JP2011197582A - Display device, display control method, and display control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect an anomaly of a display element and to display information corresponding to original display content.SOLUTION: Lighting states of LEDs 24_1 to 24_n×m are detected by lighting detection parts 31_1 to 31_n×m to be compared with a display control signal D1a. A display device 11 determines a failure if there is one or more mismatches, and uses a signal, which is obtained by inverting a display control signal D1 from a lighting pattern control circuit 21 by a logical inversion part 33, as a display control signal D1a. Therefore, when a failure occurs in a LED 24, the display device 11 can simultaneously invert the lighting patterns of all dots and notify a user of the information equivalent to that before the failure.

Description

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

  2. Description of the Related Art Conventionally, a display device including a dot matrix display unit configured by one or a plurality of LEDs (Light Emitting Diodes), fluorescent tubes, and the like arranged in a matrix as display elements has been used. Such a display device represents numbers and characters by controlling the lighting pattern of the dot matrix display unit, and notifies the user of the internal operation mode and information.

  When a part of a display element of a display device, that is, a dot fails due to a lifetime or the like and does not light up, there is a case where a pattern originally intended to be deformed loses its shape and cannot be displayed correctly.

  If the shape of the pattern collapses due to a failure of the display element in this way, the information may not be transmitted correctly to the user, or depending on the lighting pattern after the failure, the user may have made a mistake based on incorrect information without noticing the failure. Occurs when performing an operation.

  As a technique for detecting an abnormality in a display device, a technique for detecting an abnormality by detecting an energization current of a light emitting diode is known. There is also known a technique for notifying an abnormality by displaying a character that cannot be normally displayed by a display device by inverting dots 1 and 0.

Japanese Patent No. 2995664 JP 52-048931 A

  However, when the display device abnormality is notified by the conventional technique, the user can recognize that the abnormality has occurred, but cannot know the content of the original display.

  That is, the conventional technique has a problem that the original information cannot be notified when an abnormality occurs in the display element.

  The disclosed technology has been made in view of the above, and includes a display device, a display control method, and a display control program capable of detecting an abnormality of a display element and displaying information corresponding to the original display content. The purpose is to provide.

  A display device, a display control method, and a display control program disclosed in the present application output a display control signal to a plurality of display elements arranged in a matrix in a display area to display a desired pattern, and the plurality of display elements The display state of is detected. Then, the disclosed apparatus, method, and program compare the display control signal with the display state, and switch the display control signal to a signal for displaying an alternative pattern if they do not match.

  According to the display device, the display control method, and the display control program disclosed in the present application, the display device, the display control method, and the display control capable of detecting an abnormality of the display element and displaying information corresponding to the original display content. There is an effect that a program can be obtained.

FIG. 1 is a configuration diagram of a display device 11 according to the first embodiment. FIG. 2 is a configuration diagram of a display device 10 as a comparative example. FIG. 3 is an explanatory diagram of the display when a failure occurs in the LED. FIG. 4 is an explanatory diagram for inversion of the display pattern. FIG. 5 is an explanatory diagram of the state of the display device 11 in a normal state. FIG. 6 is an explanatory diagram of the state of the display device 11 when a failure occurs in the LED. FIG. 7 is a flowchart for explaining the processing operation of the display device 11. FIG. 8 is a configuration diagram of the display device 12 according to the second embodiment. FIG. 9 is an explanatory diagram of a specific example of an alternative pattern. FIG. 10 is an explanatory diagram of the state of the display device 12 in a normal state. FIG. 11 is an explanatory diagram of a state of the display device 12 when a failure occurs in the LED. FIG. 12 is a flowchart for explaining the processing operation of the display device 12. FIG. 13 is an explanatory diagram of a specific example of an alternative pattern. (Part 1) FIG. 14 is an explanatory diagram of a specific example of an alternative pattern. (Part 2) FIG. 15 is an explanatory diagram of a specific example of ROM data.

  Hereinafter, a display device, a display control method, and a display control program disclosed in the present application will be described in detail with reference to the drawings. The present invention is not limited to the following specific examples.

[Device configuration]
FIG. 1 is a configuration diagram of a display device 11 according to the first embodiment. FIG. 2 is a configuration diagram of a display device 10 as a comparative example. The display device 10 shown in FIG. 2 has a dot matrix display unit in which LEDs are arranged in an n × m matrix. The n × m LEDs 24 (LEDs 24_1 to 24_n × m) are connected to the line of the voltage Vcc via the corresponding resistors 25 (resistors 25_1 to 25_n × m), respectively.

  The LEDs 24_1 to 24_n × m are connected to the LED lighting pattern control circuit 21 via the LED driving driver 23. The LED lighting pattern control circuit 21 includes a display content processing unit 22 inside. The display content processing unit 22 determines a pattern to be displayed on the dot matrix display unit by outputting a signal indicating whether or not each of the n × m LEDs 24 is lit, and displays a desired pattern such as a character or a number. Can be displayed. The n × m signals output from the display content control unit 22 are display control signals D1.

  In the display device 10 shown in FIG. 2, the display control signal D <b> 1 is input to the LED driving driver 23. The LED driver 23 creates a drive signal D2 from the display control signal D1 and inputs the drive signal D2 to the LEDs 24_1 to 24_n × m. Specifically, the LED driving driver 23 amplifies a signal instructing to turn on the LED instructed to turn on by the display control signal D1, thereby obtaining an output necessary for turning on the LED.

  For this reason, among the LEDs 24_1 to 24_n × m, the LED instructed to be turned on by the display control signal D1 is turned on, and the other LEDs are not turned on. Therefore, the dot matrix display unit by the LEDs 24_1 to 24_n × m can display the pattern as specified by the display content processing unit 22.

  The display device 11 according to the first embodiment shown in FIG. 1 has an LED lighting pattern control circuit 21, an LED driving driver 23, LEDs 24_1 to 24_n × m, resistors 25_1 to 25_n × m, similarly to the display device 10 having a comparative configuration. Have

  In addition, the display device 11 includes a lighting detection unit 31 (31_1 to 31_n × m), a selector 32 (32_1 to 32_n × m), a logic inversion unit 33 (33_1 to 33_n × m), and a failure determination unit 41.

  The lighting detection units 31_1 to 31_n × m correspond to the LEDs 24_1 to 24_n × m, respectively, and are provided between the LED driving driver 23 and the LEDs 24_1 to 24_n × m. The lighting detection units 31_1 to 31_n × m detect the lighting state of the corresponding LED and output the detected lighting state to the failure determination unit 41. An output from the lighting detection units 31_1 to 31_n × m is a display state signal D3.

  As a means for detecting lighting by the lighting detectors 31_1 to 31_n × m, there is a method of detecting the current flowing through the LED by converting it into a voltage using a transistor or a field effect transistor (FET). There are also a method of directly detecting the lighting state by a photodiode prepared for each LED and a method of detecting the current of the light emitting diode based on the output voltage of the current transformer.

  The logic inversion units 33_1 to 33_n × m invert and output n × m signals of the display control signal D1. Each of the selectors 32_1 to 32_n × m outputs the value of the display control signal D1 as it is for each of the n × m signals of the display control signal D1, or outputs a signal inverted by the logic inversion units 33_1 to 33_n × m. It is a switching part which switches whether to do. The output of the selectors 32_1 to 32_n × m is the display control signal D1a.

  The selectors 32_1 to 32_n × m are switched simultaneously by a selector control signal D4 from the failure determination unit 41. Therefore, the display control signal D1a is the same as the display control signal D1 or a signal obtained by inverting all the signals of the display control signal D1.

  The failure determination unit 41 is a determination unit that compares the display control signal D1a and the display state signal D3 to determine whether or not they match. The failure determination unit 41 outputs a selector control signal D4 when the display control signal D1a and the display state signal D3 do not match as a result of the determination, and switches the selectors 32_1 to 32_n × m.

  The LED driving driver 23 drives the LED in the display device 11 based on the display control signal D1a. Therefore, when the selectors 32_1 to 32_n × m are switched, the instructions for turning on and off the LEDs 24_1 to 24_n × m are all reversed. As a result, the display pattern of the dot matrix display unit is also inverted.

[Specific examples of display]
The occurrence of a failure in the LED and the inversion of the display pattern will be described with reference to FIGS. FIG. 3 is an explanatory diagram of the display when a failure occurs in the LED. FIG. 4 is an explanatory diagram for inversion of the display pattern.

  As shown in FIG. 3, when a single LED fails in a pattern that displays the shape of “B” in a normal state, it is difficult to determine whether or not a failure has occurred. For this reason, there is a possibility that the user does not suspect a failure, and there is a possibility that the user will recognize “8”.

  Further, as shown in FIG. 3, when the LED in the three places fails in the pattern displaying the shape of “B” in the normal state, the occurrence of the failure cannot be recognized from the displayed pattern, and “8” is displayed. It is recognized.

  Here, when the display pattern is reversed as shown in FIG. 4, the shape of “B” can be displayed even if the same position as that shown in FIG. This is because the LED that should have been turned on in the original display pattern becomes the LED that should be turned off. In other words, by inverting the display pattern, information corresponding to the original display content can be displayed. In this way, a pattern that is different in display mode but shows the same content as the original display pattern is referred to as an equivalent pattern.

  Further, by reversing the display, it is possible to notify the user that a failure has occurred in the LED.

[Example of operation]
FIG. 5 is an explanatory diagram of the state of the display device 11 in a normal state. As shown in FIG. 5, if all the LEDs can be normally lit, the display control signal D1 output from the display content processing unit 22 is directly selected by the selectors 32_1 to 32_n × m. As a result, the same display control signal D1a as the display control signal D1 is output to the LED driver 23.

  FIG. 6 is an explanatory diagram of the state of the display device 11 when a failure occurs in the LED. When the failure determination unit 41 detects that the LED that should have been normally lit when it is normal is not lit, the failure determination unit 41 selects the selector control signal for switching the selectors 32_1 to 32_n × m as shown in FIG. D4 is output.

  Upon receiving the selector control signal D4, the selectors 32_1 to 32_n × m simultaneously select the logic inversion units 33_1 to 33_n × m to invert the lighting / extinguishing states of the LED lighting patterns all at once.

  Further, the failure determination unit 41 waits for a predetermined time, and when it again detects a mismatch between the display control signal D1a and the display state signal D3, the failure determination unit 41 determines that the display cannot be performed correctly using the reverse display and ends the processing. To do. The predetermined time for waiting is a time determined based on a required time from the output of the display control signal D1 until the lighting state of the LEDs 24_1 to 24_n × m is stabilized.

[Description of processing operation]
FIG. 7 is a flowchart for explaining the processing operation of the display device 11. The processing operation illustrated in FIG. 7 starts when the display content processing unit 22 starts outputting the display control signal D1. Moreover, when the display control signal D1 output from the display content processing unit 22 is changed, that is, when the pattern to be displayed is changed, the processing is started again. This is because some types of numbers and characters may be displayed correctly. Further, the selectors 32_1 to 32_n × m select the display control signal D1 as the initial setting of the flow start.

  As shown in FIG. 7, the failure determination unit 41 first waits for a predetermined time (S101), and whether the display control signal D1a and the display state signal D3, that is, the LED lighting signal and the LED lighting state match. Is determined (S102).

  If the display control signal D1a and the display state signal D3 match (S102, Yes), the failure determination unit 41 returns to step S101. On the other hand, if the display control signal D1a and the display state signal D3 do not match (S102, No), the failure determination unit 41 outputs a selector control signal D4 as an inversion selection signal output for selecting an inversion pattern (S103).

  After outputting the selector control signal D4, the failure determination unit 41 waits for a predetermined time (S104), and determines whether the display control signal D1a and the display state signal D3, that is, the LED lighting signal and the LED lighting state match. Determination is made (S105).

  If the display control signal D1a matches the display state signal D3 (S105, Yes), the failure determination unit 41 returns to step S104. On the other hand, if the display control signal D1a and the display state signal D3 do not match (S105, No), a failure occurrence process is performed (S106), and the process ends. Specifically, the failure occurrence processing includes turning off the LEDs 24_1 to 24_n × m, outputting to notify the occurrence of the failure, and the like.

  As described above, in the display device 11 according to the first embodiment, the lighting states of the LEDs 24_1 to 24_n × m are detected by the lighting detection units 31_1 to 31_n × m and compared with the display control signal D1a. The display device 11 determines that there is a failure when even one mismatch exists, and uses the display control signal D1a obtained by inverting the display control signal D1 from the lighting pattern control circuit 21 by the logic inversion units 33_1 to 33_n × m.

  For this reason, when the failure occurs in the LEDs 24_1 to 24_n × m, the display device 11 can reverse the lighting pattern of all the dots all at once and notify the user of information equivalent to that before the failure. Recognition and erroneous operations derived from erroneous recognition can be prevented. Moreover, the display apparatus 11 can make a user recognize that there exists a failure in a part of light emitting element by making a lighting pattern different from a normal state.

  In the first embodiment, the case where LEDs are arranged in a matrix has been described as an example. However, display control signals are output to a plurality of display elements such as fluorescent tubes, liquid crystal elements, and elements for electronic paper. Thus, the present invention can be applied to any display device that displays a desired pattern.

  In the first embodiment, the configuration in which the signal is inverted by the logic inversion unit 33 has been described. However, for example, when the display control signal does not match the display state in the LED lighting pattern control circuit 21, the display control signal is displayed. It is also possible to execute a program for switching to a reverse pattern.

[Device configuration]
FIG. 8 is a configuration diagram of the display device 12 according to the second embodiment. The display device 12 illustrated in FIG. 8 includes the LED lighting pattern control circuit 21, the LED driving driver 23, the LEDs 24_1 to 24_n × m, and the resistors 25_1 to 25_n × m, similarly to the display device 10 having the comparative configuration illustrated in FIG. Have.

  In addition, the display device 12 includes lighting detection units 31_1 to 31_n × m, selectors 32_1 to 32_n × m, a failure determination unit 42, a ROM (Read Only Memory) address generation unit 43, and a lighting pattern generation ROM 44.

  The lighting detection units 31_1 to 31_n × m correspond to the LEDs 24_1 to 24_n × m, respectively, and are provided between the LED driving driver 23 and the LEDs 24_1 to 24_n × m. The lighting detection units 31 </ b> _ <b> 1 to 31 </ b> _n × m detect the lighting state of the corresponding LED and output it to the failure determination unit 42. An output from the lighting detection units 31_1 to 31_n × m is a display state signal D3.

  The selectors 32_1 to 32_n × m output the value of the display control signal D1 as it is for each of the n × m signals of the display control signal D1, or output the alternative pattern signal D7 output from the lighting pattern generation ROM 44. It is a switching unit for switching between. The output of the selectors 32_1 to 32_n × m is the display control signal D1a.

  The selectors 32_1 to 32_n × m are switched simultaneously by a selector control signal D4 from the failure determination unit 42. Therefore, the display control signal D1a is the same as the display control signal D1 or the same as the alternative pattern signal D7.

  The failure determination unit 42 is a determination unit that compares the display control signal D1a and the display state signal D3 to determine whether or not they match. The failure determination unit 42 outputs a selector control signal D4 when the display control signal D1a and the display state signal D3 do not match as a result of the determination, and switches between the display control signal D1 and the alternative pattern signal D7. Further, the failure determination unit 42 outputs a mismatch notification signal D5 to the ROM address generation unit 43 when the display control signal D1a and the display state signal D3 do not match.

  The ROM address generation unit 43 outputs a ROM address signal D6 that specifies the address of the lighting pattern generation ROM 44 when the failure determination unit 42 outputs the mismatch notification signal D5.

  The lighting pattern generation ROM 44 is a holding unit that holds a substitute pattern corresponding to each pattern displayed on the dot matrix display unit by the display content processing unit 22. The alternative pattern is an equivalent pattern that shows the same content although the display mode is different from the display pattern instructed by the display content processing unit 22.

  The lighting pattern generation ROM 44 holds a plurality of alternative patterns corresponding to each display pattern instructed by the display content processing unit 22 with priority.

  The alternative pattern held by the lighting pattern generation ROM 44 is uniquely determined by the ROM address signal D6 specified by the ROM address generation unit 43. The lighting pattern generation ROM 44 outputs a signal indicating whether or not each of the n × m LEDs 24 is lit in order to display the substitute pattern determined by the ROM address signal D6 on the dot matrix display unit. The n × m signals output from the lighting pattern generation ROM 44 are substitute pattern signals D7.

  When the n × m signals output from the display content control unit 22 acquire the display control signal D1 and receive the mismatch notification signal D5, the ROM address generation unit 43 reads the ROM address corresponding to the display control signal D1. The signal D6 is output. Therefore, the ROM address generation unit 43 can specify an equivalent alternative pattern corresponding to the display pattern indicated by the display control signal D1.

  In addition, after displaying the alternative pattern, the ROM address generator 43 further outputs a ROM address signal D6 for designating another equivalent alternative pattern according to the priority order of the alternative pattern when receiving the mismatch notification signal D5. To do.

  The LED driving driver 23 drives the LED in the display device 12 based on the display control signal D1a. Therefore, when the selectors 32_1 to 32_n × m are switched, the on / off instructions for the LEDs 24_1 to 24_n × m are the same as the alternative pattern signal D7, and the alternative pattern is displayed on the dot matrix display portion.

[Specific examples of display]
FIG. 9 is an explanatory diagram of a specific example of an alternative pattern. As shown in FIG. 9, even when a failure occurs in units of rows or columns in the dot matrix display portion in a pattern that displays the shape of “B” in a normal state, it is equivalent by displaying an alternative pattern. Information can be output. In FIG. 9, although the bottom three rows are out of order, only normal dots are used, and a pattern “B” that is smaller than the original shape is output.

  In this way, by using the alternative pattern, it is possible to increase the number of cases where an equivalent pattern can be displayed and the failure can be remedied. In addition, by changing the display mode, it is possible to notify the user that a failure has occurred in the LED.

[Example of operation]
FIG. 10 is an explanatory diagram of the state of the display device 12 in a normal state. As shown in FIG. 10, if all the LEDs can be lit normally, the display control signal D1 output from the display content processing unit 22 is selected as it is by the selectors 32_1 to 32_n × m. As a result, the same display control signal D1a as the display control signal D1 is output to the LED driver 23.

  FIG. 11 is an explanatory diagram of a state of the display device 12 when a failure occurs in the LED. When the failure determination unit 41 detects that the LED that should be normally lit when not operating is not lit, the failure determination unit 42 selects the selector control signal for switching the selectors 32_1 to 32_n × m as shown in FIG. D4 is output.

  In addition, the failure determination unit 42 outputs a mismatch notification signal D5 to the ROM address generation unit 43. The ROM address generation unit 43 generates a ROM address signal D6 based on the mismatch notification signal D5 and the display control signal D1, and the lighting pattern generation ROM 44 outputs an alternative pattern signal D7 based on the ROM address signal D6.

  Upon receiving the selector control signal D4, the selectors 32_1 to 32_n × m simultaneously select the alternative pattern signal D7 side and switch the lighting / lighting-off state of the LED lighting pattern.

  Furthermore, after waiting for a predetermined time, the failure determination unit 42 outputs a mismatch notification signal D5 and changes the alternative pattern when it again detects a mismatch between the display control signal D1a and the display state signal D3. The predetermined time for waiting is a time determined based on a required time from the output of the display control signal D1 until the lighting state of the LEDs 24_1 to 24_n × m is stabilized.

[Description of processing operation]
FIG. 12 is a flowchart for explaining the processing operation of the display device 12. The processing operation illustrated in FIG. 12 starts when the display content processing unit 22 starts outputting the display control signal D1. Moreover, when the display control signal D1 output from the display content processing unit 22 is changed, that is, when the pattern to be displayed is changed, the processing is started again. This is because some types of numbers and characters may be displayed correctly. Further, the selectors 32_1 to 32_n × m select the display control signal D1 as the initial setting of the flow start.

  As shown in FIG. 12, the failure determination unit 42 first waits for a predetermined time (S201), and whether the display control signal D1a and the display state signal D3, that is, the LED lighting signal and the LED lighting state match. Is determined (S202).

  If the display control signal D1a and the display state signal D3 match (S202, Yes), the failure determination unit 42 returns to step S201. On the other hand, if the display control signal D1a and the display state signal D3 do not match (S202, No), the failure determination unit 42 outputs a selector control signal D4 as a ROM selection signal output for selecting an alternative pattern output from the lighting pattern generation ROM 44. Is output (S203).

  Further, the failure determination unit 42 outputs a mismatch notification signal D5 to the ROM address generation unit 43 when the display control signal D1a and the display state signal D3 do not match. The ROM address generation unit 43 receives the mismatch notification signal D5 and sends the ROM address signal D6 for selecting the first, that is, the highest priority alternative pattern corresponding to the display control signal D1, to the lighting pattern generation ROM 44.

  The lighting pattern generation ROM 44 outputs an alternative pattern signal D7 based on the ROM address signal D6. The selector 32 selects this alternative pattern signal D7, thereby selecting the first alternative pattern (S204).

  Further, the failure determination unit 42 waits for a predetermined time (S205), and determines whether the display control signal D1a and the display state signal D3, that is, the LED lighting signal and the LED lighting state match (S206).

  If the display control signal D1a matches the display state signal D3 (S206, Yes), the failure determination unit 42 returns to step S205. On the other hand, when the display control signal D1a and the display state signal D3 do not match (S206, No), the failure processing determination unit 42 outputs a mismatch notification signal D5. The ROM address generation unit 43 receives the mismatch notification signal D5a and determines whether or not an unselected alternative pattern remains (S207).

  When the unselected alternative pattern remains (S207, Yes), the ROM address generation unit 43 selects the next alternative pattern according to the priority (S208), and returns to Step S205. Then, when there are no unselected alternative patterns (S207, No), that is, when the disagreement between the display control signal D1a and the display state signal D3 is not eliminated even if all the alternative patterns are used, the failure occurrence processing is performed. (S209), and the process ends. Specifically, the failure occurrence processing includes turning off the LEDs 24_1 to 24_n × m, outputting to notify the occurrence of the failure, and the like.

[Specific examples of alternative patterns]
13 and 14 are explanatory diagrams of specific examples of alternative patterns. 13 and 14 show normal display patterns and 13 alternative patterns for 16 types of patterns 0 to 9 and A to F, respectively.

  As shown in FIG. 13, the first of the alternative patterns is a pattern obtained by inverting the normal display pattern. The second alternative pattern is a pattern in which the normal display pattern is reduced and arranged at the upper left. The third alternative pattern is a pattern in which the normal display pattern is reduced and arranged at the left center.

  The fourth alternative pattern is a pattern in which the normal display pattern is reduced and arranged at the lower left. The fifth alternative pattern is a pattern in which the normal display pattern is reduced and arranged at the lower right. The sixth alternative pattern is a pattern in which a normal display pattern is reduced and arranged at the right center.

  As shown in FIG. 14, the seventh alternative pattern is a pattern in which the normal display pattern is reduced and arranged on the upper right. The eighth alternative pattern is a pattern arranged in the upper left after inverting the normal display pattern and then reducing it. The ninth alternative pattern is a pattern arranged in the center of the left side after reducing the normal display pattern and then reducing it.

  The tenth alternative pattern is a pattern that is reversed and reduced in the normal display pattern and arranged at the lower left. The eleventh alternative pattern is a pattern arranged in the lower right after reducing the normal display pattern and then reducing it. The twelfth alternative pattern is a pattern arranged in the right center by reducing the normal display pattern and then reducing it. The thirteenth alternative pattern is a pattern arranged in the upper right by inverting the normal display pattern and then reducing it.

  FIG. 15 is an explanatory diagram of a specific example of ROM data. In the example shown in FIG. 15, the ROM address is represented by two hexadecimal digits, the first digit is assigned to a number or character type, and the second digit is assigned to a substitute pattern number. The number of the alternative pattern is used as it is as the priority order. The data portion of the ROM has a data size corresponding to n × m bits and stores an alternative pattern.

  Specifically, ROM addresses 00 to 0C correspond to the first to thirteenth alternative patterns for pattern “0”. The ROM addresses 0D to 0F are unused, and the ROM addresses 10 to 1C are associated with the first to thirteenth alternative patterns for the pattern “1”. Similarly, the ROM addresses 1D to 1F are unused, and the ROM addresses 20 to 2C are associated with the first to thirteenth alternative patterns for the pattern “2”.

  In this way, the alternative patterns are sequentially stored, and in the example of FIG. 15, the ROM addresses F0 to FC are associated with the first to thirteenth alternative patterns for the pattern “F”. Note that FIG. 15 is merely an example, and the address assignment method can be changed as appropriate according to the number and type of necessary characters and the number of alternative patterns.

  As described above, in the display device 12 according to the second embodiment, the lighting states of the LEDs 24_1 to 24_n × m are detected by the lighting detection units 31_1 to 31_n × m and compared with the display control signal D1a. The display device 12 determines that there is a failure when even one mismatch exists, and switches the selector 32 to display the alternative pattern.

  Therefore, when a failure occurs in the LEDs 24_1 to 24_n × m, the display device 12 can notify the user of information equivalent to that before the failure by using an alternative pattern, and erroneous recognition and erroneous operation derived from erroneous recognition. Can be prevented. Moreover, the display apparatus 12 can make a user recognize that there exists a failure in a part of light emitting element by making a lighting pattern different from a normal state.

  In addition, by preparing a plurality of equivalent alternative patterns and sequentially using them, it is possible to increase the probability that equivalent information can be provided to the user by the alternative patterns when a failure occurs.

  In the second embodiment, the case where LEDs are arranged in a matrix is described as an example. However, display control signals are output to a plurality of display elements such as fluorescent tubes, liquid crystal elements, and elements for electronic paper. Thus, the present invention can be applied to any display device that displays a desired pattern.

  In the second embodiment, a description has been given of an example in which a substitute pattern is stored in advance. However, for example, a substitute pattern may be appropriately created from vector font data and failure location data.

  In the second embodiment, the configuration in which the substitute pattern is read from the lighting pattern generation ROM 43 has been described. However, for example, when the display control signal and the display state do not match in the LED lighting pattern control circuit 21, the substitute pattern is used. It is good also as executing the program to switch.

  The following supplementary notes are further disclosed with respect to the embodiments including the above examples.

(Supplementary note 1) a display area in which a plurality of display elements are arranged in a matrix;
A display content processing unit that outputs a display control signal to the plurality of display elements to display a desired pattern in the display area;
A detection unit for detecting a display state of the plurality of display elements;
A determination unit for comparing the display control signal and the display state to determine whether or not they match,
A display device, comprising: a switching unit that switches the display control signal to an alternative pattern display signal when the display control signal and the display state do not match as a result of the determination by the determination unit.

(Additional remark 2) It further has a signal inversion part which inverts the display control signal and creates the signal for the alternative pattern display, and the switching part switches between a display control signal and an output of the signal inversion part. The display device according to appendix 1, which is characterized.

(Additional remark 3) It further has the holding | maintenance part which hold | maintains the alternative pattern corresponding to every pattern displayed on the said display area, The said switching part is said holding | maintenance based on the pattern shown by the said display control signal and the said display control signal The display device according to appendix 1, wherein the signal for switching is displayed to switch the substitute pattern display signal output by the unit.

(Additional remark 4) When the said holding | maintenance part hold | maintains the some alternative pattern corresponding to every pattern displayed on the said display area with priority, the output signal for alternative pattern display and the said display state are inconsistent The display device according to claim 3, wherein the substitute pattern is changed based on the priority.

(Supplementary note 5) The display according to any one of supplementary notes 1 to 4, wherein the substitute pattern displayed by the substitute pattern display signal is equivalent to the pattern displayed by the display control signal. apparatus.

(Supplementary note 6) The supplementary note 5 is characterized in that an error is output when a pattern equivalent to the pattern indicated by the display control signal cannot be displayed by the output of the substitute pattern display signal. Display device.

(Supplementary note 7) The display device according to any one of supplementary notes 1 to 6, wherein each of the plurality of display elements is a light emitting element, and the display control signal is a signal for causing the light emitting element to emit light. .

(Supplementary Note 8) A step of outputting a display control signal to a plurality of display elements arranged in a matrix in the display area to display a desired pattern in the display area;
Detecting a display state of the plurality of display elements;
Comparing the display control signal and the display state to determine whether they match,
And a step of switching the display control signal to a substitute pattern display signal when the display control signal and the display state do not match as a result of the determination.

(Supplementary Note 9) A procedure for outputting a display control signal to a plurality of display elements arranged in a matrix in the display area to display a desired pattern in the display area;
Detecting a display state of the plurality of display elements;
A procedure for comparing the display control signal and the display state to determine whether they match,
A display control program that causes a computer to execute a procedure of switching the display control signal to a signal for displaying an alternative pattern when the display control signal and the display state do not match as a result of the determination.

10 to 12 Display device 21 LED lighting pattern control circuit 22 Display content processing unit 23 LED driver 24 (24_1 to 24_n × m) LED
25 (25_1 to 25_n × m) Resistor 31 (31_1 to 31_n × m) Lighting detection unit 32 (32_1 to 32_n × m) Selector 33 (33_1 to 33_n × m) Logic inversion unit 41 to 42 Fault determination unit 43 ROM address generation Part 44 Lighting pattern generation ROM
D1, D1a Display control signal D2 Drive signal D3 Display status signal D4 Selector control signal D5 Mismatch notification signal D6 ROM address signal D7 Substitute pattern signal

Claims (7)

A display area in which a plurality of display elements are arranged in a matrix;
A display content processing unit that outputs a display control signal to the plurality of display elements to display a desired pattern in the display area;
A detection unit for detecting a display state of the plurality of display elements;
A determination unit for comparing the display control signal and the display state to determine whether or not they match,
A display device, comprising: a switching unit that switches the display control signal to an alternative pattern display signal when the display control signal and the display state do not match as a result of the determination by the determination unit.   A signal inversion unit that inverts the display control signal to generate the substitute pattern display signal, and the switching unit switches between a display control signal and an output of the signal inversion unit. Item 4. The display device according to Item 1.   The image processing apparatus further includes a holding unit that holds a substitute pattern corresponding to each pattern displayed in the display area, and the switching unit outputs the display control signal and the pattern indicated by the display control signal. The display device according to claim 1, wherein a signal for displaying an alternative pattern is switched.   The holding unit holds a plurality of alternative patterns corresponding to each pattern to be displayed in the display area with priority, and the priority order is displayed when the output signal of the alternative pattern display and the display state do not match. The display device according to claim 3, wherein the alternative pattern is changed based on the display.   The display device according to claim 1, wherein the substitute pattern displayed by the substitute pattern display signal is equivalent to the pattern displayed by the display control signal. Outputting a display control signal to a plurality of display elements arranged in a matrix in the display area to display a desired pattern in the display area;
Detecting a display state of the plurality of display elements;
Comparing the display control signal and the display state to determine whether they match,
And a step of switching the display control signal to a substitute pattern display signal when the display control signal and the display state do not match as a result of the determination. A procedure for outputting a display control signal to a plurality of display elements arranged in a matrix in the display area to display a desired pattern in the display area;
Detecting a display state of the plurality of display elements;
A procedure for comparing the display control signal and the display state to determine whether they match,
A display control program that causes a computer to execute a procedure of switching the display control signal to a signal for displaying an alternative pattern when the display control signal and the display state do not match as a result of the determination.

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