, and the present invention suitably includes this equivalent.

In addition, the low power sensing device may receive and store the program from a program providing device connected by wire or wirelessly. The program providing device is configured to perform a wired or wireless communication with a memory for storing a program including instructions for allowing the low power detection device to perform a predetermined content protection method, information necessary for a content protection method, and the low power detection device. It may include a communication unit for performing, and a control unit for automatically requesting the low power detection device or automatically transmitting the corresponding program to the low power detection device.

100: low power detection device
110: low power management department
120: interrupt unit
130: timer
140: memory unit
150: 1st bus
160: second bus
170: 3rd bus
200: application processor
210: display unit
220: input
230: proximity sensor
240: motion detection sensor

Claims (14)

In the mobile terminal,
Application Processor,
Display,
Proximity sensor,
Motion detection sensor, and
Including a low-power detection device, the low-power detection device,
When the proximity to the portable terminal is detected, the posture of the portable terminal is monitored,
It is determined whether the posture of the portable terminal satisfies a preset condition,
It is determined whether there is no movement of the mobile terminal for a preset time based on the posture of the mobile terminal,
Characterized in that the posture of the portable terminal satisfies a preset condition and is determined to provide information on the detected proximity to the application processor based on the determination that there is no movement of the portable terminal during the preset time period. To do, mobile terminal. According to claim 1,
The low power sensing device further includes an interrupt unit configured to generate an interrupt for the proximity sensing sensor,
The low power detection device,
When the mobile terminal is in the sleep mode, the proximity sensor is driven,
When the interrupt for the proximity sensor is generated through the interrupt unit, characterized in that it is further configured to drive the motion sensor, the mobile terminal. According to claim 1,
The low power sensing device is characterized in that the mobile terminal is configured to stop driving the motion detection sensor if the posture of the mobile terminal does not satisfy the preset condition. According to claim 1,
The preset condition is used to determine whether the rotation angle of the mobile terminal with respect to the horizontal direction is greater than or equal to a preset threshold value. According to claim 4,
The low power detection device,
When the rotation angle of the mobile terminal with respect to the horizontal direction is equal to or greater than the preset threshold, it is determined whether there is no movement of the mobile terminal during the preset time,
When there is no movement of the portable terminal for the preset time, and the information on the detected proximity is provided to the application processor, it is further configured to stop driving the proximity sensing sensor. According to claim 3,
The low power sensing device is further configured to determine whether a next interrupt is generated when the mobile terminal is moved for the preset time after the motion detection sensor is stopped. . In the control method of the mobile terminal,
Detecting a proximity of an object to the portable terminal by the proximity sensing sensor of the portable terminal,
A process of detecting the movement and posture of the portable terminal by the motion detection sensor of the portable terminal,
Monitoring a posture of the portable terminal when proximity to the portable terminal is detected by the low power sensing device of the portable terminal;
Determining whether or not the posture of the portable terminal satisfies a preset condition by the low power sensing device;
Determining, by the low power sensing device, whether there is no movement of the mobile terminal for a preset time based on the posture of the mobile terminal;
Based on the determination that the portable terminal satisfies the preset condition and that there is no movement of the portable terminal for the preset time by the low-power sensing device, information on the proximity of the object is applied to the portable terminal. Provided to the processor, the control method of the mobile terminal. The method of claim 7,
The low power sensing device further includes an interrupt unit configured to generate an interrupt for the proximity sensing sensor,
Driving the proximity sensing sensor when the portable terminal is in a sleep mode by the low power sensing device;
When the interrupt for the proximity sensor is generated through the interrupt unit, the low-power detection device, characterized in that it further comprises the step of driving the motion sensor, the control method of the mobile terminal. The method of claim 7,
If the posture of the portable terminal does not satisfy the preset condition, further comprising the step of stopping the driving of the motion detection sensor by the low-power detection device, the control method of the portable terminal. The method of claim 7,
The preset condition is used to determine whether the rotation angle of the portable terminal with respect to the horizontal direction is greater than or equal to a preset threshold, the control method of the portable terminal. The method of claim 10,
If the rotation angle of the mobile terminal with respect to the horizontal direction is greater than or equal to the preset threshold, determining whether or not there is no movement of the mobile terminal for the preset time by the low-power detection device,
If there is no movement of the mobile terminal for the predetermined time, and the information on the detected proximity is provided to the application processor, further comprising the step of stopping the driving of the proximity sensing sensor by the low-power sensing device. Characterized in that, the control method of the mobile terminal. The method of claim 9,
When the mobile terminal is moved for the predetermined time after the motion detection sensor is stopped by the low-power detection device, further comprising determining whether a next interrupt has occurred. The control method of the portable terminal. A computer-readable non-volatile recording medium storing instructions that cause a processor to execute the method of claim 7. delete

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