KR102273965B1 - Method for controlling signage and signage for performing the method - Google Patents

Abstract

The present invention relates to a method for controlling an object output on a signage based on temperature and the signage performing the same. The method for controlling the object output on the signage based on temperature includes the steps of: determining, by the signage, an LED module group (temperature) based on the temperature of an LED (light emitting diode) module; and determining, by the signage, object properties output on the LED module group (temperature) by the signage based on the LED module group (temperature). Accordingly, deterioration due to heat of the signage may be prevented by sensing the temperature on the signage and changing an object color and/or a position of the object output to the signage.

Description

A method for controlling an object output on a signage based on temperature and a signage for performing such a method {Method for controlling signage and signage for performing the method}

The present invention relates to a method for controlling an object output on a signage based on temperature, and a signage for performing such a method. More particularly, it relates to a method of sensing the temperature of each position of the signage, controlling the color and position of an object output on the signage according to the sensed temperature, and a signage performing such a method.

Digital signage refers to outdoor media that provides various contents and messages through digital displays rather than conventional hardware media, such as posters, guide signs, and signboards displayed on roadsides, stores, and public facilities. In other words, digital signage is used as a medium for transmitting information and advertisements using digital technology.

Recently, with the rapid development of intelligent digital imaging devices based on liquid crystal display (LCD) and light emitting diode (LED), digital signage is becoming more common. The demand and market for digital signage is showing rapid growth.

The digital advertising market is expected to show continuous growth despite the overall global economic downturn, and from the convergence media perspective, digital signage is also digitized and information, art, content, and corporate marketing needs are combined. It is expected to play a role as a new means to replace the existing media advertisements.

Digital signage is often installed outdoors. Digital signage installed outdoors is exposed to the external environment and is affected by the external environment, and deteriorates faster than signage installed indoors, resulting in the lifetime of the LED module constituting the signage. This will be relatively short.

Therefore, there is a need for research and development on a method for checking the state of the digital signage and improving the lifespan of the digital signage through control according to the state of the digital signage.

An object of the present invention is to solve all of the above problems.

In addition, an object of the present invention is to prevent deterioration of the signage due to heat by sensing the temperature on the signage and changing the object color and/or the position of the object output to the signage.

In addition, the present invention considers all of the image output to the signage and the external environment of the signage, but more accurately measures the temperature of each of a plurality of LED modules constituting the signage to signage due to heat generated in the signage. It can manage deterioration and increase the life of the signage.

A representative configuration of the present invention for achieving the above object is as follows.

According to an embodiment of the present invention, in a method of controlling an object output on a signage based on temperature, the signage determines an LED module group (temperature) based on the temperature of an LED (light emitting diode) module. and determining, by the signage, the object property output on the LED module group (temperature) based on the LED module group (temperature).

Meanwhile, the object property may include an object color and/or an object location.

In addition, the signage changes the object color of the object when the LED module group (temperature) is above the critical temperature (object color) and less than the critical temperature (object position), and the signage is the LED module group (temperature) ) is above the critical temperature (object position), the object position of the object may be changed.

According to another embodiment of the present invention, a signage for controlling an object output based on temperature receives temperature information from a temperature sensor unit implemented to determine a temperature of a light emitting diode (LED) module and the temperature sensor unit It may include a processor implemented to do this, wherein the processor determines an LED module group (temperature) based on the temperature of the LED module, and outputs on the LED module group (temperature) based on the LED module group (temperature) It can be implemented to determine the object property to be

Meanwhile, the object property may include an object color and/or an object location.

In addition, the processor changes the object color of the object when the LED module group (temperature) is greater than or equal to a threshold temperature (object color) and less than a threshold temperature (object location), and the processor determines that the LED module group (temperature) is When the threshold temperature (object position) is higher than the threshold temperature (object position), the object position of the object may be changed.

According to the present invention, deterioration due to heat of the signage can be prevented by sensing the temperature on the signage and changing the object color and/or the position of the object output to the signage.

In addition, according to the present invention, although both the image output to the signage and the external environment of the signage are taken into consideration, the temperature caused by the heat generated in the signage is more accurately measured through the temperature measurement of each of a plurality of LED modules constituting the signage. Signage deterioration can be managed, and the lifespan of the signage can be increased.

1 is a conceptual diagram illustrating a signage according to an embodiment of the present invention.
2 is a conceptual diagram illustrating an operation of a signage according to an embodiment of the present invention.
3 is a conceptual diagram illustrating a method of determining a temperature for each LED module according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a method for determining LED module grouping (temperature) according to an embodiment of the present invention.
5 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.
6 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.
7 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.
8 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.
9 is a conceptual diagram illustrating an operation of an object positioning unit according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0023] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented with changes from one embodiment to another without departing from the spirit and scope of the present invention. In addition, it should be understood that the location or arrangement of individual components within each embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description given below is not to be taken in a limiting sense, and the scope of the present invention should be taken to cover the scope of the claims and all equivalents thereto. In the drawings, like reference numerals refer to the same or similar elements throughout the various aspects.

Hereinafter, various preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those of ordinary skill in the art to easily practice the present invention.

1 is a conceptual diagram illustrating a signage according to an embodiment of the present invention.

In FIG. 1 , a signage operating based on a temperature sensed based on a temperature sensor is disclosed. According to an embodiment of the present invention, the operation of the signage is controlled based on the temperature sensed by the temperature sensor, thereby reducing the deterioration of the signage and improving the lifespan of the signage.

Referring to FIG. 1 , a signage may include a display unit 100 , a temperature sensor unit 110 , an object color determination unit 120 , an object position determination unit 130 , and a processor 140 .

The display unit 100 may be implemented to output image information. The display unit 100 may be composed of a plurality of LED modules. Hereinafter, the expression LED module is used for convenience of description, but various optical modules other than the LED module may be used, and the LED module may be used in a sense including these various optical modules.

The temperature sensor unit 110 may be implemented to sense heat generated by a signage. The temperature sensor unit 110 may include a plurality of temperature sensors. The plurality of temperature sensors correspond to each of the plurality of LED modules and/or each of the plurality of LED module groups (temperature sensors) including at least one LED module, so that each of the plurality of LED modules and/or the plurality of LED module groups (temperature sensors) ) can sense the temperature for each. The temperature sensed by the temperature sensor may be determined based on heat generated by each of a plurality of LED modules or each of a plurality of LED module groups (temperature sensors), and heat generated by an external environment (external temperature, light quantity, etc.). The LED module group (temperature sensor) is a unit including a plurality of LED modules that correspond to one temperature sensor and become a temperature measurement target.

The temperature information sensed by the plurality of temperature sensors may be transmitted to the processor 140 .

The object color determiner 120 may be implemented to determine a color of an object (eg, text) output from a display based on temperature information sensed by a plurality of temperature sensors. According to an embodiment of the present invention, the amount of heat generated from the LED module can be changed due to the color temperature for each color. By changing the object color, it is possible to control the amount of heat generated from the LED module. The lifespan of the signage can be increased based on temperature control through such object color change.

The object position determiner 130 may be implemented to determine a position of an object (eg, text) output from a display based on temperature information sensed by a plurality of temperature sensors. According to an embodiment of the present invention, the position of an object output from a specific LED module sensed at a high temperature is changed to another LED module, so that it is possible to control the amount of heat generated by the LED module. Similar to object color change, the lifespan of signage can be increased based on temperature control through object position change.

The processor 140 may be implemented to control operations of the display unit 100 , the temperature sensor unit 110 , the object color determiner 120 , and the object position determiner 130 .

2 is a conceptual diagram illustrating an operation of a signage according to an embodiment of the present invention.

In FIG. 2 , a method of sensing the temperature of an LED module and an LED module group (temperature sensor) positioned on a display through a temperature sensor on the display unit is disclosed. The arrangement of the temperature sensor disclosed in FIG. 2 is an example, and the temperature sensor may be disposed in various ways. The LED module group (temperature sensor) may be a group of adjacent LED modules based on the position of the temperature sensor.

2 (a) is a temperature sensor arrangement (first type) 210 .

The temperature sensor arrangement (first type) 210 is an arrangement of temperature sensors for sensing a temperature value for each of a plurality of LED modules constituting the display. In the temperature sensor arrangement (first type) 210 , each of the plurality of temperature sensors may correspond to each of the plurality of LED modules. Determination of the temperature of each of the plurality of LED modules constituting the current signage may be performed based on the plurality of temperature sensing values generated by each of the plurality of temperature sensors, and may be determined by the object color determination unit and the object position determination unit Object color and object position may be determined.

2(b) is a temperature sensor arrangement (second type) 220 .

The temperature sensor arrangement (second type) 220 is an arrangement of temperature sensors for sensing a temperature value corresponding to each of a plurality of LED module groups (temperature sensors) including a plurality of LED modules constituting the display. In the temperature sensor arrangement (second type) 220 , each of the plurality of LED module groups (temperature sensors) may correspond to each of the plurality of temperature sensors based on a position. Determination of the temperature state of the plurality of LED modules included in the current signage may be performed based on the plurality of temperature sensing values generated by each of the plurality of temperature sensors, and may be determined by the object color determination unit and the object position determination unit Object color and object position may be determined.

2( c ) is a temperature sensor arrangement (third type) 230 .

The temperature sensor arrangement (third type) 230 is an arrangement in which a temperature sensor including a plurality of LED modules constituting a display is arranged in units of LED modules and/or LED module groups (temperature sensors).

A temperature sensor may be adaptively disposed on the display according to the accuracy required for the temperature measurement value, and accordingly, an area on the display may be divided and the temperature measurement may be performed. For example, in the temperature sensor arrangement (third type) 230 , relatively more temperature sensors may be arranged in the center where the output frequency of the object is high than in the peripheral part. In the temperature sensor arrangement (third type) 230 , a temperature sensor may be arranged to enable more accurate temperature measurement in a region in which a relatively large amount of heat is generated.

A temperature for each LED module may be determined according to a temperature sensor arrangement (first type) 210 , a temperature sensor arrangement (second type) 220 , and a temperature sensor arrangement (third type) 230 .

3 is a conceptual diagram illustrating a method of determining a temperature for each LED module according to an embodiment of the present invention.

3 discloses a method of determining a temperature for each LED module according to a temperature sensor arrangement (first type), a temperature sensor arrangement (second type), and a temperature sensor arrangement (third type). In the present invention, the temperature of each of the plurality of LED modules included in the signage is determined in consideration of the temperature sensor arrangement type, and the LED module group (temperature) is determined by grouping the LED modules in consideration of the temperature of each of the plurality of LED modules. The LED module group (temperature) can be a unit for object color change and object position change.

3 discloses a method of determining the temperature of each of a plurality of LED modules in order to determine the LED module group (temperature).

Referring to FIG. 3 , in the temperature sensor arrangement (first type) 310, the temperature of each of the plurality of LED modules is measured by each of the plurality of temperature sensors corresponding to each of the plurality of LED modules, and a plurality of LED modules are measured without a separate calibration procedure. A temperature corresponding to each of the LED modules may be determined.

In the temperature sensor arrangement (second type) 320, the temperature sensor arrangement (third type) 330 for measuring the temperature corresponding to the LED module group (temperature sensor) corresponds to the LED module group (temperature sensor) 340 The temperature is measured, and a temperature corresponding to each of the plurality of LED modules included in the LED module group (temperature sensor) 340 may be determined through correction based on the temperature of the LED module group (temperature sensor) 340 . .

The temperature corresponding to each of the plurality of LED modules included in the LED module group (temperature sensor) 340 may be determined based on the ambient temperature and the temperature of the LED module group (temperature sensor) 340 .

For example, the LED module group (temperature sensor) 340 may include an LED module 1 , an LED module 2 , an LED module 3 , and an LED module 4 . When the temperature sensed corresponding to the LED module group (temperature sensor) 340 is x degrees, the default temperature of the LED module 1, LED module 2, LED module 3, and LED module 4 may be x degrees. Thereafter, the default temperature of each of LED module 1, LED module 2, LED module 3, and LED module 4 is to be determined based on the temperature of the LED module located around each of LED module 1, LED module 2, LED module 3, and LED module 4. can

For example, when the LED module 5 is located around the LED module 3, the temperature of the LED module 3 may be determined as an average value of the temperatures of the LED module 3 and the LED module 5 . Similarly, when the LED module 6 is located around the LED module 4, the temperature of the LED module 4 may be determined as an average value of the temperatures of the LED module 4 and the LED module 6. When the peripheral LED module is present in this way, the default temperature of the LED module included in the LED module group (temperature sensor) 340 may be adjusted in consideration of the temperature of the peripheral LED module.

Based on the position of the LED module included in the LED module group (temperature sensor) 340, there may be a plurality of peripheral LED modules, and according to an embodiment of the present invention, a plurality of other peripheral LED modules located in the periphery of the LED module The average value including up to may be determined as the default temperature of the LED module included in the LED module group (temperature sensor) 340 . For example, when the LED module 5 and the LED module 7 are located around the LED module 1, the temperature of the LED module 1 may be determined as an average value of the temperatures of the LED module 1, the LED module 5, and the LED module 7.

In the above manner, the temperature of the LED module included in the signage may be determined.

Further, according to an embodiment of the present invention, additional correction may be performed on the temperature of the LED module located outside the display and the LED module located at the position where the inflow of external air occurs. The LED module located on the outskirts of the display and the LED module where the inflow of external air occurs may exist in a position where relatively little heat is generated or heat is circulated rapidly, and the LED module determined by the above procedure reflecting this It can be adjusted to a relatively low value by adjusting the temperature of

According to an embodiment of the present invention, a temperature value corresponding to each of the plurality of LED modules may be determined with different temperature determination options (the first temperature determination option 350 and the second temperature determination option 360). In the first temperature determination option 350 , a temperature value corresponding to each of the plurality of LED modules may be determined as a temperature value corrected through the above-described correction procedure.

In the second temperature determination option 360 , a temperature value corresponding to each of the plurality of LED modules may be determined without the above-described correction procedure. Specifically, in the temperature sensor arrangement (first type) 310, a temperature value corresponding to each LED module is measured, and a temperature value corresponding to each of a plurality of LED modules may be determined without a separate calibration procedure. In a temperature sensor arrangement (second type) 320, a temperature sensor arrangement (third type) 330 for measuring a temperature value corresponding to the LED module group (temperature sensor) 340, the LED module group (temperature sensor) ( The temperature value corresponding to 340 is measured, and the temperature value of the plurality of LED modules included in the LED module group (temperature sensor) 340 is the same as the temperature value corresponding to the LED module group (temperature sensor) 340 . can be decided.

The first temperature determination option 350 or the second temperature determination option 360 may be selectively used. By default, the second temperature determination option 360 is used to determine the temperature of each of the plurality of LED modules inside the signage, and the plurality of LED modules through determination based on the second temperature determination option 360 When the temperature of a specific LED module exceeds the threshold temperature (temperature determination option), it is changed to the first temperature determination option 350 to determine the temperature of each of the plurality of LED modules inside the signage.

After the first temperature determination option is changed, the object color and the object position may be changed based on the determination of the object color determiner and the object position determiner.

As a result of the measurement through the first temperature determination option, when the temperature of a specific LED module among the plurality of LED modules is equal to or higher than the threshold temperature (object color), the object color may be changed in an LED module group (temperature) to be described later.

As a result of the measurement through the first temperature determination option, when the temperature of a specific LED module among the plurality of LED modules is equal to or higher than the threshold temperature (object position), the position of the object on the LED module group (temperature) to be described later may be changed. The threshold temperature (object location) may be a value higher than the threshold temperature (object color).

4 is a conceptual diagram illustrating a method for determining LED module grouping (temperature) according to an embodiment of the present invention.

In FIG. 4, LED module grouping based on the temperature of the LED module is disclosed.

Referring to FIG. 4 , when the temperature of each of the plurality of LED modules is determined by the procedure described above in FIG. 3 , temperature-based LED module grouping is performed to determine the LED module group (temperature) 450 .

The LED module group (temperature sensor) is an LED module group grouped based on the location of the temperature sensor and the location of the LED module, and the LED module group (temperature) 450 is an LED module group grouped based on the temperature of the LED module. .

After the temperature of each of the plurality of LED modules is determined based on FIG. 3 described above, the LED module group (temperature) 450 may be determined.

The LED module group (temperature) 450 may be generated by grouping LED modules having a similar temperature change in consideration of the temperature change over time of the LED module. In addition, the LED module group (temperature) 400 may be determined by additionally considering the location of the LED module on the actual LED signage when grouping the LED module.

The LED module group (temperature) 450 may be adaptively changed in consideration of an output object, an output time, an external environment, and the like.

An LED module in which text of a specific color is repeatedly output or adjacent to each other may have an increase/decrease pattern in which the temperature is included in a similar range and the temperature change pattern is the same. According to an embodiment of the present invention, a candidate LED module group (temperature) 400 may be primarily determined by grouping adjacent LED modules among LED modules having a temperature in a similar range and having the same temperature change pattern.

A similar range for determining the candidate LED module group (temperature) 400 may be determined in consideration of the object size, the signage size, and the number of LED modules constituting the signage. Specifically, as the object size is relatively large, the similarity range is set relatively wide, as the signage size is relatively large, the similarity range is set relatively wide, and as the number of LED modules constituting the signage is relatively large, the similarity range is relatively can be set wide.

After the candidate LED module group (temperature) 400 is determined, the LED module group (temperature) 450 may be determined in consideration of the object output pattern output on the signage.

When the object output pattern is a non-repeating non-repeating object output pattern, the candidate LED module group (temperature) 400 may be determined as the LED module group (temperature) 450 .

When the object output pattern is a repeated object output pattern, at least one candidate LED module group (temperature) 400 that outputs the same object in consideration of the output position of the object is grouped and the LED module group (temperature) 450 can be determined. For example, when the same object is output from candidate LED module group 1 (temperature) and candidate LED module group 2 (temperature), candidate LED module group 1 (temperature) and candidate LED module group 2 (temperature) are one LED It may be grouped into a module group (temperature) 450 .

The LED module group (temperature) 450 may be a unit of object color determination unit, object color change based on the object position determination unit, and object position change unit. First, the temperature of the LED module is controlled by changing the color of the object, and when the temperature is not controlled only by changing the color of the object, the temperature of the LED module can be adjusted by changing the position of the object.

For example, when the temperature of the specific LED module is higher than the threshold temperature (object color), the object color of the object output on the LED module group (temperature) 450 including the specific LED module may be changed.

Then, when the temperature of the specific LED module is higher than the threshold temperature (object position), the position of the object output from the LED module group (temperature) including the specific LED module may be changed to another LED module group (temperature).

5 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.

5 discloses a method for determining an object color of an object color determiner. Specifically, a method of changing an original color of an object to another color based on a critical temperature (object color) is disclosed.

Referring to FIG. 5 , the color of the object may be changed by determining whether it corresponds to the critical temperature (object color) 500 and how high the temperature is based on the critical temperature (object color) 500 .

First, when the threshold temperature (object color) is 500 or less, the color of the object may be output as an original color without limitation.

When the critical temperature (object color) 500 is higher, the color of the object may be changed from the original color and output.

In an embodiment of the present invention, the color of the original color may be changed between the critical temperature (object color) 500 or more and below the critical temperature (object position) 520 in consideration of the properties of the object and the output position.

First, the condition in which the color of the original color is changed between the critical temperature (object color) 500 or more and the critical temperature (object position) 520 is the first change condition 535, the second change condition 545, and the second change condition 545. There may be 3 change conditions 555, and the temperature change is subdivided from above the critical temperature (object color) 500 to below the critical temperature (object position) 520, so that the first change condition 535, the second change condition ( 545 ) and may correspond to the third change condition 555 .

Specifically, a temperature section above the temperature (object color) 500 and less than the critical temperature (object location) 520 may be divided into three lower temperature sections 530 , 540 , and 550 . The three lower temperature sections may be a first lower temperature section 530 , a second lower temperature section 540 , and a third lower temperature section 550 .

When the temperature of the LED module corresponds to the first lower temperature section 530 , the color of the object may be changed based on the first change condition 535 .

When the temperature of the LED module corresponds to the second lower temperature section 540 , the object color may be changed based on the second change condition 545 .

When the temperature of the LED module corresponds to the third lower temperature section 550 , the object color may be changed based on the third change condition 555 .

The first change condition 535 may be a condition in which only the color of the object including all objects in the LED module group (temperature) is changed, and in the first change condition 535, the color temperature of the object is gradually changed toward the lower color. The original color may be changed. For example, if the original color of the object is the first color, and the color having a lower color temperature than the first color is the second color and the third color, the first color, the second color, and the third color are changed in the order. can

The second change condition 545 is a condition in which the color of the object located at the boundary of the LED module group (temperature) is also changed in addition to the object including all objects in the LED module group (temperature). However, in the second change condition 545, the order of changing the original color of the object may be determined as follows.

Change 1) The original color of an object using one color among objects located at the boundary of the LED module group (temperature) may be gradually changed to a color having a relatively low color temperature.

Change 2) The original color of an object using multiple colors among objects located at the boundary of the LED module group (temperature) may be gradually changed to a color having a relatively low color temperature.

The third change condition 555 is a condition in which the color of an object including all objects in the LED module group (temperature) and an object located at the boundary of the LED module group (temperature) are changed. However, in the third change condition 555 , unlike the second change condition 545 , the original colors of all objects may be equally changed to the color having the lowest color temperature. That is, unlike the second change condition 545 , the original color of the object, whether the object exists on the boundary line, or whether the object contains different colors is not considered, and in the third change condition 555 , the original color of all objects is A color may be changed to a color having the lowest color temperature.

Hereinafter, the first change condition 535 , the second change condition 545 , and the third change condition 555 are specifically disclosed.

6 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.

6 discloses a method of determining an object color according to a first change condition in an object color determining unit.

Referring to FIG. 6 , objects output on the LED module group (temperature) may be classified into three types.

The object (first type) 610 may be an object including all boundary lines of the object within the LED module group (temperature).

The object (second type) 620 is an object in which all boundary lines of the object are not included in the LED module group (temperature), and the boundary line of the object is located at the boundary within the LED module group (temperature), but the original color is one color It can be an object that is

The object (third type) 630 is an object in which all boundary lines of the object are not included in the LED module group (temperature), and the boundary line of the object is located at the boundary within the LED module group (temperature), but the original color is a plurality of colors It can be an object that is

In the first change condition, the original color of the object (first type) 610 may be gradually changed to a color having a low color temperature.

For example, the original color of the object (first type) 610 is the first color 615, and the color having a lower color temperature than the first color 615 is the second color 625 and the third color ( 635 ), the original color of the object (first type) 610 may be gradually changed to the second color 625 and the third color 635 . In this case, the second color 625 and the third color 635 may be colors corresponding to the spectrum closest to the first color 615 as much as possible so that a sense of heterogeneity is not felt in consideration of other surrounding objects.

In this way, the temperature of the LED module can be lowered by reducing the heat generated by the output of the object.

When the temperature of the LED module falls under the first change condition, the third color 635 and the second color 625 are changed in the reverse order, and when the temperature of the LED module falls below the threshold temperature (object color), the object The color may be set as the original color 615 .

7 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.

7 discloses a method of determining an object color according to a second change condition in the object color determining unit.

The second change condition is applied when the temperature rises to the second lower temperature section even when the original color of the object (first type) is changed through the first change condition.

Referring to FIG. 7 , the color change of the object (second type) 720 and the object (third type) 730 may be gradually performed under the second change condition.

In the second change condition, the original color of the object may be changed based on sequential changes of the change 1 750 and change 2 760 below.

As described above, the second change condition is a condition in which the color of the object located at the boundary of the LED module group (temperature) is changed in addition to all objects within the LED module group (temperature).

Change 1 (750)) The original color of the object (second type) 720 using one color among the objects located at the boundary of the LED module group (temperature) is gradually changed to a color having a relatively low color temperature. can

Change 2 (760)) It is possible to gradually change the original color of an object (third type) 730 using multiple colors among objects located at the boundary of the LED module group (temperature) to a color having a relatively low color temperature. have.

In the second change condition, the heat generated from the LED module is reduced while sequentially changing to change 1 (750) and change 2 (760), but it is possible to minimize the sense of heterogeneity due to the color change of the object.

When the temperature of the LED module falls through the second change condition, the object (third type) 730 corresponding to the change 2 760 is converted to the original color in the reverse order, and the object corresponding to the change 1 750 ( second type) can be converted to the original color. When the LED module temperature falls to the second lower temperature section, the color of the object on the LED module may be changed in response to the first change condition described above in FIG. 6 .

8 is a conceptual diagram illustrating an operation of an object color determiner according to an embodiment of the present invention.

In FIG. 8 , a method of determining an object color according to a third change condition in the object color determining unit is disclosed.

Referring to FIG. 8 , the third change condition includes not only the first object 810 including all objects within the LED module group (temperature), but also the second object 820 positioned at the boundary of the LED module group (temperature) and This is a condition in which the color of the third object 830 is changed. However, in the third change condition, the original color of all objects (the first object 810 , the second object 820 , and the third object 830 ) is changed to the color having the lowest color temperature, unlike the second change condition. can be

That is, when the temperature of the LED module corresponds to the third change condition, the original color of all objects may be changed to the color having the lowest color temperature.

In this way, when the temperature of the LED module is lowered and the temperature of the LED module is changed from the third lower temperature section to the second lower temperature section, the object corresponding to change 2 in the reverse order of the second change condition (third type) The original color may be converted, and the object (second type) corresponding to the change 1 may be converted to the original color.

9 is a conceptual diagram illustrating an operation of an object positioning unit according to an embodiment of the present invention.

9 discloses a method for changing the position of an object in the object position determiner.

Referring to FIG. 9 , when the temperature of the LED module exceeds a threshold temperature (object position), the temperature of the LED module may be adjusted in a manner that changes the position of the object 950 .

An overheated LED module group (temperature) 905 including an LED module having a threshold temperature (object location) or higher can operate by being replaced with another target LED module group (temperature) 910 located in the vicinity of the LED module group (temperature). have.

For example, by setting a specific LED module among other LED module groups (temperature) located in the vicinity of the overheating LED module group (temperature) 905 as the target LED module group (temperature) 910, the target LED module group (temperature) An object 950 being output from the overheating LED module group (temperature) 905 on the 910 is output, and the overheating LED module group (temperature) 905 may be switched to an OFF state.

In this way, as the entire LED module switching method 900, there is no object separately output from the target LED module group (temperature) 910, and it is not dependent on the surrounding LED module group (temperature) on the overheated LED module group (temperature) 905 It can be performed when an independent object is output.

For example, if the text that displays fine dust information is output independently from the surrounding LED module group (temperature) on the overheating LED module group (temperature) 905, and there is no object separately output from the surrounding LED module group (temperature), The entire LED module conversion scheme 900 may be used.

Conversely, as the entire LED module switching method 900 , there is an object separately output from the target LED module group (temperature) 910 or the overheated LED module group (temperature) 905 is the surrounding LED module group (temperature) 910 and In the case of outputting an object in conjunction with each other, some LED module switching methods 920 may be used.

Some of the LED module switching method 920 is a method of moving the position of an object in units of pixels rather than in units of LED modules.

When some LED module switching method 920 is used, the movable range of the object in the first direction, the second direction, the third direction, and the fourth direction may be determined. The object movable range may be a pixel range of the peripheral LED module group (temperature) 910 in which an object is not output based on the overheated LED module group (temperature).

When the movable object range is determined, the position of the object output on the overheated LED module group (temperature) 905 among the movable object range is the most movable direction (for example, 30 pixels in the first direction, The object can be moved in the second direction by 20 pixels).

Through this, the temperature of the overheated LED module group (temperature) 905 is decreased due to the output of the object.

When the temperature of the overheated LED module group (temperature) 905 again falls below the threshold temperature (object position), the changed position of the object may be restored to its original position.

The embodiments according to the present invention described above may be implemented in the form of program instructions that can be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and used by those skilled in the computer software field. Examples of the computer-readable recording medium include hard disks, magnetic media such as floppy disks and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floppy disks. medium), and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. A hardware device may be converted into one or more software modules to perform processing in accordance with the present invention, and vice versa.

In the above, the present invention has been described with reference to specific matters, such as specific components, and limited embodiments and drawings, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. Those of ordinary skill in the art to which the invention pertains can make various modifications and changes from these descriptions.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and the scope of the spirit of the present invention is not limited to the scope of the scope of the present invention. will be said to belong to

Claims (6)

The method to control the object output on the signage based on the temperature is,
determining, by the signage, an LED module group (temperature) based on the temperature of the LED (light emitting diode) module; and
Comprising the step of the signage determining an object property of an object output on the LED module group (temperature) based on the LED module group (temperature),
The object properties include object color and object location,
The signage changes the object color of the object when the LED module group (temperature) is above a critical temperature (object color) or less than a critical temperature (object location),
The signage changes the object position of the object when the LED module group (temperature) is above the threshold temperature (object position),
The LED module group (temperature) includes at least one LED module grouped in consideration of the temperature of each of the plurality of LED modules disposed on the signage,
The critical temperature (object color) is a critical temperature for changing the object color output on the LED module group (temperature),
The critical temperature (object position) is a threshold temperature for changing the position of the object output on the LED module group (temperature). According to claim 1,
The LED module group (temperature) is determined based on the LED module group (temperature sensor),
The LED module group (temperature sensor) is a group of at least one LED module determined based on the position of each of the plurality of temperature sensors disposed on the signage,
The method characterized in that the LED module group (temperature) is corrected in consideration of the arrangement type of each of the plurality of temperature sensors positioned corresponding to the plurality of LED modules disposed on the signage. 3. The method of claim 2,
The object color is changed on a plurality of set lower temperature sections,
The plurality of sub-temperature sections are divided in a range from above the critical temperature (object color) to below the critical temperature (object location),
A plurality of change conditions correspond to each of the plurality of lower temperature sections,
The plurality of change conditions is whether the entire object is included in the LED module group (temperature), whether the object is located at the boundary of the LED module group (temperature), or whether the object located at the boundary has a plurality of colors A method comprising whether or not. In a signage that controls an object output based on temperature,
a temperature sensor unit implemented to determine a temperature of a light emitting diode (LED) module; and
Including a processor implemented to receive temperature information from the temperature sensor unit,
The processor determines the LED module group (temperature) based on the temperature of the LED module,
It is implemented to determine the object property of the object output on the LED module group (temperature) based on the LED module group (temperature),
The object properties include object color and object location,
The signage changes the object color of the object when the LED module group (temperature) is above a critical temperature (object color) or less than a critical temperature (object location),
The signage changes the object position of the object when the LED module group (temperature) is above the threshold temperature (object position),
The LED module group (temperature) includes at least one LED module grouped in consideration of the temperature of each of the plurality of LED modules disposed on the signage,
The critical temperature (object color) is a critical temperature for changing the object color output on the LED module group (temperature),
The critical temperature (object position) is a critical temperature for changing the position of an object output on the LED module group (temperature). 5. The method of claim 4,
The LED module group (temperature) is determined based on the LED module group (temperature sensor),
The LED module group (temperature sensor) is a group of at least one LED module determined based on the position of each of the plurality of temperature sensors disposed on the signage,
The LED module group (temperature) is a signage, characterized in that it is corrected in consideration of the arrangement type of each of the plurality of temperature sensors positioned corresponding to the plurality of LED modules disposed on the signage. 6. The method of claim 5,
The object color is changed on a plurality of set lower temperature sections,
The plurality of sub-temperature sections are divided in a range from above the critical temperature (object color) to below the critical temperature (object location),
A plurality of change conditions correspond to each of the plurality of lower temperature sections,
The plurality of change conditions is whether the entire object is included in the LED module group (temperature), whether the object is located at the boundary of the LED module group (temperature), or whether the object located at the boundary has a plurality of colors Signage, characterized in that it includes whether or not.

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