JP3111703U - LCD module inspection equipment - Google Patents

Abstract

An object of the present invention is to simplify an operation of switching between parallel data indicating 100% luminance and parallel data indicating a black level even when parallel data can be set to data indicating arbitrary luminance.
A luminance data setting unit for outputting parallel data corresponding to on / off states of bit switches S1 to S8 using signal lines L1 to L8, and a display drive signal 31 indicating luminance corresponding to the parallel data are displayed on a liquid crystal display. In the configuration including the display signal circuit 2 to be sent to the module 13, the parallel data led to the display signal circuit 2 corresponds to the on / off states of the bit switches S1 to S8 in response to the on / off switching of the level changeover switch 18. A level switching unit 3 for switching between the parallel data and the parallel data indicating the black level.
[Selection] Figure 1

Description

  The present invention relates to a liquid crystal display module inspection apparatus that sends a display drive signal indicating luminance corresponding to parallel data to a liquid crystal display module to be inspected. More specifically, parallel data corresponds to bit switch settings. The present invention relates to a liquid crystal display module inspection apparatus having a switch for switching between parallel data and parallel data indicating a black level.

  In a line for manufacturing a liquid crystal display module, a confirmation inspection of the operation of the liquid crystal display module is performed in a process near the end of the line, and FIG. 5 shows the prior art of an inspection apparatus used for the operation confirmation inspection. Yes. That is, a liquid crystal display module (hereinafter referred to as an LCD module) 13 to be inspected includes a horizontal drive circuit 6, a vertical drive circuit 7, a liquid crystal panel 8, and a backlight 9, and is provided on the LCD substrate 91. The display drive signal generated by the displayed display signal circuit 2 is displayed on the liquid crystal panel 8. On the other hand, the display signal circuit 2 generates a display drive signal indicating luminance corresponding to the parallel data guided through the 8-bit signal lines L1 to L8 sent from the main board 11. For this reason, in the inspection, it is examined whether or not the brightness of the plain image displayed on the liquid crystal panel 8 is the brightness corresponding to the setting of the bit switches S1 to S8 (this is the first conventional technique).

  Further, the following technique has been proposed (referred to as a second conventional technique). That is, in this technique, a gate element is provided in which an inspection signal output from a vertical drive circuit that drives a liquid crystal panel and an inspection signal output from a horizontal drive circuit that drives the liquid crystal panel are guided. Then, by observing the output waveform of the gate element outside, it is inspected whether the vertical drive circuit is operating normally and whether the horizontal drive circuit is operating normally. Therefore, the number of terminals for guiding the inspection signal to the outside is greater than when the inspection signal output from the vertical drive circuit and the inspection signal output from the horizontal drive circuit are each guided to the outside. Is reduced from two to one. That is, since the number of terminals that are not used except for the time of inspection is reduced, the probability of element destruction caused by the application of static electricity to the terminals can be reduced. Further, at the time of inspection, the operation state of the horizontal drive circuit and the operation state of the vertical drive circuit can be inspected without switching the connection of terminals, so that the inspection time is shortened (for example, see Patent Document 1). ).

Further, the following technique has been proposed (referred to as a third conventional technique). That is, a signal line provided on the liquid crystal panel and transmitting a signal sent from the horizontal drive circuit drops to 0 V when the power is turned off, and VCOM is turned to 0 V when the power is turned off. The speed of descending is different. For this reason, when the power is turned off, when the signal line is viewed from the VCOM, a voltage is generated due to the difference in speed described above, so that the screen is disturbed when the power is turned off. For this reason, a switch element for short-circuiting the signal line with respect to VCOM is provided between the signal line and VCOM. When the power is turned off, the switch element is turned on. As a result, when the power is turned off, the potential of the signal line immediately becomes equal to the potential of VCOM. Therefore, screen disturbance when the power is turned off is prevented (see, for example, Patent Document 2).
JP-A-7-13515 JP 2001-42288 A

  However, when the first prior art is used, the following problems occur. That is, in the inspection of the LCD module 13 in the production line, when a display drive signal indicating 100% luminance is given, the inspection contents are inspected whether the luminance of the liquid crystal panel 8 becomes 100% luminance in the standard. When a display drive signal indicating 0% luminance (a display drive signal indicating a black level) is given, two types of inspections are performed, that is, whether or not the luminance of the liquid crystal panel 8 is at the black level in the standard. There are many. However, depending on the content of the defect found in the inspection, because of the problem of reproducibility, an inspection in an arbitrary luminance display is required on the production line, and therefore the function of displaying an arbitrary luminance cannot be omitted.

  On the other hand, when a display drive signal indicating 100% luminance is applied to the LCD module 13, all of the bit switches S1 to S8 must be turned off, and when a display drive signal indicating 0% luminance is applied to the LCD module 13. All of the bit switches S1 to S8 need to be turned on. That is, in order to inspect one LCD module 13, an operation to turn on all eight bit switches S1 to S8 and an operation to turn off all eight bit switches S1 to S8 are required. Since the operation takes time, work efficiency is deteriorated.

  The second prior art is a technique for reducing the number of terminals for guiding inspection signals to the outside from two to one. For this reason, it is difficult to apply from the viewpoint of solving the problem caused in the first prior art, that is, from the viewpoint of simplifying the switch operation during the inspection of the LCD module 13 and improving the working efficiency. It has become.

  The third prior art is a technique for preventing a potential difference from being generated between the signal line and VCOM when the power is turned off. For this reason, it is difficult to apply from the viewpoint of solving the problem caused in the first prior art, that is, from the viewpoint of simplifying the switch operation during the inspection of the LCD module 13 and improving the working efficiency. It has become.

  The present invention was devised to solve the above-described problems, and the object of the present invention is to provide parallel data indicating 100% luminance even when parallel data can be set to data indicating arbitrary luminance. The operation for switching to parallel data indicating 0% luminance can be simplified, the variation of the pixels of the liquid crystal display module can be easily detected, and the configuration of the level switching unit can be simplified. An object of the present invention is to provide a liquid crystal display module inspection apparatus capable of performing the above-described process.

  Another object of the present invention is to switch the parallel data guided to the display signal circuit between the parallel data corresponding to the on / off state of the bit switch and the parallel data indicating the black level in response to the on / off switching of the level change switch. This makes it possible to simplify the operation of switching between parallel data indicating 100% luminance and parallel data indicating 0% luminance even when parallel data can be set to data indicating arbitrary luminance. It is to provide a module inspection device.

  In addition to the above purpose, the brightness of the backlight can be switched between the specified brightness as a product and the brightness that makes it easy to visually recognize the variation of the pixels of the liquid crystal display module in the display of 100% brightness. Another object of the present invention is to provide a liquid crystal display module inspection apparatus that can easily detect variations in pixels of a liquid crystal display module.

  In order to solve the above problems, a liquid crystal display module inspection device according to the present invention is provided with a bit switch corresponding to each of a plurality of signal lines, and parallel data corresponding to an on / off state of the bit switch is transmitted to the plurality of signal lines. And a display drive signal indicating the brightness corresponding to the parallel data guided through the plurality of signal lines to a liquid crystal display module to be inspected and provided with a backlight. A display signal circuit for sending and a backlight drive circuit for generating a lighting drive output for driving the backlight to send it to the liquid crystal display module, and each of the plurality of signal lines is connected to a positive power source via a resistor. Are connected to one terminal of the corresponding bit switch, and the other terminal of all the bit switches is grounded. Is applied to the liquid crystal display module inspection apparatus. A level changeover switch is provided. Corresponding to the on / off switching of the level changeover switch, the parallel data guided to the display signal circuit is converted into parallel data corresponding to the on / off state of the bit switch and parallel data indicating the black level. A level switching unit for switching and a backlight luminance switch are provided. The level switching unit is provided for each of the plurality of signal lines, and includes a diode having an anode connected to the signal line and a cathode connected to each other and connected to one terminal of the level switching switch. Further, the other terminal of the level change switch provided in the level change unit is grounded. In addition, the backlight drive circuit changes the level of the lighting drive output in response to the ON / OFF of the backlight brightness switch, thereby changing the backlight brightness to a specified brightness as a product and parallel indicating 100% brightness. In the display corresponding to the data, the brightness is changed so that the variation of the pixels of the liquid crystal display module can be easily recognized.

  That is, when the on / off state of the bit switch is set to a state corresponding to parallel data indicating 100% luminance, the display signal circuit can be connected to the display signal circuit only by a simple operation of switching on / off of one switch called a level change switch. The derived parallel data can be switched between parallel data indicating 100% luminance and parallel data indicating 0% luminance (black level). When the backlight luminance switch is used to make the luminance of the backlight easy to see the variation of the pixels of the liquid crystal display module in the display corresponding to the parallel data indicating 100% luminance, the liquid crystal display module The variation of the pixels can be easily recognized. Further, the level switching unit can be configured by a number of diodes equal to the number of signal lines and one switch.

  Also, the liquid crystal display module inspection apparatus according to the present invention is provided with a bit switch corresponding to each of a plurality of signal lines, and luminance data for outputting parallel data corresponding to the on / off state of the bit switch using the plurality of signal lines. A liquid crystal display module inspection apparatus comprising: a setting unit; and a display signal circuit for sending a display drive signal indicating luminance corresponding to parallel data guided through the plurality of signal lines to a liquid crystal display module to be inspected Has been applied. A level changeover switch is provided. Corresponding to the on / off switching of the level changeover switch, the parallel data guided to the display signal circuit is converted into parallel data corresponding to the on / off state of the bit switch and parallel data indicating the black level. A level switching unit for switching is provided.

  That is, when the on / off state of the bit switch is set to a state corresponding to parallel data indicating 100% luminance, the display signal circuit can be connected to the display signal circuit only by a simple operation of switching on / off of one switch called a level change switch. The derived parallel data can be switched between parallel data indicating 100% luminance and parallel data indicating 0% luminance.

  In addition to the above-described configuration, the liquid crystal display module is provided with a backlight, and includes a backlight drive circuit that generates a lighting drive output for driving the backlight and sends it to the liquid crystal display module, and a backlight luminance switch. ing. Then, the backlight drive circuit changes the level of the lighting drive output in response to the on / off of the backlight brightness switch, thereby changing the backlight brightness to a specified brightness as a product and parallel indicating 100% brightness. In the display corresponding to the data, the brightness of the liquid crystal display module is changed to a luminance that facilitates visual recognition of pixel variations.

  That is, when the backlight luminance switch is used to make the luminance of the backlight easy to see the variation of the pixels of the liquid crystal display module in the display corresponding to the parallel data indicating 100% luminance, the liquid crystal display module The variation of the pixels can be easily recognized.

  According to the present invention, when the on / off state of the bit switch is set to a state corresponding to parallel data indicating 100% luminance, only a simple operation of switching on / off of one switch called a level change switch is performed. The parallel data guided to the display signal circuit can be switched between parallel data indicating 100% luminance and parallel data indicating 0% luminance. When the backlight brightness switch is used to make the brightness of the backlight easy to see the variation of the pixels of the liquid crystal display module in the display corresponding to the parallel data indicating 100% brightness, the liquid crystal display module The variation of the pixels can be easily recognized. In addition, the level switching unit can be configured by a number of diodes equal to the number of signal lines and one switch. For this reason, even when the parallel data can be set to data indicating arbitrary luminance, the operation of switching between parallel data indicating 100% luminance and parallel data indicating 0% luminance can be simplified. Therefore, the work efficiency of inspection can be increased. In addition, it is possible to easily detect variations in pixels of the liquid crystal display module, and it is possible to simplify the configuration of the level switching unit.

  Further, according to the present invention, when the on / off state of the bit switch is set to a state corresponding to parallel data indicating 100% luminance, only a simple operation of switching on / off of one switch called a level change switch is required. The parallel data guided to the display signal circuit can be switched between parallel data indicating 100% luminance and parallel data indicating 0% luminance. For this reason, even when the parallel data can be set to data indicating arbitrary luminance, the operation of switching between parallel data indicating 100% luminance and parallel data indicating 0% luminance can be simplified. That is, the inspection work efficiency can be increased.

  Further, when the backlight luminance switch is used to make the luminance of the backlight easy to see the variation of the pixels of the liquid crystal display module in the display corresponding to the parallel data indicating 100% luminance, the liquid crystal display Since it becomes easy to visually recognize the variation of the pixels of the module, it is possible to easily detect the variation of the pixels of the liquid crystal display module.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram (partially including a circuit diagram) showing an electrical configuration of an embodiment of a liquid crystal display module inspection apparatus according to the present invention. The same reference numerals as those in FIG. 5 are given to the elements.

  As shown in the figure, this embodiment is roughly composed of two substrates, a main substrate 11 and an LCD substrate 12, via a connector (not shown) provided on the LCD substrate 12. A liquid crystal display module (hereinafter referred to as an LCD module) 13 to be inspected is connected to the LCD substrate 12. The main board 11 and the LCD board 12 are connected to each other by an FFC cable.

  Further, the inspection content is the inspection (contrast of the display state of the LCD module 13 when the display driving signal 31 for displaying 100% luminance and the display driving signal 31 for displaying 0% luminance (black level) are given. And inspection of variations in the elements of the LCD module 13 when the display drive signal 31 for displaying 100% luminance is given (inspection for occurrence of irregularities such as stripes that disturb the screen). It is made up of.

  Specifically, the LCD module 13 is a 2.45 inch LCD module, and includes a horizontal drive circuit 6, a vertical drive circuit 7, a liquid crystal panel 8, and a backlight 9. The horizontal drive circuit 6 generates a drive signal for driving the liquid crystal panel 8 according to a display drive signal 32 including a signal indicating an image and a signal indicating timing, and sends the drive signal to the liquid crystal panel 8. The vertical drive circuit 7 generates a drive signal for driving the liquid crystal panel 8 according to the display drive signal 33 indicating the timing of scanning in the vertical direction, and sends it to the liquid crystal panel 8. The backlight 9 includes a cold cathode tube and a light guide plate (not shown), and forms a light source of the liquid crystal panel 8.

  The main board 11 is a block that generates 8-bit parallel data indicating luminance and outputs the parallel data to the LCD board 12. For this reason, a luminance data setting unit 1 is provided. The luminance data setting unit 1 includes eight bit switches S1 to S8 (configured by dip switches) corresponding to the eight signal lines L1 to L8, respectively. One terminal of each of the bit switches S1 to S8 is connected to the corresponding signal line L1 to L8, and the other terminal is all grounded. In addition, each of the signal lines L1 to L8 is connected to a positive power source (3.3 V) via the corresponding resistors R1 to R8.

  For this reason, when all of the bit switches S1 to S8 are turned off, all of the signal lines L1 to L8 are at the H level, and parallel data indicating 100% luminance is output. When all of the bit switches S1 to S8 are turned on, all of the signal lines L1 to L8 are at L level, and parallel data indicating 0% luminance (black level) is output. When the on / off states of the bit switches S1 to S8 are set to other states, parallel data indicating luminance corresponding to the on / off state at that time is output.

  The LCD substrate 12 includes a display signal circuit 2, a level switching unit 3, a backlight luminance switch 4, and a backlight driving circuit 5.

  The display signal circuit 2 displays a display drive signal 31 (a display drive signal 32 to be sent to the horizontal drive circuit 6 and a display to be sent to the vertical drive circuit 7) indicating luminance corresponding to the parallel data guided through the signal lines L1 to L8. Are transmitted to the LCD module 13 to be inspected. The display signal circuit 2 is a circuit integrated in an IC conventionally used as a timing controller.

  The level switching unit 3 includes eight diodes D1 to D8 and a level switch 18. The anodes of the diodes D1 to D8 are connected to the corresponding signal lines L1 to L8, the cathodes of the diodes D1 to D8 are connected to each other, and are connected to one terminal of the level changeover switch 18. Yes. The other terminal of the level switch 18 is grounded.

  For this reason, when the level changeover switch 18 is turned off, each of the signal lines L1 to L8 is equivalent to a state disconnected from the diodes D1 to D8. Accordingly, the display signal circuit 2 is supplied with the parallel data sent from the luminance data setting unit 1. When the level switch 18 is turned on, the signal lines L1 to L8 are grounded via the diodes D1 to D8. Accordingly, the display signal circuit 2 is supplied with parallel data all at L level. At this time, the level of the signal lines L1 to L8 does not become 0V, but is about 0.6V. However, in the display signal circuit 2, it is identified as the L level.

  That is, the level switching unit 3 converts the parallel data guided to the display signal circuit 2 in response to the on / off switching of the level switching switch 18, the parallel data corresponding to the on / off states of the bit switches S1 to S8, and the black level. Switch to the parallel data shown. Therefore, when all of the bit switches S1 to S8 are turned off, the parallel data guided to the display signal circuit 2 is converted into parallel data indicating 100% luminance and 0% only by operating the level changeover switch 18. Switching to parallel data indicating luminance is possible.

  The backlight drive circuit 5 generates a lighting drive output 34 for lighting the backlight 9 and sends it to the LCD module 13. The backlight luminance switch 4 switches the level of the lighting drive output 34 that the backlight drive circuit 5 sends to the LCD module 13.

  Specifically, the backlight drive circuit 5 includes an inverter circuit 29, two transistors Q1 and Q2, two Zener diodes ZD1 and ZD2, and two resistors R11 and R12, as shown in FIG. .

  The inverter circuit 29 generates a lighting drive output 34 for lighting the backlight 9 using the direct current sent from the emitter of the transistor Q1 as an operation power supply. For this reason, the emitter of the transistor Q1 is led to the power input terminal of the inverter circuit 29. Further, a 7V positive power supply 28 is led to the collector of the transistor Q1. A resistor R11 is connected between the collector and base of the transistor Q1.

  The cathodes of the Zener diodes ZD1 and ZD2 are connected to the base of the transistor Q1. The anode of the Zener diode ZD1 is grounded, and the anode of the Zener diode ZD2 is connected to the collector of the transistor Q2. The emitter of the transistor Q2 is grounded, and the base of the transistor Q2 is led to one terminal of the backlight luminance switch 4. Further, a positive power supply 28 is supplied to the base of the transistor Q2 via the resistor R12. The other terminal of the backlight luminance switch 4 is grounded.

  Note that the Zener voltage of the Zener diode ZD2 is set lower than the Zener voltage of the Zener diode ZD1. For this reason, when the transistor Q2 is turned on, the current via the resistor R11 does not flow to the Zener diode ZD1 side but flows to the Zener diode ZD2 side. As a result, a voltage stabilized by the Zener diode ZD2 is applied to the base of the transistor Q1. On the other hand, when the transistor Q2 is turned off, a voltage stabilized by the Zener diode ZD1 is applied to the base of the transistor Q1.

  The backlight drive circuit 5 has the above-described configuration. Accordingly, when the backlight luminance switch 4 is turned on and the transistor Q1 is turned off, a voltage obtained by subtracting the base-emitter voltage (about 0.6 V) of the transistor Q1 from the Zener voltage of the Zener diode ZD1 is supplied to the inverter circuit 29. (In this embodiment, this voltage is about 6V).

  When the backlight luminance switch 4 is turned off and the transistor Q1 is turned on, the base of the transistor Q1 is obtained from the voltage obtained by adding the collector-emitter voltage (about 0.3 V) of the transistor Q2 to the Zener voltage of the Zener diode ZD2. A voltage obtained by reducing the voltage between the emitters is applied to the inverter circuit 29 (in this embodiment, this voltage is about 4.5V).

  That is, when the backlight luminance switch 4 is turned on, the level of the lighting drive output 34 becomes high, and when the backlight luminance switch 4 is turned off, the level of the lighting drive output 34 becomes low. For this reason, the luminance of the backlight 9 becomes a prescribed luminance as a product when the backlight luminance switch 4 is turned on. On the other hand, when the backlight luminance switch 4 is turned off, the luminance of the backlight 9 is such that the variation of the pixels of the LCD module 13 in the display corresponding to the parallel data indicating 100% luminance can be easily recognized (as a product). The brightness is sufficiently lower than the specified brightness).

  3 and 4 are flowcharts showing the inspection procedure. The inspection procedure for the LCD module 13 will be described with reference to FIG.

  By operating a power switch (not shown), the power is turned off. In this state, all the bit switches are turned off so that the parallel data output from the luminance data setting unit 1 is parallel data indicating 100% luminance (step S1). Further, the level changeover switch 18 is turned on so that the parallel data guided to the display signal circuit 2 is parallel data indicating 0% luminance (black level) (step S2). Further, in order to set the luminance of the backlight 9 to a prescribed luminance as a product, the backlight luminance switch 4 is turned on (step S3).

  Next, after the LCD module 13 is connected to the LCD substrate 12 (step S4), the power is turned on (step S5). Therefore, a solid image corresponding to the black level is displayed on the liquid crystal panel 8 of the LCD module 13. It is checked whether or not the display at this time is a prescribed display (step S6). When there is no abnormality, the level changeover switch 18 is turned off, so that the parallel data becomes data indicating 100% luminance, and a solid image with 100% luminance is displayed on the liquid crystal panel 8 (steps S7 and S8). It is checked whether the display at this time is a specified display. That is, it is checked whether or not a prescribed contrast is obtained (step S9).

  When the LCD module 13 is normal and has a prescribed contrast, the backlight luminance switch 4 is turned off, and a plain image showing the luminance of the backlight 9 and 100% luminance is displayed on the liquid crystal panel 8. At this time, the brightness of the liquid crystal panel 8 is set to a luminance that makes it easy to visually recognize whether or not there is a variation in pixels (when there is a variation, a striped pattern or the like occurs in the liquid crystal panel 8) (step S11). If the pixels do not vary, the power is turned off (steps S12 and S13), and the LCD module 13 is removed from the LCD substrate 12 (step S14). And when performing a test | inspection continuously, operation | movement transfers to step S2 from step S15. When all the LCD modules 13 have been inspected, the operation ends.

  On the other hand, an abnormality is found when a black level plain image is displayed on the liquid crystal panel 8 (step S7), or when a 100% luminance plain image is displayed on the liquid crystal panel 8. When (step S10) or when element variations are found (step S12), the operation proceeds to step S21.

  When the process proceeds to step S21, the brightness of the plain image to be displayed in the state where the LCD module 13 in which the defect is found is connected to the same LCD substrate 12 as in the previous inspection is set to 100% brightness or 0% brightness. If the brightness is different from, it is checked whether further inspection is necessary.

  When it is determined that further inspection is necessary, the level changeover switch 18 is turned off, and the parallel data guided to the display signal circuit 2 is changed to parallel data set by the bit switches S1 to S8, and then the bit switches S1 to S1. Using S8, the parallel data of the luminance necessary for the inspection is given to the display signal circuit 2 (steps S22 and S23). Then, further inspection for defects is performed. At this time, when the luminance needs to be changed, the bit switches S1 to S8 are operated as necessary (step S24).

  When the inspection is completed, the power is turned off and the LCD module 13 is removed from the LCD substrate 12 (steps S25 and S26). Thereafter, the operation proceeds to step S1, and the process returns to the next inspection of the LCD module 13. On the other hand, if an abnormality is found in steps S7, S10, and S12, but it is determined that there is no need to continue further inspection in the production line, the operation proceeds from steps S21 and S22 to step S25, and the power is turned off. . Thereafter, the LCD module 13 is removed from the LCD substrate 12 (step S26).

  The present invention is not limited to the above-described embodiment, and the parallel data guided to the display signal circuit 2 has been described as being 8-bit data. However, when the parallel data is in other numbers of bits, Can be applied.

  In order to change the level of the lighting drive output 34, the operating power supply voltage of the backlight drive circuit 5 is switched between 6V and 4.5V, which is 75% of 6V. The ratio between the voltage for the purpose and the voltage for facilitating the visual recognition of pixel variations may be the most optimal ratio for the liquid crystal display module depending on the configuration of the liquid crystal display module to be inspected. desirable.

1 is a block diagram (partly including a circuit diagram) showing an electrical configuration of an embodiment of a liquid crystal display module inspection device according to the present invention. FIG. 2 is a circuit diagram (partly including a block diagram) showing detailed electrical connection of a backlight drive circuit. It is a flowchart which shows the test | inspection procedure of a liquid crystal display module. It is a flowchart which shows the test procedure of a liquid crystal display module. It is a block diagram (a circuit diagram is included in part) which shows the electrical structure of a prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Brightness data setting part 2 Display signal circuit 3 Level switching part 4 Backlight brightness switch 5 Backlight drive circuit 9 Backlight 11 Main board 12 LCD board 13 Liquid crystal display module 18 Level change switch 31 Display drive signal 34 Lighting drive output D1- D8 Diode R1-R8 Resistor S1-S8 Bit switch

Claims (3)

A bit switch corresponding to each of the plurality of signal lines is provided, and a luminance data setting unit that outputs parallel data corresponding to the on / off state of the bit switch using the plurality of signal lines;
A display signal circuit for sending a display drive signal indicating luminance corresponding to parallel data guided through the plurality of signal lines to a liquid crystal display module to be inspected and provided with a backlight;
A backlight drive circuit that generates a lighting drive output for driving the backlight to be lit and sends it to the liquid crystal display module;
Each of the plurality of signal lines is connected to a positive power source through a resistor and connected to one terminal of a corresponding bit switch, and the other terminals of all the bit switches are grounded in the liquid crystal display module inspection device. ,
A level switch is provided, and the level at which the parallel data guided to the display signal circuit is switched between the parallel data corresponding to the on / off state of the bit switch and the parallel data indicating the black level in response to the on / off switching of the level switch. A switching unit;
With backlight brightness switch,
The level switching unit is provided for each of the plurality of signal lines, and includes a diode having an anode connected to the signal line and a cathode connected to one terminal of the level switching switch.
The other terminal of the level selector switch provided in the level selector is grounded,
The backlight drive circuit changes the level of the lighting drive output in accordance with the on / off state of the backlight brightness switch, thereby changing the backlight brightness into parallel data indicating the specified brightness as the product and 100% brightness. A liquid crystal display module inspection apparatus, characterized in that the brightness is changed to a luminance that facilitates visual recognition of pixel variations of the liquid crystal display module in the corresponding display. A bit switch corresponding to each of the plurality of signal lines is provided, and a luminance data setting unit that outputs parallel data corresponding to the on / off state of the bit switch using the plurality of signal lines;
In a liquid crystal display module inspection apparatus comprising: a display signal circuit that transmits a display drive signal indicating luminance corresponding to parallel data guided through the plurality of signal lines to a liquid crystal display module to be inspected;
A level switch is provided, and the level at which the parallel data guided to the display signal circuit is switched between the parallel data corresponding to the on / off state of the bit switch and the parallel data indicating the black level in response to the on / off switching of the level switch. A liquid crystal display module inspection apparatus comprising a switching unit. The liquid crystal display module is provided with a backlight,
A backlight drive circuit that generates a lighting drive output for driving the backlight to be transmitted and sends it to the liquid crystal display module;
With backlight brightness switch,
The backlight drive circuit changes the level of the lighting drive output in response to the ON / OFF state of the backlight brightness switch, thereby changing the backlight brightness to parallel data indicating the specified brightness as the product and 100% brightness. 3. The liquid crystal display module inspection apparatus according to claim 2, wherein the luminance is changed to a luminance that facilitates visual recognition of variations in pixels of the liquid crystal display module in the corresponding display.

Images