JP2017015943A - Display control device, display control system, display control method and display control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow a display device to display information with good visibility.SOLUTION: A display control device 3 includes a determination part 26 which determines whether or not there is a display element whose lighting rate of a display device that is assigned to the display element is a threshold value or less among one or a plurality of display elements that are displayed on a display unit 2 containing a plurality of display devices, and a control part 12 which, if the determination part 26 determines that there is a display element whose lighting rate is the threshold value or less, moves or reduces one or a plurality of display elements so that the lighting rate of each display element contained in one or a plurality of display elements exceeds a threshold value, for display on the display unit 2.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a display control device, a display control system, a display control method, and a display control program.

  Display devices that display information using a plurality of display elements have been put into practical use. For example, a road information board installed on an expressway or the like displays traffic information using a plurality of light emitting diodes (LEDs). Since the road display board is exposed to the external environment, the LED may be damaged due to the influence of rain or wind.

  When a failure occurs in the LED of the road display board, information may not be normally displayed on the road display board. As a related technique, there has been proposed a technique for converting a display symbol into a new display symbol using a display unit other than the abnormal display unit when a display symbol is applied to the abnormal display unit (see, for example, Patent Document 1). ).

JP-A-7-199851

  When predetermined information is displayed by a plurality of LEDs of the display device, the visibility of displayed information decreases when the number of failed LEDs among the LEDs for displaying information increases. In this case, information is not displayed on the display device with good visibility.

  As one aspect, an object of the present invention is to display information on a display device with good visibility.

  In one aspect, the display control device includes a determination unit and a control unit. The determination unit determines whether there is a display element whose lighting rate of the display element assigned to the display element is equal to or less than a threshold value among one or more display elements displayed on the display device including the plurality of display elements.

  When the determination unit determines that there is a display element whose lighting rate is equal to or less than the threshold, the control unit includes one or more lighting units such that the lighting rate of each display element included in the one or more display elements exceeds the threshold value. The display element is moved or reduced and displayed on the display device.

  As one aspect, information can be displayed on the display device with good visibility.

It is FIG. (1) which shows the example of a display of a road display board. It is a figure which shows an example of the display control system of embodiment. It is a figure which shows an example of the table memorize | stored in a memory | storage part. It is FIG. (2) which shows the example of a display of a road display board. FIG. 5 is a first diagram illustrating an example of a partial area of image data. It is a figure (the 3) which shows the example of a display of a road display board. FIG. 10 is a second diagram illustrating an example of a partial region of image data. FIG. 6 is a diagram (part 1) illustrating an example of image data before and after movement of a display character string. It is FIG. (4) which shows the example of a display of a road display board. It is FIG. (5) which shows the example of a display of a road display board. FIG. 6 is a second diagram illustrating an example of image data before and after a display character string is moved. It is a figure which shows an example of the image data before and behind reduction of a display character string. It is FIG. (6) which shows the example of a display of a road display board. It is FIG. (7) which shows the example of a display of a road display board. FIG. 11 is a third diagram illustrating an example of image data before and after a display character string is moved. It is FIG. (8) which shows the example of a display of a road display board. It is FIG. (9) which shows the example of a display of a road display board. It is a figure which shows an example of the image data before and behind the movement of a display figure. It is FIG. (10) which shows the example of a display of a road display board. It is a flowchart (the 1) which shows an example of the flow of a process of embodiment. It is a flowchart (the 2) which shows an example of the flow of a process of embodiment. It is a flowchart (the 3) which shows an example of the flow of a process of embodiment. It is a figure which shows the other example of a road display board. It is a figure which shows an example of the display control system of a modification. It is a figure which shows the example of a display of the screen part of a modification. It is a flowchart (the 1) which shows an example of the flow of a process of a modification. It is a flowchart (the 2) which shows an example of the flow of a process of a modification. It is a figure which shows an example of the hardware constitutions of a display control apparatus.

<Example of road display board of embodiment>
Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 shows an example of a road display board 1. The road display board 1 is installed in the upper part of roads, such as a highway and a general road, for example. The road display board 1 includes an LED display unit 2. The road display board 1 is an example of a display device including a plurality of display elements.

  In the embodiment, it is assumed that a plurality of LEDs are arranged vertically and horizontally on the LED display unit 2. The LED is an example of a display element. The display element is not limited to the LED. For example, the display element may be a lamp or the like.

  When each LED of the LED display unit 2 is turned on or off, predetermined information is displayed on the LED display unit 2. For example, in the example of FIG. 1, the LED display unit 2 displays that “accident closure” has occurred between “Tokyo” and “Yokohama”. The information displayed on the LED display unit 2 is changed by changing the lighting state of each LED (whether it is turned on or off).

  The LED display part 2 of the road display board 1 is exposed to the external environment, and a failure such as disconnection or short circuit may occur in the LED due to the influence of rain, wind, or the like. The LED in which a failure has occurred does not light up. Accordingly, a portion of the information displayed on the LED display unit 2 that uses the failed LED is missing.

  In the embodiment, a case where the display device is a road display board will be described, but the display device is not limited to a road display board. For example, the display device may be a display guide plate or the like installed in a railway vehicle.

<Example of display control apparatus and road display board of embodiment>
FIG. 2 shows an example of a display control system 4 including a plurality of road display boards 1 and a display control device 3. In the example of FIG. 2, the display control device 3 and the plurality of road display boards 1 are connected via a network NW. In addition, the road display board 1 connected to the display control apparatus 3 may be one.

  The display control device 3 performs display control so that predetermined information is displayed on the LED display unit 2 of the road display board 1. The display control device 3 is realized by a computer including a processor and a memory, for example.

  In the embodiment, the display control device 3 performs control to display traffic information on the LED display unit 2 of the road display board 1. The display control device 3 is installed in, for example, a road control center.

  As shown in the example of FIG. 2, the road display board 1 includes an LED display section 2 and a road display board control section 10. The road display board control unit 10 includes a first communication unit 11, an LED control unit 12, and a failure LED detection unit 13.

  The first communication unit 11 communicates with the display control device 3 via the network NW. The LED control unit 12 performs lighting control (control to turn on or off) each LED included in the LED display unit 2 based on display control by the display control device 3. By this lighting control, arbitrary traffic information is displayed on the LED display unit 2.

  In the embodiment, the LED control unit 12 performs lighting control of each LED based on the image data received from the display control device 3. One pixel (one pixel) of the image data corresponds to one LED of the LED display unit 2 (hereinafter, one LED may be referred to as one dot).

  The fault LED detection unit 13 detects a faulty LED among the LEDs included in the LED display unit 2. For example, the fault LED detection unit 13 may detect a faulty LED based on the voltage or current of the unit to which the LED is connected.

  When a failure occurs in the LED included in the LED display unit 2, the failure LED detection unit 13 creates failure information in which the failed LED is specified. As described above, the LED display unit 2 of the embodiment has a plurality of LEDs arranged vertically and horizontally.

  For example, the failed LED may be specified by the row number and column number of the LEDs arranged vertically and horizontally. In this case, the failure information may be information including a row number and a column number. When the failure LED detection unit 13 detects that a plurality of LEDs have a failure, the failure LED detection unit 13 creates failure information that specifies the plurality of failed LEDs.

  Next, the display control device 3 will be described. The display control device 3 includes a second communication unit 21, an image data creation unit 22, a failure information acquisition unit 23, a failure information reflection unit 24, a calculation unit 25, a determination unit 26, a storage unit 27, and a display control unit 28. The 2nd communication part 21 communicates with the 1st communication part 11 of each road display board 1 via network NW.

  The image data creation unit 22 creates image data for displaying traffic information on the LED display unit 2 of the road display board 1. The traffic information is information related to road traffic, and may be information such as road regulations and traffic jams, for example. For example, traffic information is input to the image data creation unit 22 from a device or the like that manages traffic information.

  The traffic information displayed on the LED display unit 2 includes one or more display elements. The display element may be a character or a graphic such as a symbol.

  The image data creation unit 22 assigns a plurality of pixels to one display element in the image data in which pixels corresponding to the respective LEDs arranged vertically and horizontally on the LED display unit 2 are arranged. When the traffic information includes a plurality of display elements, the image data creation unit 22 assigns a plurality of pixels to each display element. Thereby, the 1 or several display element showing traffic information is reflected in image data.

  The image data creation unit 22 reflects each display element on the image data so that each display element is displayed at an appropriate position and size when the traffic information is displayed on the LED display unit 2. Hereinafter, an example in which the traffic information is represented by a plurality of display characters will be described. An example in which the traffic information includes display characters and display figures will be described later.

  The failure information acquisition unit 23 acquires failure information from the road display board 1 via the network NW. As described above, the failure information is created by the failure LED detection unit 13. The failure information acquisition unit 23 is an example of an acquisition unit.

  The failure information reflecting unit 24 reflects the failure information in the image data created by the image data creating unit 22. The failure information is information for identifying the failed LED. One pixel of the image data corresponds to one LED (one dot) of the LED display unit 2. For this reason, when failure information is reflected in image data, a pixel corresponding to a failed LED in the image data is specified.

  When the display control device 3 is connected to a plurality of road display boards 1 via the network NW, the failure information reflecting unit 24 reflects the failure information on the image data for each of the plurality of road display boards 1.

  The calculation unit 25 calculates the lighting rate of each display character included in the image data reflecting the failure information. When the display character is displayed on the LED display unit 2, the lighting rate indicates a rate of LEDs that are lit (non-failed LED) among a plurality of LEDs assigned to the display character.

  As described above, one pixel of the image data corresponds to one LED of the LED display unit 2. In addition, the failure information acquisition unit 23 acquires failure information for specifying the failed LED in the LED display unit 2.

  The calculation unit 25 subtracts the number of pixels corresponding to the failed LED among the pixels assigned to the display character from the number of pixels assigned to the display character, thereby obtaining the number of pixels corresponding to the LED to be lit. The number may be calculated.

  The calculation unit 25 may calculate the lighting rate of the display character by dividing the number of pixels corresponding to the LED to be lit among the pixels assigned to the display character by the number of pixels assigned to the display character. Good.

  If the number of pixels assigned to the display character is the same as the number of pixels corresponding to the LED to be lit, the lighting rate is 100%. On the other hand, the lower the number of pixels corresponding to the LEDs to be lit among the pixels assigned to the display characters, the lower the lighting rate.

  When the display control device 3 is connected to the plurality of road display boards 1 via the network NW, the calculation unit 25 calculates the lighting rate of each display character for each of the plurality of road display boards 1.

  The determination unit 26 compares the lighting rate of the display character calculated by the calculation unit 25 with a threshold value of the lighting rate of the display character, and determines whether the lighting rate is equal to or less than the threshold value for each display character. The determination unit 26 refers to the table stored in the storage unit 27 and recognizes the display character threshold.

  The storage unit 27 will be described. The storage unit 27 stores the correspondence between the display characters and the lighting rate threshold value in a table format. FIG. 3 shows an example of a table stored in the storage unit 27. The table in the example of FIG. 3 includes items of name, display character, kanji code, number of dots, threshold (lighting rate), and threshold (number of dots).

  The name is the name of the display character. The display character is display character data reflected in the image data. A kanji code is a code of a display character. The number of dots indicates the number of LEDs assigned to display characters among the plurality of LEDs of the LED display unit 2. The number of dots is also the number of pixels (number of pixels) assigned to display characters in the image data.

  The threshold value (lighting rate) is a value that indicates the threshold value of the display character as a percentage. The threshold (number of dots) is a value obtained by multiplying the number of dots of display characters by the threshold (lighting rate). Hereinafter, the threshold value (lighting rate) is simply referred to as a threshold value. The threshold value may be set to an arbitrary value.

  The threshold value may be used, for example, to determine whether the visibility of display characters is good. In the embodiment, when the lighting rate of the display characters exceeds the threshold value, even if the lighting rate of the display characters is not 100%, it is displayed on the LED display unit 2 with good visibility. On the other hand, when the lighting rate of the display characters is less than or equal to the threshold value, the visibility of the display characters decreases, and the display characters are not displayed on the LED display unit 2 with good visibility.

  As illustrated in the example of FIG. 3, the storage unit 27 stores a threshold corresponding to each display character. For example, when the display character is complicated (in the case of a kanji having a large number of strokes), the threshold may be set high. In addition, when the display character is not complicated (in the case of a kanji with a small number of strokes), the threshold may be set low.

  Therefore, the determination unit 26 refers to the table in the storage unit 27 and performs comparison to determine whether the lighting rate of the display characters is equal to or less than the threshold based on the threshold set for each display character. For this reason, appropriate determination according to each of a plurality of types of display characters is performed.

  When the display control device 3 is connected to the plurality of road display boards 1 via the network NW, the determination unit 26 determines that the lighting rate of each display character is equal to or less than the threshold for each of the plurality of road display boards 1. Determine whether.

  The display control unit 28 performs display control of one or more display characters displayed on the LED display unit 2 of the road display board 1. The display control unit 28 is an example of a control unit.

  The display control unit 28 displays the LED on the road display board 1 so that the display is based on the image data created by the image data creation unit 22 or image data obtained by performing predetermined image processing on the image data. The display control of the unit 2 is performed.

  In the embodiment, the display control unit 28 controls the second communication unit 21 so that the image data is transmitted to the road display board 1. The first communication unit 11 of the road display board 1 receives image data from the second communication unit 21 via the network NW, and the LED control unit 12 is assigned to display characters among the pixels included in the image data. The LED corresponding to the selected pixel is turned on.

  The display control unit 28 performs image processing for moving or reducing one or more display characters included in the image data when the display characters whose lighting rate is determined to be equal to or less than the threshold are included in the image data.

  As described above, the LED control unit 12 performs lighting control of each LED of the LED display unit 2 based on the image data. When the display control unit 28 performs image processing for moving or reducing one or a plurality of display characters on the image data, the LED control unit 12 determines whether each display character is moved or reduced based on the image data. LED lighting control is performed.

  Thereby, the display control unit 28 performs display control of one or a plurality of display characters displayed on the LED display unit 2.

  Hereinafter, when display characters determined to have a lighting rate equal to or lower than the threshold value are included in the image data, the display control unit 28 moves or moves a plurality of display characters including the display characters (hereinafter referred to as display character strings). An example of reduction will be described.

  The display control unit 28 may perform either one of movement and reduction of the display character string or may perform both movement and reduction. The display control unit 28 may move or reduce one display character.

  On the other hand, when the lighting rate of each display character included in the image data exceeds the threshold, the lighting rate of each display character is high. In this case, since each display character is displayed on the LED display unit 2 with good visibility, the display control unit 28 does not move or reduce the display character.

  The image data creation unit 22 creates image data in which each display character is displayed at an appropriate position and size when traffic information is displayed on the LED display unit 2. Therefore, when each display character is displayed on the LED display unit 2 at a high lighting rate, if the display character is moved or reduced, the visibility may be lowered.

  For this reason, the display control unit 28 does not move or reduce each display character when the lighting rate of each display character included in the image data exceeds the threshold value. In this case, each display character with a high lighting rate is displayed on the LED display unit 2 of the road display board 1 at an appropriate position and size. Therefore, the traffic information is displayed on the LED display unit 2 with good visibility.

  When the display control device 3 is connected to a plurality of road display boards 1 via the network NW, the display control unit 28 performs display control on each road display board 1 individually.

  Note that the display control unit 28 may perform display control of one or more display characters displayed on the LED display unit 2 by a method other than the method of using image data. For example, the display control unit 28 transmits a control signal for individually turning on or off each LED of the LED display unit 2 to the road display board 1 so that the LED control unit 12 performs lighting control of each LED. Good.

<Specific example>
FIG. 4 shows an example of the road display board 1 when some of the LEDs in the LED display section 2 are out of order. In the example of FIG. 4, the shaded region is a region where the LED has failed (hereinafter, referred to as a failure region 30). The failure area 30 includes a plurality of LEDs.

  In the example of FIG. 4, among the display characters displayed on the LED display unit 2, some of the display characters “stop” are included in the failure area 30. Accordingly, among the plurality of LEDs assigned to the “stop” display character, the LEDs included in the failure area 30 are not lit.

  However, among the plurality of LEDs assigned to the “stop” display character, only a few LEDs are faulty and most of the remaining LEDs are lit. Accordingly, the lighting rate of the “stop” display character is high, and the display character is displayed on the LED display unit 2 with good visibility.

  The failure information acquisition unit 23 acquires failure information for identifying the failed LED from the failure LED detection unit 13 of the road display board 1 via the network NW. The failure information reflecting unit 24 reflects the acquired failure information on the image data created by the image data creating unit 22.

  The calculation unit 25 calculates the lighting rate of each display character based on the image data reflecting the failure information. FIG. 5 shows an example of a part of the image data in which the failure information is reflected, including a display character “stop”.

  In the example of FIG. 5, one cell represents one pixel of the image data. That is, one grid corresponds to one dot of LED. Black squares represent pixels corresponding to the LEDs that are lit. This pixel is referred to as a first pixel 31.

  In the example of FIG. 5, the square pixels surrounded by a thick line are LEDs assigned to the display character “stop” and are pixels corresponding to the failed LED. This pixel is referred to as a second pixel 32. The LED corresponding to the second pixel 32 is not lit.

  In the example of FIG. 5, the number of first pixels 31 is 38 and the number of second pixels 32 is two. The sum (= 40) of the number of first pixels 31 and the number of second pixels 32 is the number of pixels assigned to the display character “stop”.

  The number of pixels is also the number of LEDs assigned to the display character “stop” among the LEDs included in the LED display unit 2. The number of pixels (number of LEDs) assigned to the display character is not limited to the example of FIG.

  The calculation unit 25 divides the number of first pixels 31 (= 38) by the sum of the number of first pixels 31 and the number of second pixels 32 (= 40). In this case, the lighting rate of the “stop” display character is “95.0%”.

  The determination unit 26 refers to the threshold value (= 80%) of the “stop” display character in the table of the storage unit 27 and compares the threshold value with the lighting rate. In this case, the determination unit 26 determines that the lighting rate of the “stop” display character exceeds the threshold value.

  The failed LED in the LED display unit 2 is an LED included in the failure area 30 and the other LEDs are lit. The display character overlapping with the failure area 30 is “stop”. Therefore, the lighting rate of each display character other than “stop” is 100%, which exceeds the threshold.

  Therefore, the lighting rate of each display character displayed on the LED display unit 2 exceeds the threshold value. In this case, the display control unit 28 does not move or reduce the display character string of the image data. For this reason, the display control unit 28 performs control so that the image data created by the image data creation unit 22 is transmitted to the road display board 1.

  The LED control unit 12 of the road display board 1 performs lighting control of each LED of the LED display unit 2 based on the image data created by the image data creation unit 22. Thereby, since each display character is displayed on the LED display unit 2 at an appropriate position and size, traffic information is displayed on the LED display unit 2 with good visibility.

  FIG. 6 shows an example in which the number of failed LEDs among the LEDs assigned to the “stop” display characters of the LED display unit 2 is larger than in the example of FIG. In the case of the example in FIG. 6, the lighting rate of the “stop” display character is low, and the visibility of the display character is reduced.

  In the example of FIG. 7, the number of first pixels 31 is 31, and the number of second pixels 32 is nine. The calculation unit 25 divides the number of first pixels 31 (= 31) by the total number of first pixels 31 and second pixels 32 (= 40). In this case, the lighting rate of the display character “stop” is “77.5%”.

  Accordingly, the determination unit 26 determines that the lighting rate of the “stop” display character is equal to or less than the threshold value (= 80%). In this case, the visibility of the “stop” display character displayed on the LED display unit 2 is lowered, and there is a possibility that correct traffic information may not be provided to the user who uses the road.

  In this case, the display control unit 28 performs image processing on the image data to move or reduce a display character string including display characters whose lighting rate is equal to or less than a threshold value. FIG. 8 shows an example of image data 40 for causing the LED display unit 2 to display traffic information related to road regulation caused by an accident.

  In FIG. 8, “before moving” image data 40 is an example of the image data 40 created by the image data creation unit 22. Further, “after moving” image data 40 indicates the image data 40 after the display control unit 28 performs image processing for moving the display character string.

  In the embodiment, the predetermined area of the image data 40 is divided into a plurality of blocks. The image data 40 in the example of FIG. 8 shows an example in which a predetermined area is divided into four blocks B1 to B4. In the example of FIG. 8, each block is divided by a one-dot chain line.

  Each block includes a display character string. In the embodiment, it is assumed that a display character string included in one block includes at least one word.

  The determination unit 26 determines, for each block, whether there is a display character whose lighting rate is equal to or less than a threshold in the display character string. When it is determined that there are display characters whose lighting rate is equal to or lower than the threshold, the display control unit 28 includes a plurality of blocks including other blocks adjacent to or within the block including the display characters whose lighting rate is equal to or lower than the threshold. Move or reduce the display string within the area.

  Of the image data 40, the display character string “Tokyo” is included in the block B1. The display character string “-Yokohama” is included in the block B2. The display character string “Accident” is included in the block B3. The display character string “block” is included in the block B4.

  In the example of FIG. 8, the display character strings included in the block B1 and the block B2 indicate the start point or end point of the road regulation section. The display character string included in the block B3 indicates the cause of road regulation. The display character string included in the block B4 indicates an event of road regulation.

  The display control unit 28 moves the display character string in a block including display characters whose lighting rate is equal to or less than the threshold when the lighting rate of the display character closest to the boundary with another adjacent block is equal to or less than the threshold in a certain block. To do.

  On the other hand, in a certain block, when the lighting rate of display characters other than the display character closest to the boundary with another adjacent block is equal to or less than the threshold value, the display control unit 28 displays within the area including other adjacent blocks. Move a string.

  In the example of FIG. 8, it is assumed that in block B4, it is determined that the lighting rate of “stop”, which is a display character other than the display character closest to the boundary with another adjacent block B3, is equal to or less than the threshold value. Further, it is assumed that it is determined that other blocks than the block B4 do not include display characters whose lighting rate is equal to or lower than the threshold value.

  In this case, the display control unit 28 moves or reduces the display character string within an area including the block B3 and the block B4 adjacent to the block B3. In the example of FIG. 8, the display control unit 28 moves the display character string “accident closure” obtained by combining “accident” included in the block B3 and “passage” included in the block B4.

  In the example of FIG. 8, since the block B1 and the block B2 do not include display characters whose lighting rate is equal to or less than the threshold value, the display control unit 28 moves or reduces the display character strings included in the blocks B1 and B2. Absent.

  The display control unit 28 detects a region where the lighting rate of each display character included in the display character string exceeds the threshold while moving the display character string within the region including the block B3 and the block B4. For example, every time the display control unit 28 moves the display character string, the determination unit 26 may determine whether the lighting rate of each display character included in the display character string exceeds a threshold value.

  The display control unit 28 may detect an area having the highest pixel presence rate corresponding to the LED in which no failure has occurred in the two areas of the block B3 and the block B4, and move the display character string to the area. Good. In this case, there is a high possibility that the lighting rate of each display character included in the display character string exceeds the threshold value.

  The area where the display character string is moved is an area including two blocks, block B3 and block B4, and the area is wider than the area of one block. Since the display control unit 28 moves the display character string in a wide area, it is easy to detect an area where the lighting rate of each display character included in the display character string exceeds the threshold value.

  In the image data 40 “after movement” in FIG. 8, it is assumed that the lighting rate of each display character string included in the display character string “accident closure” exceeds the threshold.

  The display control unit 28 performs control to transmit the “after movement” image data 40 to the road display board 1. The LED control unit 12 performs lighting control of each LED of the LED display unit 2 based on the image data 40. Thereby, the traffic information as shown in the example of FIG. 9 is displayed on the LED display unit 2.

  On the LED display unit 2, the display characters “stop” after movement are displayed at a high lighting rate. For this reason, the lighting rate of each display character of the LED display part 2 becomes high, and traffic information is displayed on the LED display part 2 with favorable visibility.

  Next, an example in which the display character string is reduced will be described. FIG. 10 shows a display example of the road display board 1 when the failure area 30 is further widened and the lighting rate of the “stop” display character is further lowered. FIG. 11 shows an example of “before moving” image data 40 and “after moving” image data 40.

  Similar to the example shown in FIG. 8, the display control unit 28 moves the display character string “Accident Closed” within the areas of the blocks B3 and B4.

  The display control unit 28 moves the display character string “Accident Closure” in a direction away from the position of the display character “Stop”. The image data 40 “after movement” in FIG. 11 shows an example in which the display control unit 28 moves the display character string to an area where the pixel presence rate corresponding to the LED that has not failed is highest.

  However, in this example, since the failure area 30 is wide, even if the above movement is performed, the lighting rate of the display character “stop” after the movement is still below the threshold value. In block B3 and block B4, it is assumed that an area in which the lighting rate of all display characters of the display character string “accident closure” does not exceed the threshold is not detected.

  For example, when traffic information based on the “after movement” image data 40 in FIG. 11 is displayed on the LED display unit 2, the display character “stop” is displayed on the LED display unit 2 because the lighting rate is equal to or less than the threshold value. Not displayed with good visibility.

  In this case, the display control unit 28 reduces the display character “accident character string” at a predetermined scale (for example, 90%). The “before reduction” image data 40 in FIG. 12 is the “after movement” image data 40 in FIG.

  The image data 40 “after reduction” in FIG. 12 shows an example in which the display control unit 28 reduces the display character string of “accident closure” included in the image data 40 “before reduction”. When this display character string is reduced, it is assumed that the lighting rate of the “stop” display character exceeds the threshold. In this case, the lighting rate of each display character included in the image data 40 exceeds the threshold value.

  The display control unit 28 performs control to transmit the image data 40 in which the display character string “Accident Closure” is moved and reduced to the road display board 1. The LED control unit 12 performs lighting control of each LED of the LED display unit 2 based on the image data 40.

  As shown in the example of FIG. 13, the display character string “accident closure” has been moved and reduced, but the lighting rate of each display character is high. For this reason, the visibility as the whole display character string is favorable. That is, since the lighting rate of each display character displayed on the LED display unit 2 is high, the traffic information is displayed on the LED display unit 2 with good visibility.

  Next, a case where the lighting rate of the display character closest to the boundary with another adjacent block in a certain block is equal to or less than a threshold value will be described. FIG. 14 shows an example in which, among the traffic information displayed on the LED display unit 2, many of the LEDs assigned to the display character “late” are included in the failure area 30.

  In the case of the example of FIG. 14, it is assumed that the lighting rate of the “late” display character is equal to or less than the threshold value. Image data 40 “before movement” in FIG. 15 is an example of image data reflecting failure information of each LED of the LED display unit 2 in FIG. 14.

  In this case, the display control unit 28 detects a region where the lighting rate of each display character included in the display character string “accident” exceeds the threshold in the block B3, and moves the display character string to the region. The image data 40 “after movement” in FIG. 15 shows an example in which the lighting rate of each display character included in the display character string exceeds the threshold after the display character string “accident” is moved.

  The display control unit 28 controls each display character to be displayed on the LED display unit 2 based on the “after movement” image data 40. Thereby, as shown in the example of FIG. 16, the display character “late” is displayed with good visibility on the LED display unit 2. Therefore, traffic information is displayed on the LED display unit 2 with good visibility.

  As described above, the image data creation unit 22 creates the image data 40 for displaying each display character on the LED display unit 2 at an appropriate position and size. For this reason, from the viewpoint of visibility, it is preferable that the number of display characters to be moved or reduced is small.

  When the display control unit 28 moves the display character string included in the block B3 and does not move the display character string included in another block, the number of display characters to be moved decreases. Thereby, the traffic information is displayed on the LED display unit 2 with good visibility.

  Even if the display character string “Accident” is moved, if the lighting rate of the display character “Late” is equal to or lower than the threshold value, the display control unit 28 has a high presence rate of pixels corresponding to non-failed LEDs. The display character string “Accident” may be reduced in the area.

  In the above-described example, the display control unit 28 moves the display character string and then reduces the display character string. However, the display control unit 28 performs only the reduction of the display character string. Also good. Further, the display control unit 28 may move the display character string after reducing the display character string.

  Next, display figures will be described. As described above, the display element may be a display graphic such as a symbol representing a traffic sign. FIG. 17 shows an example in which the traffic information is information that combines display characters and display figures. In the example of FIG. 17, many of the LEDs assigned to the display graphic F are included in the failure area 30.

  In the example of FIG. 18, it is assumed that the lighting rate of the display graphic F included in the “pre-movement” block B4 is equal to or less than the threshold value. The display control unit 28 moves the display graphic F included in the block B4 in the direction of the arrow. Thereby, the lighting rate of the display figure F in the “after movement” image data 40 exceeds the threshold value.

  FIG. 19 shows a display example of the LED display unit 2 based on the “after movement” image data 40. The display figure F is displayed on the LED display unit 2 with good visibility. Thereby, the traffic information is displayed on the LED display unit 2 with good visibility.

<Example of Flowchart of Embodiment>
Next, an example of the processing flow of the embodiment will be described with reference to the flowcharts of FIGS. As shown in FIG. 20, first, the image data creation unit 22 creates image data in which traffic information is reflected (step S1).

  For example, when a new road regulation occurs, traffic information is input to the image data creation unit 22. Then, the image data creation unit 22 creates image data reflecting the traffic information by assigning each display character representing the traffic information to a plurality of pixels of the image data.

  The failure information acquisition unit 23 acquires failure information from the failure LED detection unit 13 of each road display board 1 via the network NW. Thereby, the failure information of the LED display part 2 of each road display board 1 is collected (step S2).

  The processing after step S3 is performed for each road display board 1. The failure information reflecting unit 24 reflects the acquired failure information on the image data 40 created by the image data creating unit 22 (step S3).

  The image data 40 reflecting the failure information includes one or more display characters. The calculation unit 25 calculates the lighting rate for each display character included in the image data 40 (step S4).

  The determination unit 26 refers to the table in the storage unit 27 to determine for each display character whether there is a display character whose lighting rate is equal to or less than the threshold (step S5). If it is determined that there is no display character whose lighting rate is equal to or lower than the threshold (NO in step S5), the process proceeds from “A” to step S11.

  When it is determined that there is a display character whose lighting rate is equal to or less than the threshold (YES in Step S5), the display control unit 28 includes a display character string including a display character whose lighting rate is equal to or less than the threshold and a block including the display character string. Identify.

  The display control unit 28 moves the display character string within one block or a region of a plurality of blocks adjacent to each other, and detects a region where the lighting rate of each display character included in the display character string exceeds a threshold value. (Step S6).

  When a region where the lighting rate of each display character included in the display character string exceeds the threshold value is detected (YES in step S7), the display control unit 28 moves the display character string to the detected region (step S8). . Then, the process proceeds from “A” to step S11.

  On the other hand, when the area where the lighting rate of each display character string included in the display character string exceeds the threshold is not detected (NO in step S7), the process proceeds from “B” to step S9. The processes after “B” will be described with reference to the flowchart of FIG.

  The display control unit 28 reduces the display character string at a predetermined scale (step S9). For example, the display control unit 28 moves the display character string to an area where the pixel presence rate corresponding to the non-failed LED is high, and reduces the display character string in the area.

  As a result of performing the reduction in step S9, it is assumed that the determination unit 26 determines that there is no display character whose lighting rate is equal to or lower than the threshold in the display character string (NO in step S10). In this case, the display control unit 28 performs control to display each display character on the LED display unit 2 based on the image data 40 in which the display character string is moved and reduced (step S11).

  In the case of NO in step S5 of FIG. 20 and also in the case of YES in step S7, the process proceeds from “A” to step S11. If the image data 40 does not include display characters whose lighting rate is equal to or lower than the threshold (NO in step S5), the display control unit 28 displays each display character based on the image data 40 created by the image data creation unit 22 as an LED. Control displayed on the display unit 2 is performed. Thereby, the traffic information in which the display character string is not moved and reduced is displayed on the LED display unit 2.

  When the process of step S8 is performed, the display control unit 28 performs display control so that each display character based on the image data 40 whose display character string has been moved is displayed on the LED display unit 2. Thereby, the traffic information in which the display character string was moved is displayed on the LED display part 2.

  After the display character string is reduced in step S9, when it is determined that there is a display character whose lighting rate is equal to or lower than the threshold value in the display character string (YES in step S10), the display control unit 28 turns off the LED display unit 2. Display is made (step S11).

  For example, the display control unit 28 may control the LED display unit 2 so that display based on image data that does not reflect traffic information is performed. Further, the display control unit 28 may perform control for turning off all the LEDs of the LED display unit 2 on the road display board 1. In this case, the LED control unit 12 turns off all the LEDs on the LED display unit 2.

  Next, the subroutine of step S6 will be described with reference to the flowchart of FIG. As described above, the predetermined area of the image data 40 is divided into a plurality of blocks, and each block includes a display character string.

  The determination unit 26 determines whether there is a display character whose lighting rate is equal to or less than a threshold value for each of the blocks in which the predetermined area is divided in the image data 40 (step S6-1). The process of step S6 is performed when display characters whose lighting rate is equal to or less than the threshold value are included in the image data 40.

  The determination unit 26 identifies a block including a display character for which it is determined that the lighting rate is equal to or less than the threshold (step S6-2). And the determination part 26 determines whether the lighting rate of the display character nearest to the boundary between other blocks adjacent to this block is below a threshold value about the specified block (step S6-3).

  When YES is determined in the step S6-3, the display control unit 28 detects an area where the lighting rate of each display character exceeds the threshold in the specified block (step S6-4). On the other hand, in the case of NO in step S6-1, the display control unit 28 detects an area where the lighting rate of each display character exceeds the threshold in the area including the identified block and the block adjacent to the block (step). S6-5).

<Others>
As described above, in the embodiment, when it is determined that there is a display character whose lighting rate is equal to or less than the threshold among one or a plurality of display elements displayed on the LED display unit 2 of the road display board 1, the display control unit In 28, each display element is moved or reduced so that the lighting rate of each display element exceeds the threshold value.

  Thereby, since the lighting rate of each display element exceeds a threshold value, the lighting rate of each display element becomes high. When the lighting rate of each display element becomes high, the visibility of each display element of the LED display unit 2 becomes good, so that traffic information is displayed on the LED display unit 2 with good visibility.

  Even if the lighting rate of each display element of the LED display unit 2 is not 100%, if the lighting rate exceeds the threshold, each display element is displayed on the LED display unit 2 at a high lighting rate. Each display element displayed on the part 2 is displayed with good visibility.

  For example, when the number of failed LEDs is one among many LEDs assigned to a certain display element, it is considered that the visibility of the display element is hardly affected. Thus, when the display element displayed on the LED display unit 2 with good visibility is moved or reduced, the visibility may be lowered.

  As described above, the image data creation unit 22 creates image data for displaying each display element on the LED display unit 2 at an appropriate position and size. In this case, each display element is displayed on the LED display unit 2 at an appropriate position and size.

  When the display element displayed on the LED display unit 2 is moved or reduced at an appropriate position and size, the visibility of the traffic information displayed on the LED display unit 2 decreases.

  Therefore, in the embodiment, the display control unit 28 moves or reduces the display element when it is determined that there is a display element whose lighting rate is equal to or less than the threshold value. For this reason, when the lighting rate of each display element displayed on the LED display unit 2 exceeds the threshold value, the display element is not moved or reduced.

  Thereby, when the lighting rate of each display element exceeds a threshold value, each display element is displayed on the LED display unit 2 at an appropriate position and size, and the LED display unit 2 has good visibility. Traffic information is displayed.

  In the embodiment described above, an example in which the display control device 3 and the road display board 1 are connected via the network NW has been described. However, the display control apparatus 3 may be included in the road display board 1. FIG. 23 shows an example of the road display board 1 including the display control device 3.

  The LED control unit 12 performs lighting control of each LED of the LED display unit 2. The failure LED detection unit 13 detects a failed LED among the LEDs of the LED display unit 2 and creates failure information.

  The image data creation unit 22 creates image data 40 in which traffic information is reflected. The failure information reflection unit 24 reflects the failure information created by the failure LED detection unit 13 in the image data 40. The calculation unit 25 calculates the lighting rate of each display character included in the image data 40.

  The determination unit 26 refers to the table stored in the storage unit 27 and determines whether the lighting rate of the display character is equal to or less than the threshold for each display character. The display control unit 28 controls the LED control unit 12 based on the determination result of the determination unit 26 to perform display control of traffic information displayed on the LED display unit 2.

<Modification>
Next, a modified example will be described. The display control device 3 according to the modification includes a screen unit 51 and an input unit 52 in addition to each unit of the display control device 3 according to the above-described embodiment. The screen unit 51 displays predetermined information. The input unit 52 is, for example, a keyboard or a push button, and is provided for performing a predetermined operation.

  On the screen unit 51, for example, a pre-processing image 40A and a post-processing image 40B shown as an example in FIG. 25 are displayed. The pre-processing image 40A is an example of first image data. The processed image 40B is an example of second image data.

  The pre-processing image 40 </ b> A is image data in which traffic information and failure information are reflected in the image data 40, and display element movement and reduction image processing is not performed on the image data 40. The processed image 40B is image data obtained by subjecting the pre-processed image 40A to image processing for moving and reducing display elements.

  The pre-processing image 40A is a display image of the LED display unit 2 based on the image data 40 before the display element is moved and reduced. The processed image 40B is a display image of the LED display unit 2 based on the image data 40 after the display elements are moved and reduced. Therefore, the screen unit 51 can present both display images to an operator who operates the display control device 3, for example.

  Next, with reference to FIG. 26 and FIG. 27, a flowchart illustrating an example of the flow of processing of the modification will be described. In the flowchart of the modification, the processing up to step S9 is the same as the processing of the above-described embodiment, and thus the description thereof is omitted.

  In step S10, after the display character string is moved and reduced, it is determined whether there is a display character whose lighting rate is equal to or less than a threshold among the display characters included in the display character string.

  If YES is determined in step S10, the display control device 3 issues a warning that there is a display character whose lighting rate is equal to or less than the threshold value in the display character string even when the display character string is moved and reduced (step S10). S21). For example, this warning may be displayed on the screen unit 51.

  Then, the pre-processing image 40A and the post-processing image 40B are displayed on the screen unit 51 (step S22). In the modification, it is assumed that either the pre-processing image 40A or the post-processing image 40B can be selected by the input unit 52.

  For example, when the operator who operates the display control device 3 selects either the pre-processing image 40A or the post-processing image 40B using the input unit 52, the display control device 3 accepts this selection operation.

  When the display control device 3 accepts selection of either the pre-processing image 40A or the post-processing image 40B (YES in step S23), the process proceeds to “C”. When the display control device 3 does not accept any selection between the pre-processing image 40A and the post-processing image 40B (NO in step S23), the display control unit 28 hides the LED display unit 2 (step S24). .

  The processes after “C” will be described with reference to the flowchart of FIG. When the display control device 3 accepts that the pre-processing image 40A has been selected (YES in step S25), the display control unit 28 performs setting to transmit the pre-processing image 40A to the road display board 1 (step S26). .

  When the display control device 3 accepts that the processed image 40B has been selected by the input unit 52 (NO in step S25), the display control unit 28 sets to transmit the processed image 40B to the road display board 1. This is performed (step S27).

  After the process of step S26 or step S27 is executed, the process proceeds from “D” to step S11 of FIG. When step S26 is executed, the display control unit 28 performs control so that the set pre-processing image 40A is transmitted to the road display board 1. When step S27 is executed, the display control unit 28 performs control so that the set post-processing image 40B is transmitted to the road display board 1.

  As a result, each display element based on the selected image data 40 of the pre-processing image 40A or the post-processing image 40B is displayed on the LED display unit 2. When neither the pre-processing image 40A nor the post-processing image 40B is selected, the LED display unit 2 is not displayed.

  In the modified example, if YES in step S10, the display control unit 28 does not perform control to hide the LED display unit 2 at that time, but the display control device 3 displays options on the screen unit 51. . Thereby, the display control apparatus 3 can perform display control of each road display board 1 flexibly.

  The display of the pre-processing image 40A and the post-processing image 40B in step S22 may be performed not only in the case of YES in step S10 but also at an arbitrary timing. For example, in the case of NO in step S10, the pre-processing image 40A and the post-processing image 40B may be displayed on the screen unit 51.

<Example of hardware configuration of display control device>
Next, an example of the hardware configuration of the display control device 3 will be described with reference to the example of FIG. As shown in the example of FIG. 28, a processor 111, a random access memory (RAM) 112, a read only memory (ROM) 113, and an auxiliary storage device 114 are connected to the bus 100. Further, a medium connection unit 115, a communication interface 116, an input interface 117, and a display interface 118 are connected to the bus 100. In FIG. 28, the interface is described as “IF”.

  The processor 111 is an arbitrary processing circuit. The processor 111 executes a program expanded in the RAM 112. As a program to be executed, a program for performing the processing of the embodiment may be applied. The ROM 113 is a non-volatile storage device that stores programs developed in the RAM 112.

  The auxiliary storage device 114 is a storage device that stores various types of information. For example, a hard disk drive or a semiconductor memory may be applied to the auxiliary storage device 114. The medium connection unit 115 is provided so as to be connectable to the portable recording medium 119.

  The portable recording medium 119 may be a portable memory, an optical disc (for example, Compact Disc (CD) or Digital Versatile Disc (DVD)), a semiconductor memory, or the like. A program for performing the processing of the embodiment may be recorded on the portable recording medium 119.

  The communication interface 116 is an interface that performs communication. The input interface 117 is an interface connected to the keyboard 121. The display interface 118 is an interface connected to the display 122.

  In the display control device 3, the image data creation unit 22, the failure information acquisition unit 23, the failure information reflection unit 24, the calculation unit 25, the determination unit 26, and the display control unit 28 execute a program given by the processor 111. This may be realized.

  The second communication unit 21 may be realized by the communication interface 116. The storage unit 27 may be realized by the RAM 112 or the auxiliary storage device 114. The screen unit 51 may be realized by the display 122. The input unit 52 may be realized by the keyboard 121.

  The RAM 112, the ROM 113, the auxiliary storage device 114, and the portable recording medium 119 are all examples of a tangible storage medium that can be read by a computer. These tangible storage media are not temporary media such as signal carriers.

<Others>
The present embodiment is not limited to the above-described embodiment, and various configurations or embodiments can be taken without departing from the gist of the present embodiment.

DESCRIPTION OF SYMBOLS 1 Road display board 2 LED display part 3 Display control apparatus 4 Display control system 10 Road display board control part 12 LED control part 13 Fault LED detection part 22 Image data creation part 23 Fault information acquisition part 24 Fault information reflection part 25 Calculation part 26 Determination unit 27 Storage unit 28 Display control unit 40 Image data 51 Screen unit 52 Input unit 111 Processor 112 RAM
113 ROM

Claims (9)

A determination unit that determines whether there is a display element having a lighting rate of the display element assigned to the display element that is less than or equal to a threshold value among one or more display elements displayed on a display device including a plurality of display elements;
1 or so that the lighting rate of each display element included in the one or more display elements exceeds the threshold value when the determination unit determines that there is a display element whose lighting rate is equal to or less than the threshold value. A control unit for moving or reducing a plurality of display elements to display on the display device;
A display control apparatus comprising: The determination unit determines whether there is a display element having the lighting rate equal to or lower than the threshold based on a threshold set for each display element.
The display control apparatus according to claim 1. The determination unit determines, for each block, whether or not there is a display element whose lighting rate is equal to or lower than the threshold among one or a plurality of display elements included in a block in which a predetermined area for displaying the display element is divided.
The control unit moves or reduces one or a plurality of display elements in a block in which it is determined that there is a display element whose lighting rate is equal to or less than the threshold value, and causes the display device to display the display element.
The display control apparatus according to claim 1, wherein the display control apparatus is a display control apparatus. The determination unit determines, for each block, whether or not there is a display element whose lighting rate is equal to or lower than the threshold among one or a plurality of display elements included in a block in which a predetermined area for displaying the display element is divided.
The control unit moves or reduces a plurality of display elements in an area including a block in which the lighting rate is determined to be a display element equal to or less than the threshold and a block adjacent to the display element, to the display device. Display,
The display control apparatus according to claim 1, wherein the display control apparatus is a display control apparatus. An acquisition unit that acquires failure information that identifies a display element in which a failure occurs among the plurality of display elements from the display device;
One or a plurality of display elements to be displayed on the display device are allocated to a plurality of pixels included in image data in which each display element of the plurality of display elements is associated with one pixel, and the failure information A screen unit for displaying the first image data in which is reflected, and the second image data in which the movement or reduction is reflected on the first image data;
The display control apparatus according to claim 1, further comprising: When the selection of the first image data or the second image data is received, the control unit performs control to cause the display device to perform display based on the image data for which selection has been received,
When the selection of the first image data and the second image data is not accepted, the display device is controlled to be hidden.
The display control apparatus according to claim 5. A display device including a plurality of display elements;
A display control device that performs display control on the display device,
The display control device includes:
A determination unit that determines whether there is a display element having a lighting rate of the display element assigned to the display element that is less than or equal to a threshold value among the one or more display elements;
1 or so that the lighting rate of each display element included in the one or more display elements exceeds the threshold value when the determination unit determines that there is a display element whose lighting rate is equal to or less than the threshold value. A control unit for moving or reducing a plurality of display elements to display on the display device;
A display control system comprising: Of one or more display elements displayed on a display device including a plurality of display elements, determine whether there is a display element having a lighting rate of the display element assigned to the display element equal to or lower than a threshold value,
When it is determined that there is a display element whose lighting rate is equal to or less than the threshold value, one or more displays so that the lighting rate of each display element included in the one or more display elements exceeds the threshold value, respectively. Move or reduce elements to be displayed on the display device;
A display control method, wherein a computer executes processing. Of one or more display elements displayed on a display device including a plurality of display elements, determine whether there is a display element having a lighting rate of the display element assigned to the display element equal to or lower than a threshold value,
When it is determined that there is a display element whose lighting rate is equal to or less than the threshold value, one or more displays so that the lighting rate of each display element included in the one or more display elements exceeds the threshold value, respectively. Move or reduce elements to be displayed on the display device;
A display control program for causing a computer to execute processing.

Images