WO2020237895A1 - Method for automatically adjusting output voltage according to battery power of mobile display device - Google Patents

Abstract

A method for automatically adjusting output voltage according to the battery power of a mobile display device, comprising: a system determining whether each functional module within a mobile display device is turned on/turned off and determining the amount of battery power so as to adjust the voltage outputted to each assembly within the mobile display device as well as screen brightness such that battery power is applied more efficiently, thus attaining a power saving effect, and further increasing battery life.

Description

Method for automatically adjusting output voltage according to battery power of mobile display device Technical field

The invention relates to the field of automatic regulation of battery voltage and power consumption, in particular to

A method to automatically adjust the output voltage according to the battery power of the mobile display device.

Background technique

As the screen resolution and refresh rate of current mobile display devices increase, the power consumption of the screen module is also getting higher and higher. However, the development of batteries for mobile display devices is relatively slow, and how to increase the battery life of mobile display devices under the premise of limited battery capacity has become more and more important. Mobile games, AR (Augmented Reality, augmented reality technology) and VR (Virtual The booming market of Reality (virtual reality technology) has increased the screen refresh rate (Frequency) requirement to 90Hz, 120Hz or even 240Hz.

technical problem

The voltage configuration of each component in the existing mobile display device is based on the screen refresh rate of 60 Hz, which no longer meets the market demand. Therefore, there is a need for a new technology that can adjust the voltage configured to each component according to the current battery power of the display device, so that the battery power can be used efficiently and achieve the effect of power saving.

Technical solutions

The object of the present invention is to provide a method for automatically adjusting the output voltage according to the battery power of the mobile display device, and to determine the on/off of each functional module in the mobile display device and the amount of battery power to adjust the output to the mobile display device The voltage of each component inside.

In order to achieve the above objective, the present invention provides a method for automatically adjusting the output voltage according to the battery power of the mobile display device, the steps of which include:

S1: After the mobile display device is powered on, the system determines whether the automatic voltage adjustment technology is turned on, if it is turned on, go to S2, if not, go to step S4;

Said S2: The power detector of the system detects the battery power and sends the command corresponding to the detected power to the drive integrated circuit according to the preset power-command correspondence;

... S3: The drive integrated circuit determines the output voltage according to the instruction and whether one or more functional modules are turned on;

Said S4: The drive integrated circuit determines the output voltage according to whether one or more of the functional modules are turned on.

The voltage automatic adjustment technology can determine whether to automatically turn on according to the settings of the device to which it is applied before the last shutdown, and can be manually turned on/off at any time on the device in the turned on state.

The functional modules include high frequency application mode (high frequency, HF), ambient light sensor (ambient brightness sensor, ABS), dark screen display (always on One or more of display, AOD) and high brightness mode (HBM).

The power-command correspondence relationship is stored in the power detector.

In the electric quantity-command correspondence relationship, there are three electric quantities with different pole pitches corresponding to three different commands:

Command 1. The corresponding command for power ≤5% is: directly determine the output voltage;

Command 2: 20%≥electricity>5% corresponds to the command: judge whether the ambient light sensor (AOD) is turned on;

Instruction 3. The instruction corresponding to the battery power> 20% is: Determine whether the high frequency application mode (HF) is turned on.

In order to achieve the above objective, the present invention also provides another method for automatically adjusting the output voltage according to the battery power of the mobile display device, the steps of which include:

... S5: After the mobile display device is powered on, the system determines whether the automatic voltage adjustment technology is turned on, if it is turned on, go to S6, if not, go to step S8;

The S6: The drive integrated circuit of the system uses an internal voltage comparator to detect the battery voltage to obtain the battery power;

... S7: The drive integrated circuit determines the output voltage according to the command corresponding to the preset power-command correspondence and whether one or more functional modules are turned on;

Said S8: The drive integrated circuit determines the output voltage according to whether one or more of the functional modules are turned on.

The voltage automatic adjustment technology can determine whether to automatically turn on according to the settings of the device to which it is applied before the last shutdown, and can be manually turned on/off at any time on the device in the turned on state.

The functional module includes one or more of high frequency application mode (HF), ambient light sensor (ABS), dark screen display (AOD), and high brightness mode (HBM).

The electric quantity-command correspondence relationship is stored in the drive integrated circuit.

In the electric quantity-command correspondence relationship, there are three electric quantities with different pole pitches corresponding to three different commands:

Command 1. The corresponding command for power ≤5% is: directly determine the output voltage;

Command 2: 20%≥electricity>5% corresponds to the command: judge whether the ambient light sensor (AOD) is turned on;

Instruction 3. The instruction corresponding to the battery power> 20% is: Determine whether the high frequency application mode (HF) is turned on.

Beneficial effect

The present invention provides a method for automatically adjusting the output voltage according to the battery power of a mobile display device, judging the on/off of each function module in the mobile display device and the amount of battery power to adjust the output to each of the mobile display devices The voltage of the component and the brightness of the screen enable the battery power to be used efficiently, achieve the effect of power saving, and further increase the battery life.

Description of the drawings

In order to further understand the features and technical content of the present invention, please refer to the following detailed description and accompanying drawings of the present invention. However, the accompanying drawings are only provided for reference and illustration and are not used to limit the present invention.

The technical solutions and other beneficial effects of the present invention will be made obvious by describing in detail the specific embodiments of the present invention in conjunction with the accompanying drawings.

In the attached picture,

FIG. 1 is a flow chart of a method for automatically adjusting the output voltage according to the battery power of a mobile display device provided by the present invention.

2 is a flowchart of another method for automatically adjusting the output voltage according to the battery power of the mobile display device provided by the present invention.

3 is a simplified schematic block diagram of a system in a method for automatically adjusting output voltage according to the battery power of a mobile display device according to Embodiment 1 of the present invention.

4 is a simplified schematic block diagram of a system in a method for automatically adjusting output voltage according to the battery power of a mobile display device according to Embodiment 2 of the present invention.

FIG. 5 is a technical flow chart of a method for automatically adjusting the output voltage according to the battery power of the mobile display device according to Embodiment 1 and Embodiment 2 of the present invention.

6 is a voltage configuration table of a method for automatically adjusting the output voltage according to the battery power of the mobile display device according to the embodiment 1 and the embodiment 2 of the present invention.

Embodiments of the invention

In order to further explain the technical means adopted by the present invention and its effects, the following describes in detail the preferred embodiments of the present invention and the accompanying drawings.

Please refer to FIG. 1. FIG. 1 is a flow chart of a method for automatically adjusting the output voltage according to the battery power of a mobile display device provided by the present invention. The specific steps are described in Embodiment 1.

Example 1

This embodiment provides a method for automatically adjusting the output voltage according to the battery power of the mobile display device. The steps include: after the mobile display device is powered on (Power on), the system determines whether the automatic voltage adjustment technology is turned on, and if the system determines the voltage The automatic adjustment technology is turned on. As shown in Figure 3, the power detector of the system detects the battery power and sends the command corresponding to the detected power to the drive integrated circuit according to the preset power-command correspondence. The drive integrated circuit determines the output voltage according to the instruction and whether one or more functional modules are turned on; if the system determines that the automatic voltage adjustment technology is not turned on, the drive integrated circuit directly based on one or more Whether the function module is open or not determines the output voltage.

Specifically, the voltage automatic adjustment technology can determine whether to automatically turn on according to the settings of the device to which it is applied before the last shutdown, and can be manually turned on/off at any time when the device is turned on.

Specifically, the functional module includes one or more of high frequency application mode (HF), ambient light sensor (ABS), dark screen display (AOD), and high brightness mode (HBM).

Specifically, the power-command correspondence relationship is stored in the power detector.

Specifically, as shown in FIG. 5, when the automatic voltage adjustment technology is turned off, the system determines whether the ambient light sensor (ABS) is turned on, and it is not turned on by default. If the ambient light sensor (ABS) is not turned on, it is determined whether the dark screen display (AOD) is turned on, and if the dark screen display (AOD) is not turned on, then the T2 scheme in FIG. The voltage setting corresponding to each component in the mobile display device; if the dark screen display (AOD) is turned on, the voltage setting corresponding to each component in the mobile display device is given according to the T1 scheme in Figure 6; if the ambient light sensor (ABS) is turned on, it is determined whether the high-brightness mode (HBM) is turned on, and it is not turned on by default. If the high-brightness mode (HBM) is not turned on, the voltage corresponding to each component in the mobile display device is given according to the T2 scheme in Figure 6 Settings; if the high-brightness mode (HBM) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T3 scheme in FIG. 6.

Specifically, as shown in FIG. 5, when the automatic voltage adjustment technology is turned on, the system determines whether the battery power Q is> 5%, and if Q ≤ 5%, the mobile display is given according to the T1 scheme in FIG. 6 The voltage settings corresponding to each component in the device; if Q>5%, then judge whether Q>20%, if 20% ≥ Q>5%, then judge whether the ambient light sensor (ABS) is turned on, if the If the ambient light sensor (ABS) is not turned on, it is determined whether the dark screen display (AOD) is turned on, and if the dark screen display (AOD) is not turned on, the mobile display device will be given to the mobile display device according to the T4 scheme in Figure 6 The voltage setting corresponding to each component in the mobile display device; if the dark screen display (AOD) is turned on, the voltage setting corresponding to each component in the mobile display device is given according to the T1 scheme in FIG. 6; if the ambient light sensor ( ABS) is turned on, then it is determined whether the high-brightness mode (HBM) is turned on. If the high-brightness mode (HBM) is not turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T4 scheme in Figure 6 ; If the high-brightness mode (HBM) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T5 scheme in Figure 6; if Q>20%, the high-frequency application mode (HF ) Whether it is turned on, if the high frequency application mode (HF) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T6 scheme in FIG. 6; if the high frequency application mode (HF) is not turned on , It is determined whether the ambient light sensor (ABS) is turned on, if the ambient light sensor (ABS) is not turned on, then it is determined whether the dark screen display (AOD) is turned on, if the dark screen display ( AOD) is not turned on, the corresponding voltage settings of each component in the mobile display device are given according to the T2 scheme in Figure 6; if the dark screen display (AOD) is turned on, the mobile display is given according to the T1 scheme in Figure 6 Display the voltage settings corresponding to each component in the device; if the ambient light sensor (ABS) is turned on, it is determined whether the high brightness mode (HBM) is turned on, and if the high brightness mode (HBM) is not turned on, then follow The T2 scheme in Figure 6 gives the corresponding voltage settings for each component in the mobile display device; if the high brightness mode (HBM) is turned on, the T3 scheme in Figure 6 gives the corresponding voltage settings for each component in the mobile display device. Voltage setting.

Specifically, when the dark screen display (AOD) is turned on, the mobile display device can display part of the screen when the screen is off.

Specifically, when the ambient light sensor (ABS) is turned on, the mobile display device can sense the brightness of the surrounding environment and automatically adjust the screen brightness of the mobile display device.

Specifically, when the high frequency application mode (HF) is turned on, the upper limit of the screen refresh rate of the mobile display device is increased.

Specifically, when the high brightness mode (HBM) is turned on, the screen brightness of the mobile display device is adjusted to the upper limit.

Please refer to FIG. 2. FIG. 2 is a flowchart of another method for automatically adjusting the output voltage according to the battery power of the mobile display device provided by the present invention. The specific steps are described in Embodiment 2.

Example 2

This embodiment provides a method for automatically adjusting the output voltage according to the battery power of the mobile display device. The steps include: after the mobile display device is powered on (Power on), the system determines whether the automatic voltage adjustment technology is turned on, and if the system determines the voltage The automatic adjustment technology is turned on. As shown in Figure 4, the internal drive integrated circuit of the system has a voltage comparator. The voltage comparator detects the voltage of the battery to determine the electric quantity, and obtains it according to the preset electric quantity-command correspondence relationship. Instruction, the drive integrated circuit determines the output voltage according to the instruction and whether one or more functional modules are turned on; if the system determines that the automatic voltage adjustment technology is not turned on, the drive integrated circuit directly based on one or more Whether the function module is turned on determines the output voltage.

Specifically, the voltage automatic adjustment technology can determine whether to automatically turn on according to the settings of the device to which it is applied before the last shutdown, and can be manually turned on/off at any time when the device is turned on.

Specifically, the functional module includes one or more of high frequency application mode, ambient light sensor (ABS), dark screen display (AOD), and high brightness mode (HBM).

Specifically, the power-command correspondence relationship is stored in the power detector.

Specifically, as shown in FIG. 5, when the automatic voltage adjustment technology is turned off, the system determines whether the ambient light sensor (ABS) is turned on, and it is not turned on by default. If the ambient light sensor (ABS) is not turned on, it is determined whether the dark screen display (AOD) is turned on, and if the dark screen display (AOD) is not turned on, then the T2 scheme in FIG. The voltage setting corresponding to each component in the mobile display device; if the dark screen display (AOD) is turned on, the voltage setting corresponding to each component in the mobile display device is given according to the T1 scheme in Figure 6; if the ambient light sensor (ABS) is turned on, it is determined whether the high-brightness mode (HBM) is turned on, and it is not turned on by default. If the high-brightness mode (HBM) is not turned on, the voltage corresponding to each component in the mobile display device is given according to the T2 scheme in Figure 6 Settings; if the high-brightness mode (HBM) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T3 scheme in FIG. 6.

Specifically, as shown in FIG. 5, when the automatic voltage adjustment technology is turned on, the system determines whether the battery power Q is> 5%, and if Q ≤ 5%, the mobile display is given according to the T1 scheme in FIG. 6 The voltage settings corresponding to each component in the device; if Q>5%, then judge whether Q>20%, if 20% ≥ Q>5%, then judge whether the ambient light sensor (ABS) is turned on, if the If the ambient light sensor (ABS) is not turned on, it is determined whether the dark screen display (AOD) is turned on, and if the dark screen display (AOD) is not turned on, the mobile display device will be given to the mobile display device according to the T4 scheme in Figure 6 The voltage setting corresponding to each component in the mobile display device; if the dark screen display (AOD) is turned on, the voltage setting corresponding to each component in the mobile display device is given according to the T1 scheme in FIG. 6; if the ambient light sensor ( ABS) is turned on, then it is determined whether the high-brightness mode (HBM) is turned on. If the high-brightness mode (HBM) is not turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T4 scheme in Figure 6 ; If the high-brightness mode (HBM) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T5 scheme in Figure 6; if Q>20%, the high-frequency application mode (HF ) Whether it is turned on, if the high frequency application mode (HF) is turned on, the corresponding voltage settings for each component in the mobile display device are given according to the T6 scheme in FIG. 6; if the high frequency application mode (HF) is not turned on , It is determined whether the ambient light sensor (ABS) is turned on, if the ambient light sensor (ABS) is not turned on, then it is determined whether the dark screen display (AOD) is turned on, if the dark screen display ( AOD) is not turned on, the corresponding voltage settings of each component in the mobile display device are given according to the T2 scheme in Figure 6; if the dark screen display (AOD) is turned on, the mobile display is given according to the T1 scheme in Figure 6 Display the voltage settings corresponding to each component in the device; if the ambient light sensor (ABS) is turned on, it is determined whether the high brightness mode (HBM) is turned on, and if the high brightness mode (HBM) is not turned on, then follow The T2 scheme in Figure 6 gives the corresponding voltage settings for each component in the mobile display device; if the high brightness mode (HBM) is turned on, the T3 scheme in Figure 6 gives the corresponding voltage settings for each component in the mobile display device. Voltage setting.

Specifically, when the dark screen display (AOD) is turned on, the mobile display device can display part of the screen when the screen is off.

Specifically, when the ambient light sensor (ABS) is turned on, the mobile display device can sense the brightness of the surrounding environment and automatically adjust the screen brightness of the mobile display device.

Specifically, when the high frequency application mode (HF) is turned on, the upper limit of the screen refresh rate of the mobile display device is increased.

Specifically, when the high brightness mode (HBM) is turned on, the screen brightness of the mobile display device is adjusted to the upper limit.

In summary, although the present invention has been disclosed as above in preferred embodiments, the above-mentioned preferred embodiments are not intended to limit the present invention. Those of ordinary skill in the art can make various modifications without departing from the spirit and scope of the present invention. Such changes and modifications, therefore, the protection scope of the present invention is subject to the scope defined by the claims.

Claims (18)

1. A method for automatically adjusting the output voltage according to the battery power of a mobile display device, the steps of which include:

   S1: After the mobile display device is powered on, the system determines whether the automatic voltage adjustment technology is turned on, if it is turned on, go to S2, if not, go to step S4;

   Said S2: The power detector of the system detects the battery power and sends the command corresponding to the detected power to the drive integrated circuit according to the preset power-command correspondence;

   S3: The drive integrated circuit determines the output voltage according to the instruction and whether one or more functional modules are turned on;

   Said S4: The drive integrated circuit determines the output voltage according to whether one or more of the functional modules are turned on.
2. The method of automatically adjusting the output voltage according to the battery power according to claim 1, wherein the automatic voltage-adjusting technology can determine whether to automatically turn on according to the settings of the device to which it is applied before shutting down last time, and the device is turned on It can be turned on/off manually at any time.
3. The method for automatically adjusting the output voltage according to the battery power according to claim 1, wherein the function module includes one or more of a high frequency application mode, an ambient light sensor, a dark screen display, and a high brightness mode.
4. The method for automatically adjusting the output voltage according to the battery power according to claim 1, wherein the power-command correspondence relationship is stored in the power detector.
5. According to the method for automatically adjusting the output voltage according to the battery power according to claim 1, there are three kinds of power with different pole pitches corresponding to three different commands in the power-command correspondence relationship.
6. The method of automatically adjusting the output voltage according to the battery power according to claim 5

   Method, where the command corresponding to the power ≤5% is command one: directly determine the output voltage.
7. The method of automatically adjusting the output voltage according to the battery power according to claim 5

   In which, the instruction corresponding to 20%≥electricity>5% is instruction two: judge whether the ambient light sensor is turned on.
8. The method of automatically adjusting the output voltage according to the battery power according to claim 5

   Method, where the instruction corresponding to the battery power> 20% is instruction three: determine whether the high-frequency application mode is turned on.
9. The method for automatically adjusting the output voltage according to the battery power according to claim 5, wherein the command corresponding to the power ≤5% is command one: directly determine the output voltage;

   Among them, the instruction corresponding to 20%≥electricity>5% is instruction two: judge whether the ambient light sensor is turned on;

   Among them, the instruction corresponding to the battery power> 20% is instruction three: determine whether the high-frequency application mode is turned on.
10. A method to automatically adjust the output voltage according to the battery power, applied to mobile

    In the display device, the steps include:

    S5: The system judges whether the voltage automatic adjustment technology is turned on, if it is turned on, go to

    S6, if not open, go to step S8;

    The S6: The drive integrated circuit of the system uses an internal voltage comparator to detect

    Measuring the battery voltage to obtain the battery power;

    S7: The indicator corresponding to the drive integrated circuit according to the preset power-command correspondence

    The output voltage is determined by whether one or more functional modules are turned on;

    Said S8: The driving integrated circuit is based on whether one or more of the functional modules is

    Whether to open or not determines the output voltage.
11. The method for automatically adjusting the output voltage according to the battery power according to claim 10, wherein the automatic voltage adjustment technology can determine whether to automatically turn on according to the setting before the last shutdown of the device to which it is applied, and when the device is turned on Can be manually turned on/off at any time.
12. The method for automatically adjusting the output voltage according to the battery power according to claim 10, wherein the functional module includes one or more of a high frequency application mode, an ambient light sensor, a dark screen display, and a high brightness mode.
13. The method for automatically adjusting the output voltage according to the battery power according to claim 10, wherein the power-command correspondence relationship is stored in the drive integrated circuit.
14. The method for automatically adjusting the output voltage according to the battery power according to claim 10, wherein in the power-command correspondence relationship, there are three kinds of power with different pole pitches corresponding to three different commands, respectively.
15. The method for automatically adjusting the output voltage according to the battery power according to claim 14

    Method, where the command corresponding to the power ≤5% is command one: directly determine the output voltage.
16. The method for automatically adjusting the output voltage according to the battery power according to claim 14

    In which, the instruction corresponding to 20%≥electricity>5% is instruction two: judge whether the ambient light sensor is turned on.
17. The method for automatically adjusting the output voltage according to the battery power according to claim 14

    Method, where the instruction corresponding to the battery power> 20% is instruction three: determine whether a high-frequency application mode is turned on.
18. The method for automatically adjusting the output voltage according to the battery power according to claim 14, wherein the command corresponding to the power ≤5% is command one: directly determine the output voltage;

    Among them, the instruction corresponding to 20%≥electricity>5% is instruction two: judge whether the ambient light sensor is turned on;

    Among them, the instruction corresponding to the battery power> 20% is instruction three: determine whether the high-frequency application mode is turned on.