JP2009276465A - Display device and inspection method for light source of the display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device having a liquid crystal panel and a plurality of light sources irradiating the liquid crystal panel through the back face side, in which a damaged light source can be easily inspected. <P>SOLUTION: The liquid crystal display device 1 having a liquid crystal panel 2 and a plurality of light sources 3 for irradiating the liquid crystal panel 2 through the back face side of the liquid crystal panel 2 is configured to carry out a lighting control for the light sources, by sequentially applying an electric power to each of the plurality of light sources 3 from a lighting power supply; and display control of the liquid crystal panel, by synchronously displaying an image to the application of the electric power in an irradiated area of the liquid crystal panel 2, to which one light source 2 opposes and irradiates the panel with light. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a liquid crystal panel, a display device including a plurality of light sources that irradiate the liquid crystal panel from the back side, and a light source inspection method for the display device.

  A display device using a liquid crystal panel needs a backlight that irradiates the liquid crystal panel from the back side. Conventionally, a fluorescent tube such as a cold cathode tube or a hot cathode tube has been used as the backlight. As a power source applied to the backlight composed of this fluorescent tube, a lighting-only power source composed of an inverter or the like is generally used.

  In addition, in a display device using these liquid crystal panels, when a small liquid crystal panel is used, there may be one fluorescent tube used as a backlight, but when a medium-sized or larger liquid crystal panel is used. A plurality of fluorescent tubes are used.

  In the display device using the plurality of fluorescent tubes, if the fluorescent tube stops lighting due to a failure or a lifetime, even if it is one of the plurality of fluorescent tubes, the remaining fluorescent tubes In order to prevent the failure of other fluorescent tubes and the power supply dedicated to lighting or the occurrence of fire due to overload, the control of turning off all the fluorescent tubes and turning off the entire backlight is adopted (for example, , See Patent Document 1).

Patent Document 1 relates to a backlight assembly, and can detect a failure of a light source that generates light for displaying an image in real time. In the backlight assembly described in Patent Document 1, a sensor that outputs a sensing signal corresponding to the intensity of an electromagnetic field is used to detect a failure of a light source.
JP 2005-129508 A

  By the way, the backlight as described above is not configured such that a plurality of fluorescent tubes constituting the backlight can be individually turned on and off individually. Finding which of the lights did not light up was a laborious task.

  For this reason, in a display device using a liquid crystal panel, a maintenance method has been adopted in which the entire backlight is removed and replaced when the fluorescent tube stops lighting due to a failure or a lifetime.

  Such a maintenance method increases the cost, and in order to replace a fluorescent tube that has stopped lighting in a failed backlight, it is necessary to find which of the plurality of fluorescent tubes does not light up. It took time and effort.

  In particular, the size of display devices using liquid crystal panels has been increasing recently. In these large display devices, the maintenance method as described above is compared with the case of small and medium display devices. The cost and other disadvantages increase.

  Therefore, the present invention has been made to solve such a situation, and has failed in a display device including a liquid crystal panel and a plurality of light sources that irradiate the liquid crystal panel from the back side. A display device capable of easily inspecting a light source and a light source inspection method for the display device are provided.

  The display device of the present invention is a display device including a liquid crystal panel and a plurality of light sources serving as the backlight that irradiates the liquid crystal panel from the back side of the liquid crystal panel. In this display device, a single light source faces and irradiates a plurality of light sources by a light source lighting control for sequentially applying power from a lighting power source for each light source and the light source lighting control. Liquid crystal panel display control for performing display in synchronization with the application of the electric power is performed on the irradiation area of the liquid crystal panel.

  In the above display device, the light source lighting control and the liquid crystal panel display control are performed so that the presence or absence of lighting of the light source provided on the back side of the liquid crystal panel can be visually observed from the front side of the liquid crystal panel. Therefore, these control conditions generally include at least the following two points.

  The first condition is that, in the light source lighting control, the time width during which the power from the power source for lighting performed for each light source is applied is set to a time width in which the presence or absence of lighting of the light source can be sufficiently observed. is there.

  The second condition is that the display control of the liquid crystal panel with respect to the irradiation area, which is the area of the liquid crystal panel that is arranged to face and irradiate the light source, is one piece arranged on the back side of the irradiation area. During the period when the light source is on, display control is performed so that at least a part of the light from the light source passes through the irradiation area.

  According to the above display device, the power from the lighting power source is sequentially applied to the plurality of light sources one by one, and at the irradiation area of the liquid crystal panel that the one light source faces and irradiates. The display is performed in synchronization with the application of power from the lighting power source. Therefore, the presence or absence of lighting of the light source can be visually observed from the front side of the liquid crystal panel during the application period of power from the lighting power source. Therefore, a failed light source can be easily detected.

  In the above display device, information indicating the position of the light source may be displayed as the display performed by the liquid crystal panel display control.

  By doing so, it is possible to surely check whether or not the light source is turned on from the front side of the liquid crystal panel, and easily know which of the plurality of light sources is performing the visual inspection. be able to. Therefore, a failed light source can be easily detected.

  Alternatively, in the above display device, as the display performed by the above liquid crystal panel display control, the light emitted from the light source may be transmitted through the liquid crystal panel. Examples of the display in which the light emitted from the light source is transmitted through the liquid crystal panel include a white display and a light blue display.

  By doing so, it is possible to surely check whether or not the light source is turned on from the front side of the liquid crystal panel, and easily know which of the plurality of light sources is performing the visual inspection. be able to. Therefore, a failed light source can be easily detected.

  Moreover, you may make it use a hot cathode tube for the light source of each said display apparatus. A display device using a cold cathode tube is generally difficult to increase in size, whereas a display device using a hot cathode tube can be increased in size. Therefore, even for a large display device using a hot cathode tube, a failed light source can be easily inspected, and the enlargement of the display device can be promoted.

  The light source inspection method for a display device according to the present invention is a light source inspection method for a display device including a liquid crystal panel and a plurality of light sources that irradiate the liquid crystal panel from the back side of the liquid crystal panel. In this light source inspection method for a display device, light source lighting control for sequentially applying power from a lighting power source to a plurality of light sources is sequentially performed for each light source, and one light source is controlled by the light source lighting control. The liquid crystal panel display control for performing display in synchronization with the application of the electric power is performed on the irradiation area of the liquid crystal panel that faces and irradiates.

  In the above-described light source inspection method for the display device, as the display performed by the liquid crystal panel display control, information indicating the position of the light source may be displayed, or the light emitted from the light source is transmitted through the liquid crystal panel. You may make it do. Examples of the display in which the light emitted from the light source is transmitted through the liquid crystal panel include a white display and a light blue display.

  The above-described light source inspection method for each display device has the same functions and effects as those described in the description of the display device described above.

  According to the present invention, the power from the lighting power source is sequentially applied to the plurality of light sources one by one, and the illumination is performed on the irradiation area of the liquid crystal panel on which one light source faces and illuminates. Display is performed in synchronization with the application of power from the power supply. Therefore, the presence or absence of lighting of the light source can be visually observed from the front side of the liquid crystal panel during the application period of power from the lighting power source. Therefore, a failed light source can be easily detected.

  Next, a display device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an exploded perspective view showing a structure of a display device 1 in the present embodiment, and FIG. 2 is a cross-sectional view. 1 and 2, the display device 1 according to the present embodiment has a configuration in which a liquid crystal panel 2, a fluorescent tube 3, a lens sheet 4, a diffusion plate sheet 5, and a reflection sheet 6 are sequentially stacked from the front to the rear. Has been.

  Among these, 24 hot cathode tubes (HCFL) are used as the fluorescent tubes 3, and these fluorescent tubes 3 correspond to a plurality of light sources serving as the backlight described above. These fluorescent tubes 3 are arranged in parallel with each other in the longitudinal direction of the display device 1 so that both ends thereof are attached to the fluorescent tube mounting pieces. The portion excluding the surface of the liquid crystal panel 2 is covered with the chassis 10.

  The 24 fluorescent tubes 3 are referred to as a first fluorescent tube, a second fluorescent tube, a second fluorescent tube,..., A 24th fluorescent tube in order from the top.

  FIG. 3 is a block diagram illustrating a configuration of a control unit that controls the display device 1. In FIG. 3, the control unit of the display device 1 includes a main control unit 11, a three-digit decimal switch 12, a memory 13, an image input terminal 14, a lighting control unit 15, an image control unit 16, a lighting circuit 17, and a preheating. The circuit 18 is configured.

  The main control unit 11 is composed of a microprocessor and controls the entire display device 1. An image input terminal 14, a three-digit decimal switch 12, a memory 13, a lighting control unit 15, and an image control unit 16 are connected to the main control unit 11. The memory 13 stores an OS necessary for control performed by the main control unit 11, various software, inspection image data to be described later, and the like. The image input terminal 14 is used for inputting image data displayed on the display device 1.

  The three-digit decimal (decimal number) switch 12 is a switch for setting the control mode of the display device 1 described above. As the control mode, a three-digit decimal number is set as shown in FIG. Based on the 3-digit decimal number set in the 3-digit decimal switch 12, the display device 1 is controlled.

  The display device 1 is usually a device that displays the image data input from the image input terminal 14 on the liquid crystal panel 2, but has a mechanism that can easily inspect whether the fluorescent tube 3 has failed or not visually. I have.

  Therefore, in the above display device 1, as shown in FIG. 4, when the setting value of the 3-digit decimal switch 12 in which the 3-digit decimal number is set is “100”, the control mode is set to the normal operation mode. . In this normal operation mode, image data input from the image input terminal 14 is displayed.

  When the set value of the above-mentioned three-digit decimal switch 12 is “200”, the control mode is set to the all fluorescent tube inspection mode. In this all fluorescent tube inspection mode, all fluorescent tubes 3 are visually inspected. When the set value of the 3-digit decimal switch 12 is “201 to 224”, the control mode is set to the individual fluorescent tube inspection mode. In this individual fluorescent tube inspection mode, a visual inspection of the fluorescent tubes with numbers indicated by the 1's place and the 10's place of the set value of the 3-digit decimal switch 12 is performed.

  The lighting control unit 15 in the control unit of the display device 1 performs lighting control of the fluorescent tube 3. The lighting control unit 15 is connected to a lighting circuit 17 and a preheating circuit 18 that are directly related to lighting and extinguishing of the fluorescent tube 3. The lighting control unit 15 is configured by a microprocessor and includes a memory for internal processing. The internal processing memory stores an OS necessary for control performed by the lighting control unit 15, various software, data necessary for various processing, and the like.

  The liquid crystal panel 2 is connected to the image control unit 16, and the image control unit 16 performs display control of the liquid crystal panel 2. The image control unit 16 includes a microprocessor and includes an internal processing memory. The internal processing memory stores an OS necessary for control performed by the image control unit 16, various software, data necessary for various processes, and the like.

  Next, an image display mechanism in the display device 1 will be described. The main controller 11 is connected to the lighting controller 15 as shown in FIG. First, the relationship between the main control unit 11 and the lighting control unit 15 will be described.

  FIG. 5 is an explanatory diagram showing signals transmitted and received between the main control unit 11 and the lighting control unit 15. In FIG. 5, a dimming signal, a normal lighting command, an inspection lighting command, and fluorescent tube designation data (1) to (8) are sent from the main control unit 11 to the lighting control unit 15. An error signal is sent from the lighting control unit 15 to the main control unit 11 when an error occurs in the lighting control unit 15.

  As shown in FIG. 7, the dimming signal is a digital signal of about 200 Hz in which one cycle consists of a high level and a low level. The brightness of the fluorescent tube 3 is determined by the duty ratio between the high level and the low level of the dimming signal. When the ratio of the high level is higher than the low level, the fluorescent tube 3 is lit brightly, and when the ratio of the low level is higher than the high level, the fluorescent tube 3 is lit darkly.

  The normal lighting command is output when the control mode is the normal operation mode. The inspection lighting command is output when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode. The fluorescent tube designation data (1) to (8) are data composed of 8 bits, and are signals for designating which of the first fluorescent tube to the 24th fluorescent tube is to be lit. The fluorescent tube designation data is output together with the inspection lighting command when the inspection lighting command is output.

  That is, normally, the control mode is a normal operation mode, and in this normal operation mode, a normal lighting command is output from the main control unit 11 to the lighting control unit 15, and at this time, the fluorescent tube designation data is Not output. In this case, all the fluorescent tubes from the first fluorescent tube to the 24th fluorescent tube are automatically turned on by the hardware of the lighting control unit 15.

  In contrast, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, the main controller 11 outputs the fluorescent tube designation data together with the inspection lighting command to the lighting controller 15. The

  The lighting control unit 15 is connected to a lighting circuit 17 and a preheating circuit 18 as shown in FIG. Therefore, next, the relationship between the lighting control unit 15 and the lighting circuit 17 and the relationship between the lighting control unit 15 and the preheating circuit 18 will be described.

  First, the relationship between the lighting control unit 15 and the lighting circuit 17 will be described. FIG. 6 is an explanatory diagram showing signals transmitted and received between the lighting control unit 15 and the lighting circuit 17. As shown in FIG. 3, one end of all the fluorescent tubes 3 of the first fluorescent tube to the 24th fluorescent tube is connected to the lighting circuit 17. The other end of these fluorescent tubes 3 is connected to a preheating circuit 18 as will be described later.

  In FIG. 6, signals sent from the lighting control unit 15 to the lighting circuit 17 are a first fluorescent tube lighting signal to a 24th fluorescent tube lighting signal. The signal sent from the lighting circuit 17 to the lighting control unit 15 is an error signal sent when an error occurs in the lighting circuit 17.

  FIG. 7 illustrates the above-described first generation generated by the lighting control unit 15 when a normal lighting command is output from the main control unit 11 to the lighting control unit 15, that is, when the control mode is the normal operation mode. It is the time chart which showed the fluorescent tube lighting signal-the 24th fluorescent tube lighting signal. As shown in this time chart, the first fluorescent tube lighting signal to the 24th fluorescent tube lighting signal are generated based on the dimming signal output from the main control unit 11 to the lighting control unit 15.

  The first fluorescent lamp lighting signal to the twenty-fourth fluorescent lamp lighting signal are provided on the condition that a normal lighting command is output from the main control section 11 to the lighting control section 15. Is generated.

  As shown in FIG. 7, the first fluorescent tube lighting signal is the same as the dimming signal output from the main control unit 11 to the lighting control unit 15, but the second fluorescent tube lighting signal to the 24th fluorescent tube. The lighting signal is generated by delaying the dimming signal little by little.

  FIG. 8 is an explanatory diagram showing lighting voltage waveforms actually applied to the first to 24th fluorescent tubes in the lighting circuit 17. Actually, the lighting voltage applied to the first fluorescent tube to the 24th fluorescent tube is turned on based on the first fluorescent tube lighting signal to the 24th fluorescent tube lighting signal sent from the lighting control unit 15 to the lighting circuit 17. It is generated by the circuit 17.

  Actually, a high frequency of 34 kHz generated from a DC voltage of 380 volts is used for generating the lighting voltage applied to the first fluorescent tube to the 24th fluorescent tube. The lighting voltage waveform is synchronized with each of the first fluorescent tube lighting signal to the 24th fluorescent tube lighting signal, and is 200 volts, low level during the period in which the first fluorescent tube lighting signal to the 24th fluorescent tube lighting signal is high level. This period is generated to be 3 volts. Each of the first to twenty-fourth fluorescent tubes is turned on at a predetermined brightness by turning on during the 200-volt period of the lighting voltage waveform and turning off during the 3-volt period of the lighting voltage waveform. Will be.

  The above description is a case where a normal lighting command is output from the main control unit 11 to the lighting control unit 15 as described above. On the other hand, when the inspection lighting command is output from the main control unit 11 to the lighting control unit 15, that is, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, the following is performed. become.

  When the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, the fluorescent tube designation data is output from the main control unit 11 to the lighting control unit 15 together with the inspection lighting command in any case. The

  Therefore, in this case, while the fluorescent tube designation data output together with the inspection lighting command is output from the main controller 11, the first fluorescent light is generated by the lighting controller 15 based on the fluorescent tube designation data. Any one of the tube lighting signal to the 24th fluorescent tube lighting signal is output.

  In this case, different operations are performed in the following points between the all fluorescent tube inspection mode and the individual fluorescent tube inspection mode. That is, in the case of the all fluorescent tube inspection mode, the fluorescent tube designation data output from the main control unit 11 is automatically changed by the software of the main control unit 11, for example, at intervals of 10 seconds. A fluorescent tube lighting signal is output.

  On the other hand, in the case of the individual fluorescent tube inspection mode, when the number indicated by the 1's place and the 10's place of the set value of the 3-digit decimal switch 12 representing the individual fluorescent tube inspection mode is changed by manual operation, The fluorescent tube designation data output from the main control unit 11 is changed by the software of the main control unit 11, and a fluorescent tube lighting signal corresponding to this is output from the lighting control unit 15.

  Next, the relationship between the lighting control unit 15 and the preheating circuit 18 will be described. FIG. 9 is an explanatory diagram showing signals transmitted and received between the lighting control unit 15 and the preheating circuit 18. As shown in FIG. 3, the preheating circuit 18 is connected to the other end of all the fluorescent tubes from the first fluorescent tube to the 24th fluorescent tube.

  In FIG. 9, signals sent from the lighting control unit 15 to the preheating circuit 18 are a first fluorescent tube preheating signal to a 24th fluorescent tube preheating signal. The signal sent from the preheating circuit 18 to the lighting control unit 15 is an error signal sent when an error occurs in the preheating circuit 18.

  FIG. 10 illustrates the above-described first generation generated by the lighting control unit 15 when a normal lighting command is output from the main control unit 11 to the lighting control unit 15, that is, when the control mode is the normal operation mode. It is the time chart which showed the fluorescent tube preheating signal-the 24th fluorescent tube preheating signal. As shown in this time chart, the first fluorescent tube preheating signal to the 24th fluorescent tube preheating signal are generated based on the dimming signal output from the main control unit 11 to the lighting control unit 15.

  The first to twenty-fourth fluorescent tube preheating signals are provided on the condition that a normal lighting command is output from the main control unit 11 to the lighting control unit 15. Is generated.

  As shown in FIG. 10, the first fluorescent tube preheating signal is the same as the dimming signal output from the main control unit 11 to the lighting control unit 15, but the second fluorescent tube preheating signal to the 24th fluorescent tube. The preheating signal is generated by gradually delaying the dimming signal.

  FIG. 11 is an explanatory diagram showing preheating voltage waveforms actually applied to the first to 24th fluorescent tubes in the preheating circuit 18. Actually, the preheating voltage applied to the first to twenty-fourth fluorescent tubes is preheated based on the first to twenty-fourth fluorescent tube preheating signals sent from the lighting control unit 15 to the preheating circuit 18. It is generated by the circuit 18.

  Actually, a high frequency of 34 kHz generated from a DC voltage of 380 volts is used to generate the preheating voltage applied to the first fluorescent tube to the 24th fluorescent tube. This preheating voltage waveform is synchronized with each of the first fluorescent tube preheating signal to the 24th fluorescent tube preheating signal, and the period during which the first fluorescent tube preheating signal to the 24th fluorescent tube preheating signal is high level is 10 volts, low level. This period is generated to be 3 volts. The first to twenty-fourth fluorescent tubes are turned on during the 10-volt period of the preheating voltage waveform, and are turned off during the 3-volt period of the preheating voltage waveform, together with the lighting voltage described above.

  The above description is a case where a normal lighting command is output from the main control unit 11 to the lighting control unit 15 as described above. On the other hand, when the inspection lighting command is output from the main control unit 11 to the lighting control unit 15, that is, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, the following is performed. become.

  When the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, as described above, the fluorescent tube together with the inspection lighting command is sent from the main control unit 11 to the lighting control unit 15. The specified data is output.

  Therefore, in this case, while the fluorescent tube designation data output together with the inspection lighting command is output from the main controller 11, the first fluorescent light is generated by the lighting controller 15 based on the fluorescent tube designation data. Any one of the tube preheating signal to the 24th fluorescent tube preheating signal is output.

  In this case, in the all fluorescent tube inspection mode and the individual fluorescent tube inspection mode, different operations are performed in the following points as described above. That is, in the case of the all fluorescent tube inspection mode, the fluorescent tube designation data output from the main control unit 11 is automatically changed by the software of the main control unit 11, for example, at intervals of 10 seconds. A fluorescent tube preheating signal is output.

  On the other hand, in the case of the individual fluorescent tube inspection mode, when the number indicated by the 1's place and the 10's place of the set value of the 3-digit decimal switch 12 representing the individual fluorescent tube inspection mode is changed by manual operation, The fluorescent tube designation data output from the main control unit 11 is changed by the software of the main control unit 11, and a fluorescent tube preheating signal corresponding to this is output from the lighting control unit 15.

  In the description of the relationship between the lighting control unit 15 and the lighting circuit 17 and the relationship between the lighting control unit 15 and the preheating circuit 18, the time indicated by the first fluorescent tube lighting signal to the 24th fluorescent tube lighting signal. As can be seen by comparing FIG. 7 which is a chart and FIG. 10 which is a time chart showing the first to 24th fluorescent tube preheating signals, the first fluorescent tube lighting signal to the 24th fluorescent tube. The lighting signal and the first fluorescent tube preheating signal to the 24th fluorescent tube preheating signal have exactly the same timing.

  Thus, in said display apparatus 1, the 1st fluorescent tube produced | generated based on the 1st fluorescent tube lighting signal-the 24th fluorescent tube lighting signal at one end with respect to the 1st fluorescent tube-the 24th fluorescent tube. A lighting voltage waveform to a 24th fluorescent tube lighting voltage waveform and a first fluorescent tube preheating voltage waveform to a 24th fluorescent tube generated based on the first fluorescent tube preheating signal to the 24th fluorescent tube preheating signal at the other end. The fluorescent tube is turned on by applying the preheating voltage waveform at the same timing.

  The main control unit 11 is connected to an image control unit 16 as shown in FIG. 3, and the liquid crystal panel 2 is connected to the image control unit 16. Then, next, the relationship between the main control part 11, the image control part 16, and the liquid crystal panel 2 is demonstrated. FIG. 12 is an explanatory diagram showing signals transmitted and received between the main control unit 11 and the image control unit 16.

  In FIG. 12, signals sent from the main control unit 11 to the image control unit 16 are a synchronization signal and image data. The signal sent from the image control unit 16 to the main control unit 11 is an error signal sent when an error occurs in the image control unit 16.

  When the control mode is the normal operation mode, the image data sent from the main control unit 11 to the image control unit 16 is image data inputted from the image input terminal 14. On the other hand, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, a plurality of inspection image data stored in the memory 13 connected to the main control unit 11 is The software of the control unit 11 is sent from the main control unit 11 to the image control unit 16 and displayed on the liquid crystal panel 2.

  Which timing of the plurality of pieces of inspection image data is sent out is controlled by software of the main control unit 11.

  FIG. 13 shows an example of an image formed by the inspection image data stored in the memory 13. These images include information indicating the position of each fluorescent tube 3 in the area portion of the liquid crystal panel 2 corresponding to the position where each of the 24 first fluorescent tube to the 24th fluorescent tube described above is installed. The images can be viewed from the front side of the liquid crystal panel 2 when the respective fluorescent tubes 3 are lit. As information representing the position of the fluorescent tube 3, a number indicating the number of the fluorescent tube 3 arranged from the top is used.

  Specifically, in the display device 1, the size of the display screen of the liquid crystal panel 2 is 1080 dots in the vertical direction as shown in FIG. With respect to the display screen of 1080 dots in the vertical direction, as shown in FIG. 14, 24 fluorescent tubes 3 are parallel to each other in the longitudinal direction of the display screen, that is, in the horizontal direction. Is arranged. Therefore, the illumination area of the liquid crystal panel 2 per one fluorescent tube 3 is 45 dots in the vertical direction.

  That is, each image shown in FIG. 13 includes a number indicating the position of each fluorescent tube 3 corresponding to the position where each of the 24 first fluorescent tube to 24th fluorescent tube described above is installed. A strip-shaped area D having 45 dots in the vertical direction is provided.

  FIG. 14 shows a state in which the second fluorescent tube is lit, and FIG. 13B is used as an image in this case. In this case, in a state where the second fluorescent tube is lit, the number “2”, which is a number indicating the position of the second fluorescent tube, can be visually confirmed from the front side of the liquid crystal panel 2.

  As described above, in the display device 1 described above, the control process in the main control unit 11 is performed by software. Then, next, the control process by the software in the main control part 11 is demonstrated.

  15 to 17 are flowcharts showing control processing by software in the main control unit 11. In the main control unit 11 of the display device 1 described above, in order to perform the above-described control processing, an operation type flag F, a value (temporary storage area value) M stored in the temporary storage area, a counter C, And the value (fluorescent tube number) P showing the fluorescent tube number is provided. A value (decimal switch value) set in the three-digit decimal switch 12 is represented by N.

  The operation type flag F is the operation type flag F = 0 when the control mode is the normal operation mode, and operates when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode. The type flag F = 1.

  When the operation type flag F is the operation type flag F = 0, a normal lighting command is output from the main control unit 11 to the lighting control unit 15, and as described above, by the hardware of the lighting control unit 15. All the fluorescent tubes of the first fluorescent tube to the 24th fluorescent tube are automatically turned on.

  The temporary storage area is an area for temporarily storing the value N of the 3-digit decimal switch 12, and the value M of the temporary storage area is a value obtained by reading the value N of the 3-digit decimal switch 12 at a certain time. . The counter C is a counter used for determining whether or not the processing for the 24 fluorescent tubes 3 has been completed. The fluorescent tube number P represents a number indicating the number of the fluorescent tube 3 arranged from the top.

  Next, control processing by software in the main control unit 11 will be described based on the flowcharts shown in FIGS. In the flowchart shown in FIG. 15, the main control unit 11 first sets the operation type flag F = 0 and the value M = 0 in the temporary storage area (S1) and reads the value N of the three-digit decimal switch 12 (S2). .

  Next, the value N of the three-digit decimal switch 12 is stored in the temporary storage area, and the value M = N in the temporary storage area is set (S3). Then, it is checked whether the value M of the temporary storage area is 100 or not. If the value M of the temporary storage area is 100 (S4), this means that the value N of the three-digit decimal switch 12 is N. Since = 100, the control mode is the normal operation mode. Therefore, the operation type flag F = 0 is set, and the process proceeds to S10.

  In S10, the value N of the 3-digit decimal switch 12 is read, and the value N of the 3-digit decimal switch 12 is compared with the value M in the temporary storage area (S11). The value N of the 3-digit decimal switch 12 = temporary storage. If the value is the area value M (S12), the value set in the three-digit decimal switch 12 has not changed, so the process returns to S10 and the processes after S10 are repeated.

  If the value N of the 3-digit decimal switch 12 and the value M of the temporary storage area are compared with the value N of the temporary storage area 12 in S12, if the value N of the temporary storage area 12 is not equal to the value M of the temporary storage area, the value is set to the 3-digit decimal switch 12 Since the value is changed, the process returns to S3 and the processes after S3 are repeated.

  If the temporary storage area value M = 100 in the check of whether or not the temporary storage area value M = 100 in S4, this is not the value N = 100 of the three-digit decimal switch 12; However, the possibility of the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode is high. Therefore, next, the operation type flag F = 1 is set (S6), and the process proceeds to S7.

  In S7, it is checked whether or not the value M of the temporary storage area is 200. If the value M of the temporary storage area is 200, the control mode is the all fluorescent tube inspection mode. Therefore, the entire fluorescent tube inspection process is performed (S20), and when the entire fluorescent tube inspection process (S20) is completed, the process proceeds to S10. In S10, the above-described processing is already performed.

  If it is determined in S7 whether the temporary storage area value M = 200 or not, the process proceeds to S8. In S8, it is checked whether or not the value M in the temporary storage area is 201 = <the value M in the temporary storage area = <224. If 201 = <the value M in the temporary storage area = <224, the control mode Is an individual fluorescent tube inspection mode. Therefore, the individual fluorescent tube inspection process is performed (S30), and when the individual fluorescent tube inspection process (S30) is completed, the process proceeds to S10. In S10, the above-described processing is already performed.

  In S8, if the value M of the temporary storage area is 201 = <value of the temporary storage area M = <224, and if 201 = <value of the temporary storage area M = <224, this is Since the control mode is neither the full fluorescent tube inspection mode nor the individual fluorescent tube inspection mode, the operation type flag F = 0 is set (S9), and the process proceeds to S10. In S10, the above-described processing is already performed.

  FIG. 16 is a flowchart showing the all fluorescent tube inspection process (S20). In FIG. 16, in the all fluorescent tube inspection process (S20), first, the counter C = 0 is set (S21). Then, the process proceeds to S22. In S22, the counter C = C + 1 is set, and then the process proceeds to S23.

  In S23, the fluorescent tube designation data of the number indicated by the counter C is transmitted to the lighting control unit 15 together with the inspection lighting command. Next, the inspection image data having the number indicated by the counter C is taken out from the memory, and transmitted to the image control unit 16 (S24), and the process proceeds to S25.

  In S25, it is checked whether 10 seconds have passed, and if 10 seconds have passed, it is checked whether counter C = 25 or not. If the counter C is not 25, the inspection of all the 24 fluorescent tubes 3 has not been completed, so the process returns to S22 and the processes after S22 are repeated. If the counter C = 25, since all the 24 fluorescent tubes 3 have been inspected, the entire fluorescent tube inspection process (S20) is ended.

  FIG. 17 is a flowchart showing the individual fluorescent tube inspection process (S30). In FIG. 17, in the individual fluorescent tube inspection process (S30), first, the fluorescent tube number P = 0 is set (S31), and the result of subtracting 200 from the value M in the temporary storage area is used as the value of the fluorescent tube number P. (S32), the process proceeds to S33.

  The calculation for obtaining the value of the fluorescent tube number P in S32 is to obtain the number of the fluorescent tube to be inspected. That is, as described above, when the setting value of the three-digit decimal switch 12 in which the control mode is the individual fluorescent tube inspection mode is “201 to 224”, the one's place of the setting value of the three-digit decimal switch 12 and 10 The number indicated by the position is the number of the fluorescent tube to be examined. Therefore, the value of the fluorescent tube number P is a number indicated by the 1's place and the 10's place of the set value of the digit decimal switch 12, and represents the number of the fluorescent tube 3 to be inspected. .

  In S33, the fluorescent tube designation data of the number indicated by the fluorescent tube number P is transmitted to the lighting control unit 15 together with the inspection lighting command. Then, the inspection image data having the number indicated by the fluorescent tube number P is taken out from the memory 13 and transmitted to the image control unit 16 (S34), and the individual fluorescent tube inspection process (S30) is ended.

  In the display device 1 described above, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, if the fluorescent tube 3 to be inspected is lit, a number indicating the position of the fluorescent tube 3 Is displayed on the display screen of the liquid crystal panel 2. In this case, the displayed time is 10 seconds even in the all fluorescent tube inspection mode, and in the individual fluorescent tube inspection mode, the display is continued unless the setting of the 3-digit decimal switch 12 is changed. Therefore, sufficient time can be secured for visual inspection. In this case, by visually observing the display screen of the liquid crystal panel 2, it can be seen that the fluorescent tube 3 to be inspected is normal.

  On the other hand, when the fluorescent tube 3 to be inspected is out of order and does not light up, nothing is displayed on the display screen of the liquid crystal panel 2. However, if the fluorescent tubes 3 with the numbers before and after the number of the fluorescent tube 3 to be inspected are not broken, those numbers are displayed when the fluorescent tubes 3 with the preceding and following numbers are inspected. By visually observing the display screen, it is possible to know the numbers before and after. Therefore, the number of the fluorescent tube 3 to be inspected can be known from these numbers.

  According to the display device 1 described above, in the display device 1 that includes the liquid crystal panel 2 of the display device 1 and the plurality of fluorescent tubes 3 that irradiate the liquid crystal panel 2 from the back side of the liquid crystal panel 2, Power is applied to the tube 3 from the lighting power source one by one, and the application is performed to the liquid crystal panel 2 in synchronization with the application of power in the fluorescent tube 3. The presence or absence of lighting of the fluorescent tube 3 can be visually observed from the front side of the liquid crystal panel during the application period. Therefore, the failed fluorescent tube 3 can be easily detected.

  In the above display device 1, a hot cathode tube (HCFL) is used as the fluorescent tube 3, but in a display device configured in the same manner as the above display device 1 using a cold cathode tube (CCFL). A mechanism for inspecting the fluorescent tube for visual failure in the display device 1 can be used.

  Further, in the display device 1 described above, the inspection image data sent from the main control unit 11 to the image control unit 16 is the position where each of the 24 first fluorescent tubes to the 24th fluorescent tubes is installed. Information indicating the position of each fluorescent tube 3 in the corresponding area of the liquid crystal panel 2 is an image that can be viewed from the front side of the liquid crystal panel 2 when each fluorescent tube 3 is lit. Is used.

  In this case, as described above, when the control mode is the all fluorescent tube inspection mode or the individual fluorescent tube inspection mode, and the fluorescent tube 3 to be inspected is lit, the number indicating the position of the fluorescent tube 3 However, it is displayed on the display screen of the liquid crystal panel 2, and the number indicating the position of the fluorescent tube 3 together with the presence or absence of lighting of the fluorescent tube 3 can be easily identified visually.

  However, the inspection image data sent from the main control unit 11 to the image control unit 16 is not limited to such data, and each of 24 first fluorescent tubes to 24th fluorescent tubes is installed. The image data for inspection may be used so that the portion of the area of the liquid crystal panel 2 corresponding to the position (for example, D in FIG. 13 as the inspection image) is displayed in white or light blue. Even in this case, the presence or absence of lighting of the fluorescent tube 3 can be easily identified visually.

It is the disassembled perspective view which showed the structure of the display apparatus in this Embodiment. It is sectional drawing which showed the structure of the display apparatus in this Embodiment. It is the block diagram which showed the structure of the control part of the display apparatus in this Embodiment. It is the table which showed the setting content of the 3-digit decimal switch of the display apparatus in this Embodiment. It is explanatory drawing which showed the signal between the main control part of the display apparatus in this Embodiment, and a lighting control part. It is explanatory drawing which showed the signal between the lighting control part of the display apparatus in this Embodiment, and a lighting circuit. It is a time chart of the light control signal of the display apparatus in this Embodiment, and a fluorescent tube lighting signal. It is a time chart of the fluorescent tube lighting signal and fluorescent tube lighting voltage waveform of the display device in the present embodiment. It is explanatory drawing which showed the signal between the lighting control part of the display apparatus in this Embodiment, and a preheating circuit. It is a time chart of the light control signal and fluorescent tube preheating signal of the display apparatus in this Embodiment. It is a time chart of the fluorescent tube preheating signal and fluorescent tube preheating voltage waveform of the display apparatus in this Embodiment. It is explanatory drawing which showed the signal between the main control part of the display apparatus in this Embodiment, and an image control part. (A)-(d) is explanatory drawing which showed the example of the image formed with the image data for a test | inspection of the display apparatus in this Embodiment. It is explanatory drawing which showed a response | compatibility with the liquid crystal panel and fluorescent tube of the display apparatus in this Embodiment. It is the flowchart (the 1) which showed the control processing of the main control part of the display apparatus in this Embodiment. It is the flowchart (the 2) which showed the control processing of the main control part of the display apparatus in this Embodiment. It is the flowchart (the 3) which showed the control processing of the main control part of the display apparatus in this Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Display apparatus 2 Liquid crystal panel 3 Fluorescent tube 4 Lens sheet 5 Diffusion plate sheet 6 Reflective sheet 7 Fluorescent tube mounting piece 10 Chassis 11 Main control part 12 3-digit decimal switch 13 Memory 14 Image input terminal 15 Lighting control part 16 Image control part 17 Lighting circuit 18 Preheating circuit

Claims (7)

A display device comprising: a liquid crystal panel; and a plurality of light sources that irradiate the liquid crystal panel from the back side of the liquid crystal panel,
For each of the plurality of light sources, for each one of the light sources, a light source lighting control that sequentially applies power from a lighting power source, and the light source lighting control causes the one light source to face and irradiate the light source. A liquid crystal panel display control for performing display in an irradiation area of a liquid crystal panel in synchronization with the application of the electric power. The display device according to claim 1,
The display performed by the liquid crystal panel display control is a display device that displays information representing the position of the light source. The display device according to claim 1,
The display performed by the liquid crystal panel display control is a display device that is transmitted so as to transmit the irradiation of the light source. The display device according to any one of claims 1 to 3,
The display device, wherein the light source is a hot cathode tube. A light source inspection method for a display device comprising: a liquid crystal panel; and a plurality of light sources that irradiate the liquid crystal panel from the back side of the liquid crystal panel,
For each of the plurality of light sources, for each of the light sources, performing light source lighting control for sequentially applying power from a lighting power source,
A liquid crystal panel display control for performing display in synchronization with the application of the electric power to an irradiation area of the liquid crystal panel irradiated with one light source facing by the light source lighting control. Light source inspection method. The light source inspection method for a display device according to claim 5,
The display performed by the liquid crystal panel display control is a light source inspection method for a display device, which is performed so as to display information indicating the position of the light source. The light source inspection method for a display device according to claim 5,
The display performed by the liquid crystal panel display control is a light source inspection method for a display device that is performed so as to transmit the irradiation of the light source.

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