JP2013206058A - Power supply management device, power supply management method and power supply management program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To use the detection of the proximity of an object by a proximity sensor for power supply management.SOLUTION: A power supply device is configured such that a proximity sensor is disposed in the periphery of a touch panel for an input operation, and that when the proximity of input means such as a finger is detected by the proximity sensor, a performance mode in which performance is given priority is set, and that when the proximity is not detected, an energy saving mode in which partial power supply is turned off is set. In the performance mode, the power supply management device turns on the power source of the touch panel, and controls the touch panel and fully operates a whole CPU operation in the case of a multi-core CPU. In the energy saving mode, the power supply management device turns off the power source of the touch panel, and operates the necessary number of CPU and puts unnecessary CPU in a standby state in the case of the multi-core CPU.

Description

  The present invention relates to a power management device, a power management method, and a power management program, for example, management of power supplied to a display device having a touch panel, a plurality of CPUs, and the like.

Display devices that perform input corresponding to a display screen from a touch panel (touch sensor) arranged on the surface of a display are widely used in various electronic devices such as tablet-type mobile terminal devices and personal computers.
Patent Document 1 proposes a technique for detecting an input operation on a screen with a finger or the like and displaying an input icon on the display screen by arranging a proximity sensor on the display device.

  However, the technique described in Patent Document 1 additionally displays an icon for input operation on a screen being displayed, and uses detection of the proximity of an object by a proximity sensor as a trigger for switching the screen.

JP 2010-277377 A

  An object of the present invention is to use detection of proximity of an object by a proximity sensor for power management.

(1) In the first aspect of the invention, a display that displays an image, a touch panel that is provided on the display and receives an input operation, a physical quantity for a predetermined object is detected, and the detected physical quantity is converted into a distance. When the case value r is less than the value R when the proximity detection threshold is converted into distance, power is supplied according to the proximity detection means for detecting the proximity state and the proximity detection state by the proximity detection means Thus, there is provided a power management apparatus comprising: a mode switching unit that switches between a performance mode in which all devices are operated and an energy saving mode that cuts off power supply to at least the touch panel.
(2) In the invention according to claim 2, the mode switching means switches to the performance mode immediately when the proximity detection means detects the proximity state in the energy saving mode. A power management apparatus as described is provided.
(3) In the invention described in claim 3, the mode switching means switches to the energy saving mode when the non-proximity state continues for a predetermined time or more in the performance mode. A power management device according to item 2 is provided.
(4) In the invention according to claim 4, the mode switching means forcibly switches to the energy saving mode when the physical quantity r detected by the proximity detection means is continuously the same value in the performance mode. The proximity detection means changes a threshold value (distance converted value R) for determining proximity to the physical quantity r continuously detected when the mode switching means forcibly switches to the energy saving mode. A power management apparatus according to claim 1, 2, or 3 is provided.
(5) In the invention according to claim 5, there is provided a power management method for a power management device comprising a display for displaying an image and a touch panel disposed on the display and receiving an input operation, wherein the physical quantity for a predetermined object A proximity detection step for detecting a proximity state when the detected physical quantity is converted into a distance and the value r is less than a value R when the proximity detection threshold is converted into a distance, and the proximity detection A mode switching step for switching between a performance mode in which all devices are operated by supplying power according to the proximity detection state by the step and an energy saving mode for cutting off power supply to the touch panel at least. A power management method is provided.
(6) In the invention according to claim 6, there is provided a power management program for a power management apparatus comprising a display for displaying an image and a touch panel disposed on the display and receiving an input operation, wherein the physical quantity for a predetermined object And a proximity detection function for detecting a proximity state when the detected physical quantity converted to distance is less than a value R when the proximity detection threshold is converted to distance, and the proximity detection A mode switching function that switches between a performance mode in which all devices are operated by supplying power according to the proximity detection state by the function and an energy saving mode that cuts off power supply to the touch panel. Provides a power management program to be realized.

  According to the present invention, since the performance mode and the energy-saving mode are switched according to the proximity detection state by the proximity detection means, the proximity means can be used for suppressing power consumption.

It is a block diagram showing the whole power management system using the power management apparatus with which this embodiment is applied. It is a flowchart showing the content of the whole process by a power management device. It is a flowchart showing a mode switching process.

Hereinafter, preferred embodiments of a power management apparatus, a power management method, and a power management program according to the present invention will be described in detail with reference to FIGS. 1 to 3.
(1) Outline of Embodiment The power management apparatus according to the present embodiment monitors the proximity of an object (input means such as a finger or a touch pen) by a proximity sensor, and when proximity is detected, a touch panel disposed on the display device Alternatively, the mode is switched from the performance mode to the energy saving mode by turning off the power supplied to the multi-core CPU.

That is, when the proximity sensor detects proximity, it can be determined that the user is about to perform an input operation such as a touch panel. On the other hand, if not detected, it can be determined that the user does not perform an input operation. Therefore, a proximity sensor for detecting in advance whether or not an input operation has been performed is provided on a display device on which a touch panel is provided.
When a user input operation is performed, it is necessary to operate the CPU with high performance in order to detect the input operation using the touch panel and to perform various processes based on the input operation. For example, when a finger is dragged on the touch panel, it is necessary for the CPU to scroll the display screen in an amount and a direction corresponding to the detected drag amount while detecting the touch (contact) and the drag amount.
On the other hand, when no input operation is performed, input detection from the touch panel and CPU operation with high performance become unnecessary.

Therefore, the power management device sets the performance mode to prioritize performance when the proximity sensor detects the proximity of an input means such as a finger, and saves energy by turning off part of the power supply when proximity is not detected. Mode.
That is, in the performance mode, the power management apparatus turns on the power of the touch panel, controls the touch panel, and fully operates all CPU operations in the case of a multi-core CPU.
On the other hand, in the energy saving mode, the power management apparatus turns off the power of the touch panel, and in the case of a multi-core CPU, operates a necessary number of CPUs and puts unnecessary CPUs in a standby state. In addition, power supply to peripheral devices that may be subjected to processing and operations based on touch panel operations is also turned off.

(2) Details of Embodiment FIG. 1 is a configuration diagram showing the entire power management system using a power management apparatus to which the present embodiment is applied.
As shown in FIG. 1, the power management apparatus 10 targets the touch panel 30, peripheral device 40, and multi-core CPU 14 for power management.
The power management apparatus 10 includes a proximity sensor 11. The proximity sensor 11 is disposed in the display device 20 where the touch panel 30 is disposed, and detects an input operation to the touch panel 30 in advance by detecting the proximity of an input unit such as a user's finger.

The display device 20 includes a display 21 composed of thin film transistors (TFTs), and displays various images and images of input operation icons.
For example, when the display device 20 is used in a navigation device that is mounted on a vehicle or carried by the vehicle, an input screen for route search is displayed on the display 21, a result of route search is displayed, or the current location is displayed. A map of the surrounding area is displayed. In addition, when displaying an image from a DVD or television, the video is displayed or an operation screen is displayed. In addition, a navigation operation image, a screen corresponding to various functions such as a radio, a CD, and a game, and an input operation screen are displayed.

  Various operation buttons (panel switches) 22 such as a power switch and a menu switch are disposed on the outer frame of the display device 20 (the frame on which the display 21 is disposed).

A proximity sensor 11 is disposed at the lower right of the outer frame of the display device 20. The proximity sensor 11 in the present embodiment outputs infrared rays, measures the distance r from the illuminance of the reflected light to the object (predetermined object), and detects proximity when the measured distance is equal to or less than the threshold value R.
The proximity sensor 11 may use illuminance itself as a measurement parameter for detecting the proximity of an object, or measure a physical quantity that can be converted into a distance such as a sound wave, an electromagnetic wave, or a reflection time.
Although the case where one proximity sensor 11 in the present embodiment is arranged at the lower right of the display 21 will be described as an example, a plurality of proximity sensors 11 may be arranged. That is, it may be arranged in other places such as the lower left and the upper left, arranged in four corners, or arranged in four sides according to the region where the object is desired to be detected. In any case, the number of arrangements and the distance at which one sensor detects proximity is determined depending on which range the proximity sensor 11 detects for proximity.

The touch panel 30 is disposed on the surface of the display 21, and the output of the touch panel 30 is output to the control IC 33.
When the user touches (presses) the touch panel 30, the control IC 33 detects coordinate information (x, y) of the touch position and supplies it to the power management apparatus 10.
The touch panel 30 may be any of an ultrasonic method, a capacitance method, an optical (infrared) method, a distortion method, and a resistive film method, and the control IC 33 is touched by a method according to the method of the touch panel 30. Detection is performed.

The touch panel 30 and the control IC 33 operate by receiving power supply from a common power generation unit 31.
The power generation unit 31, the touch panel 30, and the control IC 33 are connected via a switch 32.
The switch 32 is turned on and off by the power management apparatus 10 based on the determination of switching between the performance mode and the energy saving mode in the present embodiment.

In addition, power is supplied from the power generation unit 41 via the switch 42 to the peripheral device 40 that can perform a specific process or operation corresponding to the presence or absence of an input operation on the touch panel 30.
The switch 42 is also turned on and off by the power management device 10 based on the determination of switching between the performance mode and the energy saving mode.

In FIG. 1, the power generation unit 31 and the power generation unit 41 are described as separate power sources, but a common power source may be used.
However, the switch 32 and the switch 42 are arranged separately and controlled to be turned on and off separately. This is because it is necessary to arrange one switch for each device block that can be turned on / off in common depending on whether or not the situation in which processing and operation of each device are required is common. It is.
In FIG. 1, the switches 32 and 42 are illustrated, but when there is a device block of another process or operation status, a switch for the device block is also provided.

The power management block 13 does not individually determine the switching target based on the determination of switching between the performance mode and the energy saving mode, but turns on and off the power supply to all the devices at once. Also good. In this case, the power supply is provided with a first power supply system that supplies power to all devices subject to mode switching and a second power supply system that is independently supplied regardless of mode switching. An on / off switch is provided for the first power supply system.
However, as will be described later, it is not a device block for turning on / off the power according to the mode switching, but a device block (for example, a multi-core CPU 14 described later) that shifts to an energy saving mode using a well-known technique. Instead of providing a switch for turning on and off the power, power is supplied by a third power supply system (or a second power supply system may be used) to supply mode switching information.

The power management apparatus 10 includes a sensor input unit 12, a power management block 13, and a multi-core CPU 14.
The sensor input unit 12 receives a measurement value from the proximity sensor 11.
The power management block 13 uses the measured value of the proximity sensor 11 as an input value to determine the switching timing between the performance mode and the energy saving mode, and based on the determination, controls the on / off of the switches 32, 42,. The mode switching information for the multi-core CPU 14 is supplied.

The power management block 13 is configured by a computer system including a CPU, ROM, RAM, and storage unit (not shown).
The power management block 13 includes various processing programs such as overall processing and mode switching processing in the present embodiment, and the CPU executes these processing programs to perform processing according to each supply and target The proximity of an object is detected and the mode is switched.
The power management block 13 stores a threshold value R for determining whether or not the object has approached by the proximity sensor 11.
In addition, the power management block 13 includes a timer for measuring a time t (non-proximity time) during which proximity is not continuously detected.
Further, the power management block 13 stores a mode flag for distinguishing whether the currently set mode is the performance mode or the energy saving mode. This mode flag represents a performance mode when the flag is on, and an energy saving mode when the flag is off, and is rewritten each time the mode is switched.

Next, the display processing operation performed by the power management apparatus 10 configured as described above will be described.
FIG. 2 is a flowchart showing the contents of the entire process performed by the power management apparatus 10.
This whole process starts when the power supply of the power management apparatus 10 is turned on.
When the power management block 13 executes the entire flow when the power is turned on, the power management block 13 first performs initialization (step 10).
In this initial setting, the power management block 13 turns on all the switches 32, 42,... To perform the initial setting for each device in order to supply power to each device and device block.
As the initial setting performed here, initial settings corresponding to each device such as white balance adjustment of the display device 20, output adjustment of the proximity sensor 11, and setting of a threshold value R for detecting proximity are performed.

Next, the power management block 13 performs a mode switching process described later (step 11).
Then, the power management block 13 performs processing for each device and device block according to the currently set mode (performance mode, energy saving mode) (step 12).

Then, the power management block 13 determines whether or not the power of the apparatus is turned off (step 13). If not turned off (step 13; N), the process returns to step 11 to perform the mode switching process and other processes. repeat.
When the power is turned off (step 13; Y), the entire flow is also terminated.

FIG. 3 is a flowchart showing the mode switching process.
The power management block 13 reads the input value r of the proximity sensor 11 (step 22), and confirms whether the current mode is the performance mode or the energy saving mode from ON / OFF of the mode flag (step 23).

When the mode flag is off and the current mode is the energy saving mode (step 23; N), the power management block 13 determines whether or not the proximity of the input means such as a finger has been detected (step 24).
That is, the power management block 13 compares the input value r of the proximity sensor read in step 22 with the threshold value R, and determines that the proximity value is close if the input value r is less than the threshold value R.
If proximity is not detected in the energy saving mode (step 24; N), the power management block 13 returns to the main routine while maintaining the current state.

  On the other hand, when the proximity of the input means is detected (step 24; Y), since the touch panel operation by the user is estimated, the power management block 13 immediately switches from the energy saving mode to the performance mode (step 25 to step 27).

That is, the power management block 13 determines which block is currently powered off (step 25).
Then, the power management block 13 turns on the power to the block determined to be turned off (step 26).
In other words, the power management block 13 turns on the switch 32 for supplying power to the touch panel 30 and the control IC 33 and the switch 42 for supplying power to the peripheral device 40 and performs full operation on the multi-core CPU 14. Supply information to indicate.

The power management block 13 performs initialization processing for each block whose power is turned on (step 27), and returns to the main routine.
Here, the initialization process performed by the power management block 13 performs the same process as the initial setting (step 10) performed in the entire process on the block whose power is turned on.

Returning to step 23, if the current mode is the performance mode (step 23; Y), the power management block 13 determines whether or not proximity has been detected in the same manner as in step 24 (step 29).
When proximity is detected in the performance mode (step 29; Y), the power management block 13 returns to the main routine while maintaining the current state.

On the other hand, when proximity is not detected (step 29; N), the power management block 13 determines whether or not the non-proximity time t has passed (step 30).
That is, the power management block 13 determines whether or not the proximity is not detected for the non-proximity time t.
When the non-proximity time t has not elapsed (step 30; N), that is, when the time when no proximity is continuously detected is less than the non-proximity time t, or midway proximity is detected (step 29; Y) If so, the power management block 13 returns to the main routine.

On the other hand, when the non-proximity state of the input means or the like is continuously detected for the non-proximity time t (step 29; N, step 30; Y), the power management block 13 switches from the performance mode to the energy saving mode (steps 31 to 31). 33).
As described above, switching from the energy saving mode to the performance mode immediately switches the mode by detecting proximity in order to quickly respond to the user's input operation, etc., but does not immediately switch from the performance mode to the energy saving mode. The switching is performed after a non-operation guess is made for a certain time (non-proximity time t). Thereby, even when the input means approaches or moves away in a short time, it is possible to prevent the mode from being frequently switched, and to reduce the power consumption required for unnecessary switching.

The power management block 13 determines a block to be turned off among blocks that are power management targets of the power management block 13 (step 31).
In other words, even when switching to the energy-saving mode because the non-operation state has continued, the blocks that require processing or operation corresponding to the specific function currently being processed or the supply block that is in operation are subject to power-off. Excluded from. For example, if none of the visual, audio, and navigation functions are used, the power of the speaker-related block is turned off by the energy saving mode, but when the voice guidance by the navigation function is being executed, The power source of the speaker is excluded from being turned off. In addition, during execution of voice guidance by the navigation function, the processing performance such as detection of the current position of the vehicle and scrolling of the map corresponding to the detected current position is high. Is done.

Then, the power management block 13 performs preprocessing for turning off the power, for example, storing necessary data (step 32), and then turns off the power of the block (touch panel, etc.) determined in step 31 to set the main routine. Return to
That is, the power management block 13 turns off the switches 32, 42,... That supply power to the block that is the target of power off, and supplies the mode switching information to the multi-core CPU 14 (when it is an off target).

The embodiment of the power management device 10 of the present invention has been described above. However, the present invention is not limited to the described embodiment, and various modifications can be made within the scope described in each claim. is there.
For example, in the embodiment described above, a case has been described in which, when proximity is detected in the energy saving mode, switching to the performance mode is performed immediately.
However, for example, when a plastic bottle or the like is placed in the proximity detection range of the proximity sensor 11, the proximity sensor is always in a state of detecting proximity.
Therefore, in the energy saving mode, when proximity is detected, the mode is once switched to the performance mode. However, if the input value r read in step 22 continues to be the same value, an obstacle such as a plastic bottle is permanently installed. The power management device 10 forcibly switches to the energy saving mode.

  In order to avoid detecting proximity due to the obstacle in the energy saving mode after the change by simply detecting an obstacle such as a plastic bottle and forcibly switching to the energy saving mode, the proximity sensor 11 You may make it change the value of the threshold value R for detecting a short distance into the distance r to the plastic bottle detected continuously by step 22. FIG.

In this case, when it is detected that the obstacle has been removed, the threshold value R is returned to the default value R0.
Whether or not the obstacle has been removed is determined that the obstacle has been removed when the input value of the proximity sensor read in step 22 is greater than the changed threshold value R (= r).

As described above, according to the power management apparatus 10 of the present embodiment, the following effects can be obtained.
(1) Proximity sensor 11 is arranged on display device 20, and everything is operated by supplying power to each device block according to the proximity detection state and non-detection state of the object (input means such as a finger). Since the target performance mode and the energy saving mode for cutting off (off) the power supply to some devices are switched, the power consumption can be suppressed.
(2) In addition, since power is not supplied to some devices in the energy saving mode, it is possible to suppress excessive electromagnetic noise from devices that are turned off.
(3) When proximity is detected in the energy saving mode, the mode is immediately switched to the performance mode, so that it is possible to quickly respond to user input operations and the like.
(4) On the other hand, even if the non-proximity state is detected in the performance mode, when the non-detection state continues for a certain time t or longer, the user performs an input operation intermittently by switching to the energy saving mode. Even in such a case, frequent mode switching is avoided.
(5) In the performance mode, when the input value r read in step 22 continues to be the same value, the value of the threshold value R for forcibly switching to the energy saving mode and detecting the short distance by the proximity sensor 11 Is changed to the distance r to the PET bottle continuously detected in step 22, so that the mode is not repeatedly changed even when an obstacle such as a PET bottle is permanently installed. Can do.

DESCRIPTION OF SYMBOLS 10 Power supply management apparatus 11 Proximity sensor 12 Sensor input part 12
13 Power management block 14 Multi-core CPU
20 Display Device 21 Display 22 Operation Button 30 Touch Panel 31 Power Supply Generation Unit 32 Switch 33 Control IC
40 Peripheral equipment 41 Power generator

Claims (6)

A display for displaying images,
A touch panel disposed on the display and receiving an input operation;
Proximity detection means for detecting a proximity state when a physical quantity for a predetermined object is detected and a value r when the detected physical quantity is converted into a distance is less than a value R when a proximity detection threshold is converted into a distance; ,
Mode switching means for switching between a performance mode in which all devices are operated by supplying power according to a proximity detection state by the proximity detection means, and an energy saving mode for cutting off power supply to at least the touch panel; ,
A power management apparatus comprising: The mode switching means immediately switches to the performance mode when the proximity state is detected by the proximity detection means in the energy saving mode.
The power management apparatus according to claim 1. The mode switching means switches to the energy saving mode when the non-proximity state continues for a predetermined time or longer in the performance mode.
The power management apparatus according to claim 1, wherein the power management apparatus is a power management apparatus. The mode switching means forcibly switches to the energy saving mode when the physical quantity r detected by the proximity detection means is continuously the same value in the performance mode,
The proximity detection means, when forcibly switching to the energy saving mode by the mode switching means, changes a threshold for determining proximity (distance converted value R) to the physical quantity r that is continuously detected.
The power management apparatus according to claim 1, claim 2, or claim 3. A power management method for a power management apparatus comprising a display for displaying an image and a touch panel disposed on the display and receiving an input operation,
A proximity detection step of detecting a proximity state when a physical quantity for a predetermined object is detected and a value r when the detected physical quantity is converted into a distance is less than a value R when a proximity detection threshold is converted into a distance; ,
A mode switching step for switching between a performance mode in which all devices are operated by supplying power according to the proximity detection state in the proximity detection step, and an energy saving mode that cuts off power supply to at least the touch panel. ,
A power management method comprising: A power management program for a power management device comprising a display for displaying an image and a touch panel disposed on the display and receiving an input operation,
A proximity detection function for detecting a proximity state when a physical quantity for a predetermined object is detected, and a value r when the detected physical quantity is converted into a distance is less than a value R when a proximity detection threshold is converted into a distance; ,
A mode switching function for switching between a performance mode in which all devices are operated by supplying power according to a proximity detection state by the proximity detection function and an energy saving mode that cuts off power supply to at least the touch panel ,
A power management program that enables computers to realize

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