KR101132677B1 - An apparatus and method for processing control information to prevent micro control unit overload in the display system including a plural number of sensors - Google Patents

Abstract

In the sensor module included in the display device, a sensor module for minimizing the performance degradation of the MCU by preventing the overload of the microcontrol unit (MCU) of the main control module is disclosed.
The sensor module of the display device according to the present invention includes a sensor for receiving input information, a local micro control unit (MCU) for generating control information based on the input information received from the sensor, and a control information received from the local MCU. communication logic to the main micro control unit. Through this, by implementing the sensor and the MCU in one module, it is possible to improve the performance of the entire system by solving the problem of lowering the system implementation efficiency that may occur when the sensor and the MCU are implemented in different modules.

Description

Control information processing apparatus and method for preventing overload of a micro control unit in a display system including a plurality of sensors TECHNICAL FIELD

The present invention relates to a display control method and apparatus, and more particularly, an apparatus for preventing an overload of a micro control unit in a main control module system by processing input information received from each sensor module into individual micro control units in the sensor module. It is about a method.

Recently, various types of display devices, such as a liquid crystal display (LCD) display device, a cathode-ray tube (CRT) monitor, a light emitting diode (LED) display device, etc., are widely used.

Furthermore, in recent years, as the display device is improved, technologies for controlling the display itself as well as display information have been developed.

For example, a liquid crystal display such as an LCD (liquid crystal display) requires a separate light source called a back light because it does not emit light by itself unlike a general CRT, although a separate light source is required. It is widely used in wristwatches, computers, etc. because of its low operating voltage, low power consumption, and miniaturization.

Electronic devices with built-in LCD modules may include various products such as TVs, monitors, mobile phones, and PMPs. Especially, in the case of portable products such as mobile phones and PMPs, the brightness of the screen may vary depending on the brightness of various surrounding environments. The illumination sensor module is developed to allow the user to feel uniform brightness by differently. In addition, recently, as the touch type LCD module has been developed, a sensor module capable of processing touch input information has been developed.

In addition, Hall sensors, which can detect the position or movement of objects by detecting magnetic force of objects with magnetic bodies, and acceleration sensors (G sensors), which can detect gravity, acceleration, and instantaneous shocks of objects, are also developed. These technologies are also being actively applied to portable communication equipment such as TVs, monitors, mobile phones and PMPs in recent years.

As a result of the development of sensors added to the display as well as the display information, a problem that is inevitably caused is an increase in the amount of information that the control module of the display device must process.

In other words, in the past, the main control module embedded in the display device only needed to control the display information and display information such as basic color, brightness, and display coordinate setting, so that the overload of the main control module was not a problem. Since the main control module must process not only the basic display control information but also the information coming from the added sensors, the main control module can be overloaded.

In addition, since the sensor module and the display module typically have different producers, there are difficulties in designing the sensor module or solving problems such as compatibility so as not to overload the main control module of the display device.

1 shows a schematic diagram of a processing circuit of an LCD module according to the prior art.

According to FIG. 1, the processing circuit 100 of the LCD module according to the related art is an illuminance sensor module 110, a main control module 120, a BLU module 130, a display module 140. It is composed.

The illuminance sensor module 110 performs a function of measuring illuminance of the surrounding environment such as natural light and includes an illuminance sensor 111 and communication logic 112. The illuminance sensor 111 measures illuminance of the surrounding environment in which the display device is located, and the communication logic 112 transmits the illuminance value S (V) collected by the illuminance sensor 111 to the main control module 120. To perform.

The main control module 120 performs a function of controlling the overall system and includes a peripheral logic 121, an MCU 122, and a communication logic 123. Peripheral logic 121 may interface with other peripherals (not shown) that may interoperate with the display device, and MCU 122 may include a display including measurement of BLU control values (F (S (V))). The communication logic 123 performs the function of controlling the overall system of the device and transmits the control information generated by the MCU 122 to the BLU module 130.

The BLU module 130 performs a function of emitting light as a light source, and receives a BLU control value F (S (V)) from the main control module 120 for this purpose.

The display module 140 receives a light from the BLU module 130 and performs a function of performing a display.

In the prior art, in the case of an adaptive LCD module that allows a user to feel a uniform brightness by changing the brightness of the screen according to the change of the brightness of the surrounding environment, first, the illumination sensor module 110 recognizes the ambient light, The recognized illuminance value S (V) is transmitted to the main control module 120 through the communication module. The MCU 122 transmits a BLU control value (F (S (V)) value) corresponding to the recognized illuminance value S (V) to the BLU module 130.

At this time, since all control and arithmetic operations in the display device are generally processed in the MCU 122, in order to calculate the BLU control value (F (S (V)) value) according to the prior art, the MCU 122 The problem arises that must handle the task other than the unique task of the main control module.

That is, although the illuminance of the surrounding environment necessary for measuring the BLU control value is measured by the illuminance sensor 111 of the illuminance sensor module 110, since the generation of the BLU control value is made in the main control module 120, the illuminance In the case where the developers of the sensor module 110 and the main control module 120 are different from each other, the complementarity of the sensor module 110 and the main control module 120 are different, and thus, it is difficult to efficiently develop the entire system. Due to the nature of processing the BLU control value measurement process other than the inherent process, the MCU was overloaded or degraded, resulting in a slow processing speed.

Therefore, it is required to develop a method and a device that enable efficient system development and prevent overload of the MCU in measuring the BLU control value.

The present invention is to solve the above problems, an object of the present invention is to provide a micro control unit (microcontrol unit; MCU) for measuring the BLU control value based on the specific sensor and sensor information for measuring the BLU control value It is to provide an apparatus and method that can solve the problem of lowering the efficiency of system implementation that may occur by being implemented in a separate module.

Another object of the present invention is to mitigate the problem of overloading and performance degradation of the MCU in the main control module that may occur when the BLU control value is generated by the MCU in the main control module based on the information received from the sensor added to the display device. It is to provide a method and apparatus that can be.

In order to achieve the above object, the present invention provides an apparatus and method that can minimize the overload of the MCU in the display device.

The sensor module of the display device according to the present invention includes a sensor for receiving input information, a local micro control unit (MCU) for generating control information based on the input information received from the sensor, and a control information received from the local MCU. It may include communication logic to transmit to the main micro control unit.

In one embodiment according to the device, the sensor may include one or more of an illumination sensor, a hall sensor, and a touch sensor.

In addition, in one embodiment according to the device, the sensor module may be implemented as an integrated circuit (IC).

Further, in one embodiment according to the device, the illuminance sensor can measure natural light and / or infrared light.

The sensor module of the display device according to the present invention is controlled based on the first sensor receiving the first input information, the first input information received from the first sensor and the second input information received from the second sensor in the other sensor module. It may include a local micro control unit (MCU) for generating information, and a communication logic for transmitting the control information.

In one embodiment according to the device, the first sensor, the second sensor may include one or more of the illuminance sensor, the Hall sensor, the touch sensor.

In addition, in one embodiment according to the device, the sensor module may be implemented as an integrated circuit (IC).

Further, in one embodiment according to the device, the illuminance sensor can measure natural light and / or infrared light.

According to the present invention, the sensor and the controller (micro control unit (micro control unit) by implementing a controller for measuring the BLU control value based on the specific sensor and sensor information for recognizing the sensor information for measuring the BLU control value in one sensor module unit)) can improve the performance of the entire system by solving the problem of lowering the efficiency of system implementation that can occur when each module is implemented in different modules.

According to the present invention, it is possible to alleviate the problem of overloading and performance degradation of the main controller (main micro control unit) in the main control module generated by measuring the BLU control value.

1 shows a schematic diagram of a processing circuit of an LCD module according to the prior art.
2 illustrates a sensor circuit device for controlling backlight of a liquid crystal display according to an exemplary embodiment of the present invention.
3 illustrates a sensor circuit device for backlight control of a liquid crystal display device to which a touch sensor module is added according to an embodiment of the present invention.
4 illustrates a sensor circuit device for backlight control of a liquid crystal display device in which communication logic of each module directly transmits information to a BLU module according to an embodiment of the present invention.
5 is a flowchart illustrating a control information processing procedure in a display apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail the present invention. In the reference numerals to the components in each drawing, it is noted that the same reference numerals are assigned to the same procedures and components even though they are shown in different drawings.

2 illustrates a sensor circuit device for controlling backlight of a liquid crystal display according to an exemplary embodiment of the present invention.

According to FIG. 2, the processing circuit 100 of the LCD module according to the present invention includes an illumination sensor module 110, a main control module 120, a BLU module 130, and a display module 140. Include.

The illuminance sensor module 110 measures the illuminance of the surrounding environment such as natural light or infrared ray (IR ray), and the illuminance sensor 111, the communication logic 112, and the second micro control unit (113). The main control module 120 performs the function of controlling the overall system and includes the peripheral logic 121, the first MCU 122, and the communication logic 123. The BLU module 130 performs a function of emitting light as a light source, and the LCD module 140 receives a light from the BLU module 130 and performs a display.

Performance of each module according to an embodiment of the present invention is as follows.

The illuminance sensor module 110 measures the illuminance of the surrounding environment in which the display device is located and performs the function of measuring the BLU control value F (S (V)). The illuminance sensor 111 may be a natural light sensor and / or an infrared (IR) sensor. The function performed by the illuminance sensor 111 and the communication logic 112 is the same as that of FIG. 1 described above, and further includes a second MCU 113 to measure the BLU control value F (S (V)). . Therefore, the communication logic 112 transmits the BLU control value F (S (V)) measured by the illuminance control sensor module 110 to the main control module 120 instead of the illuminance value S (V).

In implementing the illuminance sensor module, for example, the communication logic 112 performs communication through an inter-integrated circuit (I2C) communication method, the second MCU 113 is an 8-bit (8-bit) MCU Can be implemented. However, according to an embodiment of the present invention, the second MCU 113 may be replaced with a 16-bit MCU or a 32-bit MCU, and the communication logic 112 may be replaced with a SPI, USART, SMbus, LIN, and CAN communication method. It is possible.

The main control module 120 performs the function of controlling the overall system and includes a peripheral logic 121, a first MCU 122, a communication logic 123, the peripheral logic 121 and the communication logic 123 is The function to perform is the same as FIG.

The first MCU 122 generates control information based on input information received from the peripheral device, and receives and merges the BLU control value F (S (V)) measured by the second MCU. Therefore, according to the present invention, unlike the prior art, since the BLU control value F (S (V)) is measured by the second MCU 113 in the illuminance sensor module 110, the first MCU 122 separately uses the BLU. It is not necessary to measure the control value F (S (V)).

As a result, it is possible to prevent an overload problem in processing other control information, and when a sensor needs to be added to a display device, only a sensor module needs to be added without having to worry about replacing the main module due to the risk of overload.

The BLU module 130 performs a function of emitting light as a light source, and receives a BLU control value F (S (V)) from the main control module 120 for this purpose. However, according to the embodiment, it will be possible to directly receive the BLU control value F (S (V)) from the illuminance sensor module 120.

However, in the case of a display device such as an AM OLED (active matrix organic light-emitting diode) that does not require a BLU module, control information may be transmitted to a display module instead of a BLU module. In such an implementation, a BLU module may be implemented. The spirit of the present invention may be implemented in a removed state.

The display module 140 outputs the information processed by the image processor (not shown) through the control of the BLU module 130.

The present invention can be implemented in a display device with a touch sensor such as a tablet PC or a touch screen liquid crystal screen, as well as a general display device, and further includes a touch sensor module when a touch display device is used.

3 illustrates a sensor circuit device for backlight control of a liquid crystal display device to which a touch sensor module is added according to an embodiment of the present invention.

According to FIG. 3, the processing circuit 100 of the LCD module according to the present invention includes an illumination sensor module 110, a main control module 120, a BLU module 130, a display module 140, and a touch module 150. It is composed.

The touch sensor module 150 includes a touch sensor 151, communication logic 152, a third MCU 153, and includes an illuminance sensor module 110, a main control module 120, a BLU module 130 and a display. The configuration of module 140 is shown in FIG.

The touch sensor 151 recognizes a user's touch input, generates touch information TS (V2), and transmits the touch information TS (V2) to the third MCU 153. The third MCU 153 measures touch control information TF (TS (V2)) based on the touch information TS (V2). The touch control information TF (TS (V2)) measured by the third MCU 153 is transmitted by the communication logic 152 to the first MCU 122 in the main control module 120.

In this way, the touch sensor module measures the touch control information TF (TS (V2)) and transmits it to the first MCU 122 without transmitting the touch information TS (V2) to the first MCU 122. In this case, it is possible to optimize touch sensitivity by optimizing parameters required for measurement.

However, according to a modified implementation of the present invention, the second MCU 113 and the third MCU 153 may perform the role of the removed MCU even if one of the MCU is not removed and in this case, the illumination sensor ( The control information measured by the 111 and the touch sensor 151 may be transmitted to the MCU which is not removed, merged, and transmitted to the first MCU 122.

For example, the S (V) value measured by the illuminance sensor 111 is not included in the illuminance sensor module 110 but separately provided to the third MCU 153 in the touch sensor module 150. Can be used to measure the BLU control value (F (S (V))).

On the contrary, the touch input information measured by the touch sensor 151 is transmitted to the second MCU 113 in the illuminance sensor module 110 without separately including the third MCU 153 in the touch sensor module 150. It may be possible to measure (TF (TS (V2))).

The information measured by the second MCU 113 and the third MCU 153 is transmitted to the first MCU 122 through the communication logic 112 and 152 and combined with other control information to the BLU module 130. do.

Therefore, since the first MCU 122 performs a role of merging control information measured by the second and third MCUs 113 and 153 with other information and transmitting the same to the BLU module 130, the first MCU 121 may be overloaded. This can solve problems such as lowering the processing speed.

4 illustrates a sensor circuit device for backlight control of a liquid crystal display device in which communication logic of each module directly transmits information to a BLU module according to an embodiment of the present invention.

According to FIG. 4, unlike in FIGS. 2 and 3, in order to transmit control information to the BLU module 130, whether each of the MCUs 113, 122, and 153 transmits the merged control information from the first MCU. Send control information directly to the BLU module 130.

The functions of the illuminance sensor module 110, the main control module 120, the BLU module 130, the display module 140, and the touch sensor module 150 are the same as those of FIG. 3, except that each module 110, 120, 150 is used. Communication logic (112, 123, 152) of the control information (F (S (V)), peripheral control information, TF (TS (V2))) received from the MCU of the module directly to the BLU module (130) Send.

5 is a flowchart illustrating a control information processing procedure in a display apparatus according to an embodiment of the present invention.

Each sensor (illuminance sensor, touch sensor) receives natural light, infrared light, and touch input information of the surrounding environment (S110).

The collected information is transmitted to each MCU (second MCU, third MCU) located in each module (S120).

The second MCU and the third MCU generate control information by using the collected information (S130).

Each control information measured by the second MCU and the third MCU is transmitted to and merged with the first MCU in the main control module (S140).

The first MCU merges the control information generated by the control information collected from the second MCU and the third MCU and the information collected from the peripheral logic and transmits the generated control information to the BLU module (S150).

Also, as another embodiment of the present invention, a method of sharing two MCUs by implementing two or more sensors together in one module may be considered.

When implementing two or more sensors in one module, the information coming from the sensor and the processing capacity of the local MCU in the module should be taken into consideration, and trade off of the processing capacity and the implementation volume of the module should be considered. In consideration, the implementation method may be considered.

2 to 4, although each component is implemented as a module as an embodiment of the present invention, it is not limited to a module to implement the spirit of the present invention, an integrated circuit (IC), application-specific semiconductor (ASIC; application- It may be implemented by various methods that can implement the spirit of the present invention, such as a specific integrated circuit), especially in the case of implementing the IC circuit will be advantageous in miniaturization and light weight.

The display module 140 may include a liquid crystal display, a thin film transistor-liquid crystal display, an organic light-emitting diode, a flexible display, and a three-dimensional display. The present invention may be applied to various types of display devices such as 3D display, digital light processing (DLP), liquid crystal display (LCD), plasma display panel (PDP), and the like.

Although the preferred embodiments of the present invention have been described above by way of example, the scope of the present invention should not be construed as being limited to these specific embodiments.

For example, in the preferred embodiment of the present invention, an embodiment in which an illuminance sensor and / or a touch sensor is added to the display device has been described, but the spirit of the present invention is not limited thereto.

As described above, the spirit of the present invention can measure the gravity or acceleration force applied to the object by measuring the gravity or acceleration, or the Hall sensor that can detect the position or movement of the object by sensing the magnetic force of the object moving the magnetic material as described above. The accelerometer may also be implemented in a way that is applied to the display device.

When the Hall sensor is used in the display device, the information processed by the Hall sensor module may be a graphic control module control value, and the information processed by the acceleration sensor module used by the acceleration sensor in the display device may be an acceleration control module control value. will be.

As described above, the illuminance sensor, the touch sensor, the hall sensor, and the acceleration sensor may not only be implemented as separate modules, but also a complex sensor may be implemented as one module, and as each individual module, Could be implemented together.

In the present invention, a method of implementing the illuminance sensor and the touch sensor in the display device has been described as an embodiment, and the hall sensor and the acceleration sensor have been described as additional examples, but the present invention is within the scope of the spirit and claims of the present invention. Modifications, changes, or improvements in various forms will be made, and the present invention will be directed not only to the same idea but to the equivalent idea.

Claims (8)

A sensor for receiving input information;
A local micro control unit (MCU) for generating control information for directly controlling a BLU module or a display module based on the input information received from the sensor; And
And a communication logic to directly transmit the control information received from the local MCU to the BLU module or the display module. The method of claim 1,
The sensor module of the display device including at least one sensor of the illuminance sensor, the Hall sensor, the touch sensor, the acceleration sensor. The method according to claim 1 or 2,
The sensor module is a sensor module of a display device implemented as an integrated circuit (IC). The method of claim 2,
The illuminance sensor measures at least one of natural light and infrared light. A first sensor receiving first input information;
Based on the first input information received from the first sensor and second input information received from a second sensor in another sensor module, control information for directly controlling a BLU module or a display module is generated. A local micro control unit (MCU); And
And a communication logic for directly transmitting the control information to the BLU module or the display module. The method of claim 5, wherein
The first sensor and the second sensor are sensor modules of the display device including at least one sensor of the illuminance sensor, the hall sensor, the touch sensor, the acceleration sensor. The method according to claim 5 or 6,
The sensor module is a sensor module of a display device implemented as an integrated circuit (IC). The method according to claim 6,
The illuminance sensor measures at least one of natural light and infrared light.

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