JP4515535B2 - Liquid crystal display evaluation apparatus, liquid crystal display evaluation method, and liquid crystal display - Google Patents

Description

  The present invention relates to an evaluation device for a liquid crystal display device, a liquid crystal display device equipped with a drive circuit using an overshoot parameter obtained by the evaluation, and an evaluation method for the liquid crystal display device. In particular, the evaluation includes evaluation of responsiveness. It relates to what is suitably implemented.

  In recent years, progress in flat panel displays (FPDs) has been remarkable, and cathode ray tube monitors are being replaced by various FPDs. In particular, liquid crystal displays (LCDs), which are pioneering FPDs, have made remarkable progress in technology and have been used in various scenes of daily life. ing.

  However, LCD still has some major weaknesses. One of the typical examples is that it is not good at displaying moving images. One of the main causes is that the response speed of the liquid crystal is slow. The response speed of the liquid crystal is often considered to be a black and white switching speed, but with the replacement of the cathode ray tube monitor as described above, the switching between halftone and halftone accounts for a large proportion, and the liquid crystal in this state The response speed must be taken into account. Moreover, in general, the response speed is slower in switching between halftones and halftones than in monochrome switching, which is a problem.

  For this reason, increasing the response speed is an unavoidable problem when replacing a TV with a CRT, and how to increase the response speed of liquid crystal between all gradations is a major issue. It has become a challenge. An overshoot (OS) driving method has been proposed as one of the means for solving the above problems. An example of this driving method is shown in FIG. When the liquid crystal switches from one gradation level A to another gradation level B, generally, the larger the gradation level difference between A and B, the faster the liquid crystal switches.

  Therefore, if the rise response is A <B as shown in FIG. 12, the target gradation level B is normally input after the OS gradation C having a gradation level satisfying B <C is input for a moment. The liquid crystal can be switched at a higher speed than the switching speed from A to B. Further, if A> B decay response, an OS gradation C having a gradation level satisfying B> C is input, and then a target gradation level B is input, so that a normal A to B transition is achieved. The liquid crystal can be switched at a higher speed than the switching speed.

  Actually, during full gradation switching (for example, switching from 0 gradation to 255 gradation), the liquid crystal switches at the highest speed, so the response speed of the liquid crystal by the OS driving method is theoretically between all gradations. In this switching, the response speed of full gradation switching can be increased. Therefore, by using the OS driving method in the liquid crystal display mode in which full gradation switching has a sufficiently high speed response, an LCD capable of a sufficiently high speed response in switching between all gradations can be obtained.

  One of the most important points to pay attention to when such an OS driving method is put into practical use is how to determine the OS parameter (the signal level applied as the OS gradation C during actual driving). That's what it means. In a circuit for performing OS driving, a general point of an algorithm that is generally used is “an arbitrary n field gradation (current gradation A) and an (n + 1) field gradation (arrival gradation B). And the OS parameter C is determined with reference to a look-up table (LUT) ”. The LUT determines C by combining the values of A and B, for example, “n field has 120 gradations and (n + 1) field has 150 gradations, OS parameter C has 190 gradations”. It is a list. If this LUT cannot be accurately determined, the following state is obtained, and a proper display cannot be obtained as a display.

  That is, when an appropriate OS parameter C is set, as shown in FIG. 13, an ideal responsiveness reaching the reached gradation B is obtained without exceeding the reached gradation B within one field period. be able to. On the other hand, when an excessively large OS parameter C is set to obtain a sufficiently high-speed response, an angle appears in the response waveform of the liquid crystal as shown in FIG. In such a case, the liquid crystal is responding excessively beyond the required switching level. When the LCD is actually viewed in this state, it looks unnaturally lit when switching or displaying a moving image. Further, if the OS parameter C is not set to a sufficiently large size due to fear of excessive response of the liquid crystal, sufficient response cannot be obtained (the reached gradation B is reached within one field period) as shown in FIG. No), the smaller the level of the OS parameter C, the closer to the responsiveness when the OS driving shown in FIG. 16 is not performed, and the meaning of the OS driving is lost.

  Therefore, in the determination of the OS parameter C, in a typical prior art, as shown in Japanese Patent Application Laid-Open No. 11-352450, a change in cell capacity that occurs during switching of liquid crystal is obtained, and the OS parameter C is calculated therefrom. It is done by that.

In addition, a method for estimating the OS parameter C from a response waveform of normal driving has been devised as follows.
1. The response waveform between each gradation in the normal driving method is measured.
2. From the waveform, the gradation level that is reached after elapse of time corresponding to the OS signal application amount is obtained.
3. Based on the result, the OS parameter C required for switching between the gradations is estimated, and an LUT is created.

JP 11-352450 A (publication date: December 24, 1999)

  However, when calculating the OS parameter C from the capacitance change, since the influence on the response of the viscosity of the liquid crystal is not taken into consideration at all, a large error often occurs between the calculation result and the actually required OS parameter C. That is, originally, the OS amount must be uniquely determined by the cell thickness, the cell shape, the liquid crystal material used, etc., but in reality, a large error of 30% or more occurs depending on the location. . On the other hand, until now, if the user's tolerance level for the parameter error is low and the liquid crystal with a slow response can be fast enough to withstand moving image display, even if there is some parameter error, it is acceptable. In the future, where not only response but also finer image quality is required, the allowable range of parameter error becomes extremely strict, and it is difficult to obtain the OS parameter C with less error by the conventional method.

  Further, although the method for estimating from the response waveform includes all necessary conditions, in order to determine the accurate OS parameter C, it is necessary to perform OS driving using the created LUT and perform waveform confirmation. There is a problem that it takes time and effort. Further, if adjustment is necessary as a result of the waveform confirmation, it is necessary to repeat the above estimation and confirmation measurement many times until the accurate OS parameter C is determined, which takes a lot of trouble.

  An object of the present invention is to provide a liquid crystal display evaluation apparatus, a liquid crystal display apparatus, and a liquid crystal display evaluation method capable of easily and accurately obtaining an optimal overshoot parameter.

  An evaluation apparatus for a liquid crystal display device according to the present invention receives a video signal generation circuit for supplying a video signal to a liquid crystal panel to be evaluated, an optical light receiving element facing a display unit of the liquid crystal panel, and an output from the optical light receiving element. The video signal generation circuit includes A as a gradation before changing the gradation, B as a gradation to be reached, and C as a level of the overshoot signal (where C = B). And the waveform analyzer sequentially applies the video signal whose level changes in the order of A → C → B to the liquid crystal panel while sweeping the overshoot level C. In the swept response waveform, there is no excessive response, and the level that has reached the arrival gradation B fastest is stored in association with the gradation A and the arrival gradation B before the change. .

  According to the above configuration, in performing overshoot driving for improving the response of the liquid crystal, the response of the liquid crystal panel is evaluated and the optimum overshoot parameter (actual overshoot drive level) is determined first. When an arbitrary gradation before changing the gradation is A, an arbitrary gradation to be reached is B, and an overshoot signal level is C, A → C while sweeping the overshoot level C A video signal generating circuit capable of sequentially outputting video signals whose levels change in the order of B is provided.

  Next, the display image of the liquid crystal panel by each video signal is photoelectrically converted by the optical light receiving element, and is taken into the waveform analyzer. Subsequently, the waveform analysis apparatus determines the level that has reached the arrival gradation B most quickly without the excessive response in the display result of the liquid crystal panel by the video signals of various overshoot levels C that have been swept. Stored in association with the gradation A and the arrival gradation B before the change as shoot parameters.

  Specifically, for example, in the case of a rise response, the C level is equal to or higher than the reached gradation level B for any gradations A and B where A <B, and the response waveform is observed by changing C. Then, an accurate overshoot parameter is determined by searching for the maximum C whose response waveform does not excessively respond to the B level. In other words, if overshoot driving is performed at the level C, a video image is not broken down, and a gradation display of a level closest to the desired reached gradation B can be realized within the overshoot driving period. Become. In the case of a decay response, for any gradations A and B where A> B, the level of C is equal to or lower than the reached gradation level B, the response waveform is observed by changing C, and the response waveform By searching for the smallest C that does not over-respond to the B level, the exact overshoot parameter is determined.

  Therefore, a look-up table (LookUp Table: LUT) of optimum overshoot parameters associated with the gradation A and the arrival gradation B before the change is set in the overshoot driving drive circuit of the liquid crystal panel. Thus, the drive circuit refers to the LUT from the gradation A and the arrival gradation B before the change of the input video signal, determines the optimum overshoot parameter, and appropriately overshoots the liquid crystal panel. can do.

  In this way, the optimum overshoot parameter can be obtained easily and with high accuracy. In addition, it is possible to perform measurement using an overshoot signal even for a liquid crystal panel that is not overshoot driven. Although two operations of determining the shoot parameter are necessary, in the present invention, the parameter for overshoot drive can be obtained even when the circuit is not completed, that is, even when overshoot drive is not possible.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, the overshoot drive is performed over an n field period, and the video signal generation circuit sequentially sets the level of the overshoot signal over the n field period as C1, C2. ,..., Cn (n is an arbitrary integer greater than or equal to 1), the video signals whose levels change in the order of A → C1 to Cn → B are sequentially transferred while the overshoot levels C1 to Cn are respectively swept. The waveform analysis apparatus gives the level that has reached the arrival gradation B fastest without any over-response in the response waveform obtained by sweeping the overshoot levels C1 to Cn. And storing in association with the reached gradation B.

  According to the above configuration, the overshoot signal does not need to be constant during the application period. For example, in the case where the response of the liquid crystal is remarkably slow at a low temperature, or in the double speed drive, the overshoot drive over multiple fields. By applying different overshoot signals for each field, the application range can be expanded. Therefore, assuming that the level of the overshoot signal is C1, C2,..., Cn (n is an arbitrary integer greater than or equal to 1) in order, the video signal generation circuit sets the gradation A and the arrival gradation B before the change. In addition, (n + 2) types of signals are output in this order for a specific time.

  Thus, by generating various n (multi) field overshoot drive signals, the overshoot parameters corresponding to the overshoot drive over the multiple fields can be determined accurately and simply.

  Furthermore, the evaluation apparatus for a liquid crystal display device of the present invention is further characterized by further comprising a thermostatic chamber capable of accommodating at least the liquid crystal panel.

  According to said structure, a thermostat is provided, an optical light receiving element is installed with the liquid crystal panel in the thermostat, or a liquid crystal panel is installed in the thermostat and the display part of the liquid crystal panel is externally attached to the thermostat. The display result is observed by providing a window so as to be observable and providing the optical light receiving element in the window.

  Therefore, the liquid crystal panel can be evaluated under a certain temperature condition. In addition, the liquid crystal panel can be evaluated at various environmental temperatures, and an optimal overshoot parameter can be obtained for each temperature. Furthermore, when a window is provided in the thermostatic chamber, an abnormality at the time of evaluation can be quickly found, and measures can be easily taken.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, the video signal generation circuit includes a switch provided corresponding to each of the gradation A before reaching the change, the arrival gradation B, and the overshoot level C, By digitally controlling the on / off of the switch, a voltage corresponding to the switching mode is sequentially output as the video signal.

  According to the above configuration, each of the gradation A, the reaching gradation B, and the overshoot level C before the change can be digitally adjusted arbitrarily and independently by setting the switch. The switch is preferably a multi-bit switch. In this case, an overshoot parameter can be set in detail in switching between arbitrary gradations.

  Furthermore, in the evaluation apparatus for a liquid crystal display device of the present invention, the switch for adjusting the overshoot level C is composed of two types of switches for coarse adjustment and for fine adjustment.

  According to the above configuration, after the level of the overshoot level C is adjusted to some extent with the coarse adjustment switch, the overshoot level C is determined in detail with the fine adjustment switch. For example, there are 256 levels of the overshoot level C, and it takes time to measure by changing these for each gradation. Therefore, a coarse adjustment switch and a fine adjustment switch are provided. First, the coarse adjustment switch is used to roughly determine the overshoot parameter, and then the fine adjustment switch is used to obtain an accurate overshoot parameter. Accurate evaluation in time is possible.

  In the evaluation apparatus for a liquid crystal display device of the present invention, the video signal generation circuit includes a switch provided corresponding to each of the gradation A before reaching the change, the arrival gradation B, and the overshoot levels C1 to Cn. The switch is digitally turned on / off to sequentially output a voltage corresponding to a switching mode as the video signal.

  According to the above configuration, each of the gradation A, the reaching gradation B, and the n (multi) field overshoot levels C1 to Cn before the change is digitally adjusted arbitrarily and independently by setting the switch. Can do. The switch is preferably a multi-bit switch. In this case, overshoot levels C1 to Cn can be set in detail in switching between arbitrary gradations.

  For example, in the case of 256 gradations in all gradations, it is desirable that the gradation A and the arrival gradation B before the change are switched at least every 16 gradations, preferably every gradation. On the other hand, the overshoot levels C1 to Cn need to be switched for each gradation because the overshoot effect varies depending on the gradation.

  Therefore, the number of switches for the gradations A and B can be increased by making the gradation A and the reaching gradation B before the change and the overshoot levels C1 to Cn adjustable by independent switches. Therefore, the necessary overshoot parameters can be set easily and in detail.

  Furthermore, in the evaluation apparatus for a liquid crystal display device according to the present invention, the switches for adjusting the overshoot levels C1 to Cn are composed of two types of coarse adjustment and fine adjustment.

  According to the above configuration, for example, in the case of 256 gradations in all gradations, the gradation A and the reaching gradation B before the change are switched at least every 16 gradations, preferably every gradation. On the other hand, since the overshoot levels C1 to Cn need to be switched for each gradation, the total number is 256 × n, and it takes time to change the gradation for each gradation. Therefore, for each of the overshoot levels C1 to Cn, the overshoot levels C1 to Cn are adjusted to some extent with the coarse adjustment switch, and then the overshoot levels C1 to Cn are determined in detail with the fine adjustment switch. This enables accurate evaluation in a short time.

  In the evaluation device for the liquid crystal display device of the present invention, in the case of a rise response where A <B, C1 to Cn are set to B ≦ C1 ≧ C2 ≧. And an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is determined as a maximum value at which the response waveform by the overshoot level Ck does not excessively respond to the level of the reached gradation B, If the response waveform due to the overshoot level Ck is substantially equal to the level of the reached gradation B, it is determined that Ck + 1 to Cn = B.

  According to the above configuration, in the case of the rise response, the overshoot levels C1 to Cn in all fields are equal to or higher than the reached gradation B, and the overshoot levels C1, C2,. By observing the response waveform and finding the maximum value at which the response waveform does not excessively respond to the level of the reached gradation B, the optimum overshoot parameter in each field can be determined.

  When the response waveform reaches the final gradation B level in an arbitrary k-th field, it is not necessary to perform overshoot driving thereafter. Therefore, by setting Ck + 1 to Cn = B, the overshoot of all fields is achieved. Shoot parameters can be determined.

  Furthermore, in the evaluation apparatus for the liquid crystal display device of the present invention, in the case of decay response where A> B, C1 to Cn are set to B ≧ C1 ≦ C2 ≦. And an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is determined to be a minimum value at which the response waveform by the overshoot level Ck does not excessively respond to the level of the reached gradation B If the response waveform due to the overshoot level Ck is substantially equal to the level of the reached gradation B, Ck + 1 to Cn = B is determined.

  According to the above configuration, in the case of decay response, the overshoot levels C1 to Cn in all fields are equal to or lower than the reached gradation B, and the overshoot levels C1, C2,. By observing the response waveform and finding the minimum value at which the response waveform does not excessively respond to the level of the reached gradation B, the optimum overshoot parameter in each field can be determined.

  When the response waveform reaches the final gradation B level in an arbitrary k-th field, it is not necessary to perform overshoot driving thereafter. Therefore, by setting Ck + 1 to Cn = B, the overshoot of all fields is achieved. Shoot parameters can be determined.

  The evaluation apparatus for a liquid crystal display device according to the present invention, in the case of a rise response where A <B, C1 to Cn for any gradations A and B, A <C1 ≦ ... ≦ Ck <B ≦ Ck + 1 ≧ ... ≧ Cn (k is an integer of 1 ≦ k ≦ n), and an arbitrary j-th (k + 1 ≦ j ≦ n) overshoot level Cj reaches the response waveform of the overshoot level Cj. If the maximum value that does not excessively respond to the level of gradation B is determined, and if the response waveform by the overshoot level Cj is substantially equal to the level of the reached gradation B, Cj + 1 to Cn = B is determined. It is characterized by.

  Depending on the display mode and switching gradation, the liquid crystal panel may not respond satisfactorily even if a strong overshoot signal is suddenly input. For example, in the vertical alignment mode at a low temperature, the rise from black is particularly poor and the response is poor. In such a case, as described above, first, in the 1st to kth fields, the overshoot levels C1 to Ck are intentionally set to be weak undershoot levels and the liquid crystal is made to respond slightly, and then the subsequent k + 1 to nth fields. In the field, it is conceivable to set the overshoot levels Ck + 1 to Cn to the original overshoot levels. The present invention can accurately determine an overshoot parameter even in such an overshoot driving method.

  In the apparatus for evaluating a liquid crystal display device of the present invention, the video signal generation circuit sets U1 to Un satisfying A <U1 ≦... ≦ Un ≦ B as an undershoot signal level in an arbitrary rise response of A <B. At the same time, the level C1 to Cn of the overshoot signal is set to B ≦ C1 ≧. Is applied to the liquid crystal panel, and the waveform analyzer is configured to output the undershoot signal levels U1 to Un and the overshoot signal levels C1 to Cj (j is an arbitrary integer satisfying 1 ≦ j ≦ n). ) U1 to Un and C1 to Cj so that the response waveform according to (1) reaches the level of the gradation B most quickly without exceeding the gradation B, and if j ≦ n−1, It is preferable to set Cj + 1 to Cn = B.

  As described above, in the liquid crystal panel, the response speed with respect to a predetermined gradation transition (rise A → B) can be increased by giving the undershoot signal in advance before giving the overshoot signal. According to the above configuration, the optimum undershoot signal levels U1 to Un and overshoot signal levels C1 to Cn in such a gradation transition (A → B) can be easily and accurately determined.

  Furthermore, in the evaluation apparatus for the liquid crystal display device of the present invention, in the case of a decay response where A> B, C1 to Cn are set to A> C1 ≧... Ck> B ≧ for arbitrary gradations A and B. Ck + 1 ≦ ... ≦ Cn (k is an integer of 1 ≦ k ≦ n), and an arbitrary jth overshoot level Cj (an integer of k + 1 ≦ j ≦ n) has a response waveform by the overshoot level Cj. If the minimum value that does not excessively respond to the level of the reached gradation B is determined, and the response waveform by the overshoot level Cj is substantially equal to the level of the reached gradation B, Cj + 1 to Cn = B is determined. It is characterized by that.

  According to the above configuration, the overshoot parameter can be accurately determined in the drive method in which the overshoot drive is performed from the undershoot drive in the decay response.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, the video signal generation circuit outputs U1 to Un satisfying A> U1 ≧...> Un> B with an arbitrary decay response of A> B as an undershoot signal. The level C1 to Cn of the overshoot signal is set to B ≧ C1 ≦... ≦ Cn, and each of U1 to Un and C1 to Cn is swept while A → U1 to Un → C1 to Cn → B. A video signal whose level changes in order is supplied to the liquid crystal panel, and the waveform analysis device satisfies the levels U1 to Un of the undershoot signal and levels C1 to Cj (j is 1 ≦ j ≦ n) of the overshoot signal. U1-Un and C1-Cj are determined so that the response waveform of any integer) reaches the level of gradation B most quickly without exceeding gradation B, and j ≦ n− In the case of 1, it is preferable to set Cj + 1 to Cn = B.

  As described above, in the liquid crystal panel, the response speed with respect to a predetermined gradation transition (decay A → B) can be increased by giving the undershoot signal in advance before giving the overshoot signal. According to the above configuration, the optimum undershoot signal levels U1 to Un and overshoot signal levels C1 to Cn in such a gradation transition (decay A → B) can be determined easily and accurately.

  The evaluation apparatus for a liquid crystal display device according to the present invention has C1 to Cn for any gradations A and B, and B ≦ C1 = C2 =. In addition, an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is a maximum value at which the response waveform of all overshoot levels C1 to Cn does not excessively respond to the level of the reached gradation B It is characterized by determining to.

  According to the above configuration, in the n (multiple) field overshoot drive, as a drive method in which the same effect can be obtained as a result of applying C to n fields in the A → C → B level drive, The same overshoot signal may be applied to all n fields, and the overshoot parameter in such a case of the rise response can be determined.

  Furthermore, in the evaluation apparatus for the liquid crystal display device of the present invention, in the case of a decay response where A> B, C1 to Cn are set as B ≧ C1 = C2 =. There is a minimum at which an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is not excessively responded to the level of the reached gradation B by the response waveform of all overshoot levels C1 to Cn. The value is determined.

  According to the above configuration, in the n (multiple) field overshoot drive, as a drive method in which the same effect can be obtained as a result of applying C to n fields in the A → C → B level drive, The same overshoot signal may be applied to all n fields, and the overshoot parameter in such a case of decay response can be determined.

  The liquid crystal display device of the present invention is characterized in that the overshoot level C determined by the evaluation device is stored as a look-up table for overshoot drive by the drive circuit.

  According to the above configuration, since the drive circuit includes a lookup table having an overshoot parameter optimum for the liquid crystal panel to be used, a liquid crystal display device capable of high-speed response and causing no video breakdown is provided. Can be realized.

  Furthermore, the liquid crystal display device of the present invention is characterized in that the drive circuit stores the overshoot levels C1 to Cn determined by the evaluation device as a look-up table for overshoot drive.

  According to the above configuration, when performing overshoot driving over multiple fields, the drive circuit has a lookup table composed of overshoot parameters optimal for the liquid crystal panel to be used, so high-speed response is possible. In addition, it is possible to realize a liquid crystal display device that does not cause video failure.

  Further, the liquid crystal display device evaluation method of the present invention is a method in which an overshoot signal is given to the liquid crystal panel to be evaluated, and the optimum overshoot signal level is evaluated from the response result, before the gradation is changed. When the gradation is A, the gradation to be reached is B, and the level of the overshoot signal is C (including C = B), a video signal whose level changes in the order of A → C → B. The step of applying to the liquid crystal panel and displaying it, the step of reading the display image of the liquid crystal panel based on the video signal, and the step of analyzing the waveform of the read display image are repeated while sweeping the overshoot level C. In the response waveform at each overshoot level C, the level that has reached the arrival gradation B fastest without excessive response is determined as the gradation A and the arrival gradation before the change. In association with each other, comprising the steps of slide into the store.

  According to the above configuration, when performing the overshoot driving for improving the response of the liquid crystal, in determining the optimum overshoot parameter, first, an arbitrary gradation before changing the gradation is set to A, When an arbitrary gradation to be reached is B and the level of the overshoot signal is C, a video signal whose level changes in the order of A → C → B is sequentially output while sweeping the overshoot level C. Display on the LCD panel.

  Along with the output, the display image is read, and the waveform analysis of the read display image is sequentially performed. As a result, the level that has reached the arrival gradation B fastest without excessive response is stored in association with the gradation A and the arrival gradation B before the change as the optimum overshoot parameter.

  Therefore, by setting a lookup table of the optimum overshoot parameter C corresponding to the gradation A and the arrival gradation B before the change in the driving circuit for overshoot driving of the liquid crystal panel, the driving is performed. The circuit can determine the optimum overshoot parameter from the gradation A and the arrival gradation B before the change of the input video signal with reference to the LUT, and can appropriately overshoot the liquid crystal panel. .

  In this way, the optimum overshoot parameter can be obtained easily and with high accuracy. In addition, it is possible to perform measurement using an overshoot signal even for a liquid crystal panel that is not overshoot driven, and when the overshoot drive is introduced to the panel later, circuit design and OS Although the two operations of determining the parameter C are necessary, the present invention can determine the parameters for overshoot driving even when the circuit is not completed, that is, even when overshoot driving is not possible.

  Furthermore, in the method for evaluating a liquid crystal display device according to the present invention, the overshoot drive is performed over an n field period, and the video signal generation circuit sets the level of the overshoot signal over the n field period in order of C1, C2. ,..., Cn (n is an arbitrary integer greater than or equal to 1), the video signals whose levels change in the order of A → C1 to Cn → B are sequentially transferred while the overshoot levels C1 to Cn are respectively swept. It is characterized by giving to the panel.

  According to the above configuration, the overshoot signal does not need to be constant during the application period. For example, in the case where the response of the liquid crystal is remarkably slow at a low temperature, or in the double speed drive, the overshoot drive over multiple fields. By applying different overshoot signals for each field, the application range can be expanded. Therefore, assuming that the level of the overshoot signal is C1, C2,..., Cn (n is an arbitrary integer greater than or equal to 1) in order, the video signal generation circuit sets the gradation A and the arrival gradation B before the change. In addition, (n + 2) types of signals are output in this order for a specific time.

  As a result, the overshoot parameter corresponding to the overshoot drive over multiple fields can be determined accurately and simply.

  In addition, in order to solve the above-described problems, the evaluation apparatus for a liquid crystal display device according to the present invention detects (detects) a signal unit that gives a signal to a liquid crystal panel to be evaluated and a display (display state) of the liquid crystal panel. A display detection unit (display detection unit); and an analysis unit that analyzes a detection result (detection result) of the display detection unit. The signal unit corresponds to the original gradation (A) with respect to the liquid crystal panel. A test drive that gives a signal, then gives an overshoot signal, and then gives a signal corresponding to the reached gradation (B) while sweeping the level of the overshoot signal, and the analysis unit comprises: Each detection result from the display detection unit obtained by the trial drive is analyzed, and based on the result, the level of the overshoot signal corresponding to the optimum detection result is set to the original gradation (A) and the reached gradation. It is configured to continue to store in association with B).

  First, the overshoot (OS) signal is a signal having a level equal to or higher than the level of the signal corresponding to the arrival gradation (B) (in the case of the rise response of the original gradation A <arrival gradation B), or the above arrival. A signal having a level equal to or lower than the level of the signal corresponding to the gradation (B) (in the case of the decay response of the original gradation A> the reached gradation B).

  In the above configuration, the signal unit provides a signal corresponding to the original gradation (A) to the liquid crystal panel, then an overshoot signal, and then a signal corresponding to the arrival gradation (B). The trial drive (trial OS drive) is performed by changing (over sweeping) the level of the overshoot signal.

  As a result, a display corresponding to each overshoot signal (level) is made on the liquid crystal panel to be evaluated, and the display detection unit detects each display. Then, each detection result is analyzed by the analysis unit, and an optimum detection result when the original gradation is A and the arrival gradation is B is found, and an overshoot corresponding to the optimum detection result is found. The signal level (optimal overshoot signal level) is stored in association with the original gradation A and the arrival gradation B.

  As described above, according to the above configuration, the optimum overshoot signal corresponding to each liquid crystal panel is obtained by actually performing trial drive (trial OS drive) on the liquid crystal panel to be evaluated and evaluating its display characteristics. It is possible to find and store the level directly.

  That is, the provisional overshoot signal level is determined from the normal drive waveform and the like, and the OS is driven based on the determined level, compared with the conventional evaluation apparatus that checks and corrects the provisional overshoot signal. In addition to simplifying the evaluation process, it is possible to easily obtain an optimal overshoot signal level with high accuracy and little influence of panel characteristics and detection errors.

  Further, the evaluation apparatus for the liquid crystal display device includes an optical light receiving element provided in the display detection unit, and a waveform analysis device provided in the analysis unit, to which an output from the optical light receiving element is input, The waveform analysis apparatus has a relationship between a maximum or minimum level and a level corresponding to the arrival gradation, and the arrival floor for each output waveform from the optical light receiving element input corresponding to each trial drive. Analyze the time required to reach the level corresponding to the key, and based on the result, store the level of the overshoot signal corresponding to the optimum output waveform in association with the original gradation and the reached gradation It is preferable that it is comprised.

  In the above configuration, the display corresponding to each overshoot signal (level) is displayed on the liquid crystal panel to be evaluated, and each display is detected by the optical light receiving element, and the detection result (output) of this optical light receiving element is the waveform. Input to the analyzer. In the waveform analysis apparatus, the relationship between the maximum or minimum level and the level corresponding to the arrival gradation, and the arrival floor for the output waveform of the optical light receiving element input corresponding to each overshoot signal. The time required to reach the level corresponding to the key is analyzed, and the optimum output waveform is found.

  For example, in the case of gradation response of gradation A <gradation B, the optimum output waveform is such that the maximum level reaches the level corresponding to the arrival gradation the fastest without exceeding the level corresponding to the arrival gradation. The overshoot signal level corresponding to the optimum output waveform may be set as the optimum overshoot signal level. In the case of a decay response of gradation A> gradation B, an output waveform that reaches the level corresponding to the arrival gradation the fastest without the minimum level falling below the level corresponding to the arrival gradation is optimized. The overshoot signal level corresponding to the optimum output waveform may be set as the optimum overshoot signal level. Thus, according to the above configuration, the optimum overshoot signal (level) can be found more easily.

  In the evaluation apparatus for the liquid crystal display device, the video signal generation circuit provided in the signal unit corresponds to the original gradation for the liquid crystal panel so as to perform the trial drive over a plurality of field periods. Then, for each field period, an overshoot signal to be given to the field period is given, and then a test drive over a plurality of field periods is given to each of the field periods. Each output waveform from the optical light receiving element is configured to be performed while sweeping the level of the power overshoot signal, and the waveform analysis apparatus is input in response to the trial drive over the plurality of field periods. On the other hand, the relationship between the maximum or minimum level and the level corresponding to the reached gradation, and the level corresponding to the reached gradation Analyze required time to reach, and based on the result, store the level of overshoot signal in each field period corresponding to the optimum output waveform in association with the original gradation and the reached gradation It may be configured.

  First, in the OS drive that provides an overshoot signal of a plurality of levels over a plurality of field periods, for example, a gradation change that cannot be appropriately overshooted by one level of overshoot signal applied in one field period. This is effective for (a combination of gradation A and gradation B).

  In the above configuration, the video signal generation circuit gives a signal corresponding to the original gradation (A) to the liquid crystal panel, then gives an overshoot signal to be given to the field period for each field period, and then arrives. The trial drive (trial OS drive) over a series of a plurality of field periods giving a signal corresponding to the gradation (B) is performed by varying (sweeping) the level of the overshoot signal to be given for each field period. (I.e., various combinations of overshoot signals to be given in each field period).

  According to the above configuration, different levels of overshoot signals can be given to the liquid crystal panel during a plurality of field periods. For example, with one level of overshoot signal given during one field period as described above, appropriate OS driving is performed. Even in the case where it is not possible to perform this, it is possible to easily obtain an optimal combination of a plurality of overshoot signals that can be appropriately performed.

  In order to solve the above problems, an evaluation apparatus for a liquid crystal display device according to the present invention includes a video signal generation circuit that provides a signal to a target liquid crystal panel, an optical light receiving element that detects display on the liquid crystal panel, and the optical A waveform analysis device to which an output from the light receiving element is input, and the video signal generation circuit supplies a signal corresponding to the original gradation to the liquid crystal panel, and then performs a trial drive for providing an overshoot signal. The waveform analysis device is configured to sweep the level of the shoot signal, and the waveform analysis device has a maximum or minimum level for each output waveform from the optical light receiving element input corresponding to each test drive. Based on the result of analyzing the relationship with the level corresponding to the desired arrival gradation and the time required to reach the level corresponding to the desired arrival gradation. It is characterized in that the level of the overshoot signal corresponding to the optimum output waveform is configured to continue to store in association with the original tone and reached gradation.

  As in the above-described configuration, at the time of trial driving (trial OS driving), a signal corresponding to the final gradation is not given last, and each output waveform from the optical light receiving element input corresponding to each trial driving is applied. It is also possible to analyze the time required to reach the level corresponding to the desired arrival gradation and store the optimum level of the overshoot signal based on the result.

  According to the above configuration, it is possible to easily obtain the optimum level of the overshoot signal, particularly with respect to the gradation change that does not easily reach the level corresponding to the reached gradation.

  Further, in order to solve the above problems, the liquid crystal display device evaluation method of the present invention includes a signal corresponding to the original gradation, an arbitrary overshoot signal, and a signal corresponding to the arrival gradation on the liquid crystal panel to be evaluated. Are sequentially applied in this order to analyze the display result of the liquid crystal panel while the level of the arbitrary overshoot signal is swept, and based on the result of the analysis, the optimum analysis result is handled. And storing the level of the overshoot signal in association with the original gradation and the reached gradation.

  According to the above method, an overshoot signal is actually given to the liquid crystal panel to be evaluated (trial OS drive is performed), and the display characteristics are evaluated, so that the optimal overshoot signal level corresponding to each liquid crystal panel is obtained. In other words, you can find and store directly.

  That is, the provisional overshoot signal level is determined from the normal drive waveform, and the OS is driven based on the determined level, compared with the conventional evaluation method in which the provisional overshoot signal is confirmed and corrected. In addition to simplifying the process, it is possible to easily obtain (store) an optimum level of an overshoot signal with high accuracy and little influence of panel characteristics and detection errors.

  The liquid crystal display device of the present invention is a liquid crystal display device including a liquid crystal panel and an overshoot drive circuit, and the overshoot signal level stored as an optimum look-up table is stored in the overshoot drive circuit. The optimum overshoot signal level is obtained by sequentially providing the liquid crystal panel with a signal corresponding to the original gradation, an arbitrary overshoot signal, and a signal corresponding to the reached gradation in this order. The step of analyzing the result is repeated while sweeping the level of the arbitrary overshoot signal, and the optimum level of the overshoot signal is determined in association with the original gradation and the reached gradation based on the analysis result. It is obtained by various evaluation methods.

  The overshoot drive circuit using the optimum overshoot signal (level) obtained by the evaluation process as a look-up table (LUT) provides the liquid crystal panel with an optimum signal (overshoot signal) showing response characteristics without excess or deficiency. Can be applied. That is, in the liquid crystal display device provided with the overshoot drive circuit, display quality with excellent response characteristics and no video failure is realized.

  In order to solve the above problems, a liquid crystal display evaluation apparatus according to the present invention includes a signal unit that provides a signal to a liquid crystal panel to be evaluated, a display detection unit that detects display on the liquid crystal panel, and the display detection unit. An analysis unit that analyzes a detection result of the unit, and the signal unit provides a signal corresponding to the original gradation to the liquid crystal panel, and then according to a transition of the gradation from the original gradation to the reached gradation The test unit for overshooting or the test drive for providing both the overshooting test signal and the undershooting test signal is performed while sweeping the level of the test signal. Analyze each detection result from the display detection unit obtained by the trial drive, and based on the result, associate the test signal level corresponding to the optimum detection result with the original gradation and the reached gradation. It is characterized by being configured to continue to store Te.

  First, the undershoot test signal is a signal having a level equal to or lower than the level of the signal corresponding to the arrival gradation (B) (in the case of the rise response of the original gradation A <arrival gradation B), or the arrival level. A signal having a level equal to or higher than the level of the signal corresponding to the gradation (B) (in the case of the decay response of the original gradation A> the reached gradation B).

  In the above configuration, the signal unit performs a trial drive on the liquid crystal panel as follows. That is, after giving a signal corresponding to the original gradation (A), an overshoot test signal or an overshoot test signal and an undershoot test according to the gradation transition from the original gradation to the reached gradation Both the signal and the signal are applied by changing (sweeping) the level of the test signal for overshoot and the level of the test signal for undershoot.

  As a result, a display corresponding to each test signal (level) is made on the liquid crystal panel to be evaluated, and the display detection unit detects each display. Then, an optimum display result when the original gradation is A and the arrival gradation is B is searched, and the level of the test signal corresponding to the optimum detection result is the original gradation A and the arrival gradation. Stored in association with B.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, the signal section is configured to give a test signal for overshoot consisting of a plurality of levels to the liquid crystal panel for a predetermined gradation transition. The analysis unit is configured to store a combination of the plurality of levels in the test signal for overshoot corresponding to the optimum detection result in association with the original gradation and the reached gradation. Is preferred.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, the signal unit outputs a test signal for undershoot consisting of at least one level after giving a signal corresponding to the original gradation for a predetermined gradation transition. Next, an overshoot test signal composed of at least one level is provided to the liquid crystal panel, and the analysis unit is configured to provide an undershoot test signal corresponding to an optimum detection result. It is preferable that the level of the test signal for overshoot and the level of the test signal for overshoot are stored in association with the original gradation and the arrival gradation.

  In the evaluation apparatus for a liquid crystal display device of the present invention, the signal section may be configured to give one level in the test signal to the liquid crystal panel for one field period.

  Further, in the liquid crystal display evaluation apparatus of the present invention, an optical light receiving element provided in the display detection unit, a waveform analysis device provided in the analysis unit, to which an output waveform from the optical light receiving element is input, The waveform analysis device has a relationship between a maximum or minimum level and a level corresponding to the reached gradation for each output waveform from the optical light receiving element input corresponding to each trial drive, and Analyze the time required to reach the level corresponding to the arrival gradation, and based on the result, store the test signal level corresponding to the optimum output waveform in association with the original gradation and the arrival gradation. It is preferable to be configured so as to follow.

  In order to solve the above-described problem, the liquid crystal display device evaluation method of the present invention provides a signal corresponding to the original gradation to the liquid crystal panel to be evaluated, and then changes from the original gradation to the reached gradation. The level of the test signal is swept in the process of analyzing the display result by giving both the overshoot test signal or both the overshoot test signal and the undershoot test signal according to the gradation transition of The test signal level corresponding to the result of the optimal analysis is stored in association with the original gradation and the reached gradation.

  In order to solve the above problems, the liquid crystal display device of the present invention is a liquid crystal display device including a liquid crystal panel and a drive circuit, and the drive circuit includes a step from the original gradation to the reached gradation. The optimum level of the overshoot signal or the combination of the overshoot signal and the undershoot signal is stored as a look-up table according to the transition of the key. As a determination method, after giving a signal corresponding to the original gradation to the liquid crystal panel, an overshoot test signal or an overshoot test signal and an undershoot test signal according to the gradation transition, The test signal corresponding to the optimum display result is repeated by sweeping the level of the test signal and repeating the process of analyzing the display result by giving both It is characterized by being used a method of the above optimum level level.

  In the liquid crystal display device of the present invention, the drive circuit stores an optimum combination of a plurality of signal levels as a lookup table as an optimum level of the overshoot signal for a predetermined gradation transition. As a method for determining the optimum combination, an overshoot test signal having a plurality of signal levels is given to the liquid crystal panel after giving a signal corresponding to the original gradation, and the display result is analyzed. It is preferable to use a method in which the step of performing is repeated while sweeping the levels of the plurality of signals, and the combination of the plurality of signal levels corresponding to the optimum display result is set to the optimum combination.

  In the liquid crystal display device of the present invention, the drive circuit stores an optimum combination of the overshoot signal level and the undershoot signal level as a look-up table for a predetermined gradation transition. As a method of determining the optimum combination, after giving a signal corresponding to the original gradation to the liquid crystal panel, an undershoot test signal and an overshoot test signal are sequentially given in this order. The process of analyzing the display result is repeated while sweeping the level of each test signal, and a method is used in which the combination of the levels of each test signal corresponding to the optimal display result is the optimal combination. Is preferred.

  In the liquid crystal display device of the present invention, it is preferable that the optimum display result is that the display almost equal to the reached gradation is obtained most quickly without exceeding the reached gradation.

  In the liquid crystal display device of the present invention, it is preferable that the lookup table is stored corresponding to each of a plurality of temperatures.

  According to the above configuration, the optimum lookup table can be referred to according to the temperature obtained by the temperature sensor provided in the liquid crystal panel, for example. As a result, in the liquid crystal display device, high display quality is realized without being influenced by the ambient temperature during driving.

  It should be noted that each of the above-described configurations or methods according to the present invention can be arbitrarily combined with other configurations or methods according to the present invention as necessary.

  As described above, the evaluation apparatus for the liquid crystal display device of the present invention, when performing the overshoot drive for improving the response of the liquid crystal, first determines the optimal overshoot parameter from the video signal generation circuit, When an arbitrary gradation before changing the gradation is A, an arbitrary gradation to be reached is B, and an overshoot signal level is C, the overshoot level C is swept while A → C → A video signal whose level changes in the order of B is sequentially output, and then a liquid crystal panel display image based on each video signal is photoelectrically converted by an optical light receiving element, and the waveform analyzer then sweeps various overshoots. In the display result of the liquid crystal panel by the video signal of level C, the level that has reached the fastest reaching gradation B without the excessive response is determined as the optimum overshoot. As a parameter, it slides into the store in association with the tone A and reached gradation B before the change.

  Therefore, the optimum overshoot parameter can be obtained easily and with high accuracy. In addition, it is possible to perform measurement using an overshoot signal even for a liquid crystal panel that is not overshoot driven. Although two operations of determining the shoot parameter are necessary, in the present invention, the parameter for overshoot drive can be obtained even when the circuit is not completed, that is, even when overshoot drive is not possible.

  Further, as described above, in the liquid crystal display evaluation apparatus of the present invention, the video signal generation circuit is configured so that the level of the overshoot signal is C1, C2,..., Cn (n is an arbitrary integer greater than or equal to 1) in order. In this case, while the overshoot levels C1 to Cn are respectively swept, video signals whose levels change in the order of A → C1 to Cn → B are sequentially applied to the liquid crystal panel, and the waveform analysis apparatus is configured to apply the overshoot level C1. In the response waveform in which .about.Cn is swept, the level that has reached the arrival gradation B fastest without excessive response is stored in association with the gradation A and the arrival gradation B before the change.

  Therefore, the overshoot drive can be performed over n field periods, and the application range can be expanded.

  Furthermore, as described above, the evaluation apparatus for a liquid crystal display device according to the present invention is provided with a thermostatic bath and accommodates at least the liquid crystal panel.

  Therefore, the liquid crystal panel can be evaluated under a certain temperature condition. In addition, the liquid crystal panel can be evaluated at various environmental temperatures, and an optimal overshoot parameter can be obtained for each temperature. Furthermore, when a window is provided in the thermostatic chamber, an abnormality at the time of evaluation can be quickly found, and measures can be easily taken.

  In the evaluation apparatus for a liquid crystal display device according to the present invention, as described above, the video signal generation circuit is provided corresponding to each of the gradation A before arrival, the arrival gradation B, and the overshoot level C. A switch is provided, and the switch is digitally turned on / off to sequentially output a voltage corresponding to the switching mode as the video signal.

  Therefore, the gradation A before reaching the change, the reaching gradation B, and the overshoot level C can be arbitrarily and independently digitally adjusted by setting the switch. The switch is preferably a multi-bit switch. In this case, the overshoot level C can be set in detail in switching between arbitrary gradations.

  Furthermore, in the liquid crystal display evaluation apparatus according to the present invention, the switch for adjusting the overshoot level C is composed of two types of switches for coarse adjustment and fine adjustment as described above.

  Therefore, accurate evaluation can be performed in a short time.

  In the evaluation apparatus for a liquid crystal display device of the present invention, as described above, the video signal generation circuit corresponds to each of the gradation A before reaching the change, the arrival gradation B, and the overshoot levels C1 to Cn. A switch is provided, and the switch is digitally turned on / off to sequentially output a voltage corresponding to a switching mode as the video signal.

  Therefore, each of the n (multiple) field overshoot levels C1 to Cn can be digitally adjusted arbitrarily and independently by setting the switch. The switch is preferably a multi-bit switch. In this case, overshoot levels C1 to Cn can be set in detail in switching between arbitrary gradations.

  Furthermore, as described above, the evaluation apparatus for a liquid crystal display device according to the present invention comprises two types of switches for adjusting the overshoot levels C1 to Cn, one for coarse adjustment and one for fine adjustment.

  Therefore, the multi-field overshoot levels C1 to Cn can be accurately evaluated in a short time.

  In addition, as described above, the evaluation apparatus for the liquid crystal display device according to the present invention has C1 to Cn as to B ≦ C1 ≧ C2 ≧ for arbitrary gradations A and B in the case of a rise response where A <B. ... ≧ Cn, and an arbitrary k-th overshoot level Ck (an integer of 1 ≦ k ≦ n) is the maximum at which the response waveform by the overshoot level Ck does not excessively respond to the level of the reached gradation B If the response waveform based on the overshoot level Ck is substantially equal to the level of the reached gradation B, it is determined that Ck + 1 to Cn = B.

  Therefore, it is possible to determine the optimum overshoot parameter in each field in the multi-field overshoot drive in which the initial overshoot level C1 is maximized by the rise response.

  Furthermore, as described above, the evaluation apparatus for a liquid crystal display device according to the present invention is configured such that C1 to Cn are set to B ≧ C1 ≦ C2 for arbitrary gradations A and B in the case of a decay response where A> B. ≦... ≦ Cn and an arbitrary kth overshoot level Ck (integer of 1 ≦ k ≦ n) does not excessively respond to the level of the reached gradation B with the response waveform by the overshoot level Ck If the response waveform based on the overshoot level Ck is approximately equal to the level of the reached gradation B, it is determined that Ck + 1 to Cn = B.

  Therefore, it is possible to determine the optimum overshoot parameter in each field in the multi-field overshoot drive in which the initial overshoot level C1 is the largest by the decay response.

  Further, as described above, the evaluation apparatus for the liquid crystal display device according to the present invention sets C1 to Cn to arbitrary gradations A and B with A <C1 ≦. Ck <B ≦ Ck + 1 ≧. Cj + 1 to Cn = If the response waveform according to is determined to be the maximum value that does not excessively respond to the level of the reached gradation B and the response waveform due to the overshoot level Cj is substantially equal to the level of the reached gradation B B is determined.

  Therefore, after the rise response, the overshoot levels C1 to Ck are intentionally set to be weak undershoot levels in the 1st to 1st fields, and the liquid crystal is made to respond a little. Then, in the subsequent k + 1 to nth fields, In the driving method in which the shoot levels Ck + 1 to Cn are set to the original overshoot level, the overshoot parameter can be accurately determined.

  Furthermore, as described above, in the evaluation apparatus for the liquid crystal display device of the present invention, in the case of a decay response where A> B, C1 to Cn are set to A> C1 ≧. ≧ Ck> B ≧ Ck + 1 ≦. If the response waveform by Cj is determined to be the minimum value that does not excessively respond to the level of the reached gradation B, and the response waveform by the overshoot level Cj is substantially equal to the level of the reached gradation B, Cj + 1 to Cn = B.

  Therefore, in the decay response, in the first to k-th fields, the overshoot levels C1 to Ck are intentionally set to be weak undershoot levels, and the liquid crystal is made to respond slightly. Then, in the subsequent k + 1 to n-th fields, In the driving method in which the shoot levels Ck + 1 to Cn are set to the original overshoot level, the overshoot parameter can be accurately determined.

  Further, as described above, the evaluation apparatus for the liquid crystal display device according to the present invention, in the case of the rise response where A <B, C1 to Cn for any gradations A and B, B ≦ C1 = C2 = ... = Cn, and an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is obtained with respect to the level at which the response waveform of all overshoot levels C1 to Cn reaches the final gradation B Determine the maximum value that does not cause excessive response.

  Therefore, it is possible to determine an overshoot parameter in the case of a rise response in which the same overshoot signal is applied to all n fields.

  Furthermore, as described above, in the evaluation apparatus for the liquid crystal display device of the present invention, in the case of a decay response in which A> B, C1 to Cn are set to B ≧ C1 = C2 for arbitrary gradations A and B. = ... = Cn and an arbitrary k-th (an integer of 1 ≦ k ≦ n) overshoot level Ck is obtained with respect to the level of the arrival gradation B in which the response waveforms of all overshoot levels C1 to Cn are Determine the minimum value that does not cause excessive response.

  Therefore, the overshoot parameter in the case of a decay response in which the same overshoot signal is applied to all n fields can be determined.

  Further, as described above, the liquid crystal display device of the present invention stores the overshoot level C determined by the evaluation device in the drive circuit as a look-up table for overshoot drive.

  Therefore, since the drive circuit has a look-up table composed of overshoot parameters optimal for the liquid crystal panel to be used, it is possible to realize a liquid crystal display device capable of high-speed response and causing no video failure. it can.

  Furthermore, as described above, the liquid crystal display device of the present invention stores the overshoot levels C1 to Cn determined by the evaluation device in the drive circuit as a look-up table for overshoot driving.

  Therefore, when performing overshoot drive over multiple fields, the drive circuit has a look-up table composed of overshoot parameters optimal for the liquid crystal panel to be used, so that high-speed response is possible and video images are displayed. A liquid crystal display device that does not fail can be realized.

  In addition, as described above, the liquid crystal display evaluation method of the present invention, when performing the overshoot drive for improving the response of the liquid crystal, first changes the gradation in determining the optimum overshoot level. Arbitrary gradation before the operation is A, arbitrary gradation to be reached is B, and overshoot signal level is C, while overshoot level C is swept in order of A → C → B. Video signals with varying levels are sequentially output and displayed on the liquid crystal panel. Next, along with the output, the display image is read and the waveform analysis is sequentially performed. The reached level is stored as the optimum overshoot level in association with the gradation A and the arrival gradation B before the change.

  Therefore, the optimum overshoot parameter can be obtained easily and with high accuracy. In addition, it is possible to perform measurement using an overshoot signal even for a liquid crystal panel that is not overshoot driven, and when the overshoot drive is introduced to the panel later, circuit design and OS Although the two operations of determining the parameter are necessary, the present invention can determine the parameter for overshoot driving even when the circuit is not completed, that is, even when overshoot driving is not possible.

  Furthermore, in the evaluation method of the liquid crystal display device of the present invention, as described above, the overshoot drive is performed over an n field period, and the video signal generation circuit determines the level of the overshoot signal over the n field period, When C1, C2,..., Cn (n is an arbitrary integer greater than or equal to 1) in order, video signals whose levels change in the order of A → C1 to Cn → B while sweeping overshoot levels C1 to Cn, respectively. Are sequentially applied to the liquid crystal panel.

  Therefore, the overshoot parameter corresponding to the overshoot drive over many fields can be determined accurately and simply.

  In addition, as described above, the evaluation apparatus for a liquid crystal display device according to the present invention includes a signal unit that gives a signal to a liquid crystal panel to be evaluated, a display detection unit that detects display of the liquid crystal panel, and the display detection unit. An analysis unit for analyzing the detection result, and the signal unit gives a signal corresponding to the original gradation (A) to the liquid crystal panel, then gives an overshoot signal, and then corresponds to the arrival gradation. The test drive is applied while sweeping the level of the overshoot signal, and the analysis unit analyzes each detection result from the display detection unit obtained by the test drive, and based on the result The overshoot signal level corresponding to the optimum detection result is stored in association with the original gradation and the reached gradation.

  In other words, by actually performing trial drive (trial OS drive) on the liquid crystal panel to be evaluated and evaluating the display characteristics, the optimum overshoot signal level corresponding to each liquid crystal panel can be found directly. , You can store.

  Therefore, a temporary overshoot signal level is determined from a normal drive waveform, and the OS is driven based on the determined level, compared with a conventional evaluation apparatus that checks and corrects the temporary overshoot signal. In addition to simplifying the evaluation process, it is possible to easily obtain an optimal overshoot signal level with high accuracy and little influence of panel characteristics and detection errors.

It is a figure which shows the whole structure of the evaluation apparatus of one Embodiment of this invention. It is a block diagram which shows the example of 1 structure of the video signal generation circuit in the evaluation apparatus shown in FIG. It is a flowchart for demonstrating the production | generation operation | movement of the video signal for 1 field overshoot drive. It is a figure which shows the mode of a scroll when overshoot drive is performed using appropriate LUT. It is an example of the scroll pattern for confirming the effect of an overshoot drive. It is a figure which shows the mode of a scroll when not performing overshoot drive. It is a wave form diagram which shows an example of the signal for performing switching by 3 field overshoot drive. It is a wave form diagram which shows the other example of the signal for performing switching by 3 field overshoot drive. (A) is a graph showing the response time from the 0 gradation to the target gradation (near 255 gradations) in normal driving, and (b) is the response time from 0 to 255 gradations and for undershooting It is a graph which shows the relationship with the signal level of. It is a wave form diagram which shows the further another example of the signal for performing switching by 3 field overshoot drive. It is a flowchart for demonstrating the production | generation operation | movement of the video signal for multifield overshoot drive. It is a wave form diagram which shows the example of the signal for performing switching by 1 field overshoot drive. It is an optical response waveform due to switching of the liquid crystal panel when overshoot driving is performed with an appropriate overshoot signal. It is an optical response waveform by switching of the liquid crystal panel when overshoot driving is performed with an excessive overshoot signal. It is an optical response waveform due to switching of the liquid crystal panel when overshoot driving is performed with a weak overshoot signal. It is an optical response waveform by switching of the liquid crystal panel when overshoot driving is not performed.

An embodiment of the present invention will be described below with reference to FIGS. 1 to 6 and FIGS. 12 to 16.

  FIG. 1 is a diagram showing an overall configuration of an evaluation apparatus 1 according to an embodiment of the present invention. The evaluation apparatus 1 includes a video signal generation circuit 3 (signal unit) that supplies a video signal by OS driving to a liquid crystal panel 2 to be evaluated, and an optical light receiving element 4 (display detection unit) that faces the display unit of the liquid crystal panel 2. A waveform analysis device 5 (analysis unit) to which an output from the optical light receiving element 4 is inputted, a thermostatic chamber 6, and a control device (not shown) are configured.

  As shown by reference numeral 6, the control device sets the gradation (original gradation) before changing the gradation to A and the gradation to be reached (arrival gradation) as indicated by reference numeral 6. When B is set and the level of the OS signal (overshoot signal, test signal for overshoot) is C (however, including C = B), the OS signal level C (level of the overshoot signal) is swept, A video signal whose level changes in the order of A → C → B is sequentially output to the liquid crystal panel 2 (trial drive, trial OS drive), and is photoelectrically converted by the optical light receiving element 4 and analyzed by the waveform analyzer 5. In the response waveform (each detection result from the display detection unit), there is no excessive response, and the level that has reached the arrival gradation B fastest is associated with the gradation A and the arrival gradation B before the change. , OS parameter C (optimum Level overshoot signal corresponding to the output waveform, an optimal detection slide into stored in LUT as a level) of the test signal corresponding to the (display) result (lookup table). By using the LUT, the drive circuit (overshoot drive circuit) of the liquid crystal display device 7 on which the liquid crystal panel 2 is mounted performs the OS drive of the liquid crystal panel 2, thereby enabling appropriate OS drive. The manufacturer performs such evaluation for each model of the liquid crystal panel 2 and determines the OS parameter C.

  If the liquid crystal panel 2 is not subjected to signal conversion in the middle of a controller or the like, it does not depend on whether the controller is equipped with an OS control function or not, and the total number of models to which OS drive is actually applied is not limited. Can be evaluated. That is, when a video signal is input from the video signal generation circuit 3 to the liquid crystal panel 2, it is necessary to use an input method that allows the liquid crystal panel 2 to output a correct gradation for the signal. For example, when a video signal is input from a video input terminal, the video signal input in the gradation range of 0 to 255 is converted into a gradation range of 16 to 235 by the controller, and is correct for the liquid crystal panel 2. Signals are not input with gradation.

  Therefore, first, when the liquid crystal panel 2 has a digital input (in this case, a DVI equipped in a recent liquid crystal panel is taken as an example), the video signal generating circuit 3 has a DVI output, and the video signal generating circuit 3 The cable 8 for inputting the video signal to the liquid crystal panel 2 may be a DVI cable.

  On the other hand, when the liquid crystal panel 2 does not have the digital input, it is inappropriate to input from the video input terminal as described above, so the video signal from the video signal generating circuit 3 is sent to the source driver of the liquid crystal panel 2. Think about how to enter directly. For example, the controller and the source driver connected by the flexible board are separated, and the video signal generation circuit 3 is sandwiched between them via the flexible board. More specifically, the signal from the controller is taken into the video signal generation circuit 3 as a clock, and the video signal from the video signal generation circuit 3 is directly input to the source driver.

  The waveform analysis device 5 is for capturing and analyzing the response waveform of the liquid crystal panel 2 from the optical light receiving element 4, and generally uses an oscilloscope. The response waveform may be directly captured.

  The thermostatic chamber 6 can accommodate at least the liquid crystal display device 7, and as shown in FIG. 1, the optical light receiving element 4 may be installed together with the liquid crystal panel 2, or the liquid crystal panel 2 is installed in the thermostatic chamber 6. In addition, a window 9 is provided in the thermostatic chamber 6 so that the display unit of the liquid crystal panel can be observed from the outside, and the optical light receiving element 4 is provided in the window 9 to observe the display result. It may be. The temperature chamber 6 is temperature-controlled in the range of, for example, 0 to 60 ° C. required for the evaluation of the liquid crystal panel 2 by the control device or the like.

  By providing this thermostatic bath 6, the liquid crystal panel 2 can be evaluated under a constant temperature condition. Further, the liquid crystal panel 2 can be evaluated at various environmental temperatures, and the OS parameter C optimum for each temperature can be obtained. Therefore, detailed OS control is performed in which a LUT corresponding to several temperatures is prepared in the drive circuit of the liquid crystal panel 2 and a temperature sensor is provided in the liquid crystal panel 2 to change the reference LUT according to the detection result. It can be carried out.

  Furthermore, when the temperature of the thermostatic chamber 6 is greatly changed, a severe temperature cycle is applied, and a large burden is generated on each part of the liquid crystal panel 2, and on this occasion, a lighting abnormality may occur in rare cases. For this reason, by providing the window 9 in the thermostatic chamber 6, the measurer can quickly find such an abnormality, and measures can be easily taken.

  In FIG. 1, the video signal generation circuit 3, the waveform analysis device 5, and the control device are installed outside the thermostatic chamber 6, and can be operated by a measurer. However, they may be installed inside the thermostat 6 and the switch operation may be performed from the outside of the thermostat 6 with a remote controller or the like.

  FIG. 2 is a block diagram showing a configuration example of the video signal generation circuit 3. The video signal generation circuit 3 includes an OS signal generation unit 11, a clock signal input unit 12, a switch unit 13, and a signal output unit 14. The OS signal generation unit 11 generates a video signal in response to a clock signal from the clock signal input unit 12 according to the signal levels A, B, and C set by the switch unit 13. That is, the OS signal generation unit 11 creates a video signal at 60 Hz when a 60 Hz signal such as NTSC is input to the vertical scanning frequency, and a video signal at 50 Hz when a 50 Hz signal such as PAL is input. Create The switch unit 13 includes three systems of switches for independently controlling the levels A, B, and C of the video signal as will be described later. By switching the switches digitally on / off, the switching mode is set. Are sequentially output as the video signal. The video signal generated by the OS signal generation unit 11 is given from the signal output unit 14 to the liquid crystal panel 2 via the connection cable 8.

  The switch unit 13 for inputting parameters necessary for determining the OS signal level may be realized by a personal computer or the like, and may be substituted by an input from a control device that controls the entire evaluation apparatus 1. When the video signal is composed of the three signal levels A, B, and C as shown in FIG. 12, the switch unit 13 is composed of the three systems of switches, for example, the finest OS signal level C. When the system to be set represents 8 bits, and therefore represents 256 gradations, the system of gradation A before the gradation change and gradation B to be reached is 4 bits, so gradation switching can be performed every 16 gradations. It has become.

  It is ideal to set the OS signal level in detail in switching between arbitrary gradations, and it is desirable that the LUT is set for each switching gradation. This is because, when incorporated in the drive circuit, due to the cost of the IC and memory, there is often a restriction that a very large IC or a huge memory cannot be used and an operation program or LUT cannot be made too large. Therefore, the actual LUT can be set only for every 16 gradations for each of A and B as described above, and the interval is calculated by the interpolation algorithm. Of course, if the restrictions on the IC and memory are relaxed, an LUT in which A and B are set for each gradation may be used. Therefore, it is desirable that the arbitrary gradations A and B are switched at least every 16 gradations, preferably every gradation. On the other hand, the OS signal level C is changed by one gradation. Since the effect is different, switching for each gradation is necessary, and the number of bits of the switches of each system is selected as described above.

  In this way, the three signal levels A, B, and C can be adjusted by independent switches, so that the necessary OS signal level C can be easily reduced without increasing the number of switches for the gradations A and B. And it becomes possible to set in detail.

  Furthermore, each system switch is composed of two types of switches for coarse adjustment and fine adjustment. For example, as a very simple example, the OS signal level C as a whole is set to 8 bits, and the upper 4 bits and the lower 4 bits can be operated independently by separate switches. First, the upper 4 bits are turned on / off. By switching, the approximate size of the OS signal level C is estimated (coarse adjustment), and then the detailed OS signal level C is determined (fine adjustment) by switching on / off the lower 4 bits. Therefore, for example, 256 OS signal levels C as described above can be determined with high accuracy in a short time.

Further, the time for applying the OS signal level C needs to match the specification of the actual OS drive circuit. For example, in a drive circuit with 60 Hz drive such as the NTSC, one field is 16 msec. The time is 16 msec. As will be described later, when an OS signal is applied across a plurality of fields, the OS signal application time is:
(Number of fields to which OS signal is input) × (16 msec)
It is represented by Similarly, in a drive circuit with 50 Hz drive such as PAL, since one field is 20 msec, the OS signal application time is
(Number of fields to which OS signal is input) × (20 msec)
It is represented by

  In addition, when using a special drive circuit such as a double speed drive for doubling the frame frequency, the calculation may be performed using one field period corresponding thereto. For these drive frequencies, it is convenient to input video signals such as NTSC and PAL from the outside and use their clocks. In the case of special conditions such as double speed driving, a necessary clock may be created based on the clock of the input video signal. Of course, in all cases, the clock signal input unit 12 may create a clock inside the circuit without relying on an external input, and select the clock with a switch provided in the circuit.

  FIG. 3 is a flowchart for explaining the video signal creation operation as shown in FIG. In each of steps S1 to S3, a signal level is set from each system switch corresponding to the three signal levels A, B, and C. In step S4, a clock signal is taken in from the clock signal input unit 12, and in step S5, in response to the clock signal, the level set by the switches of each system and in the order of A → C → B. A video signal whose level changes is output. The signal of gradation A before the change is output for a predetermined period, the signal of OS signal level C is output for one field period, and the signal of arrival gradation B is output for a predetermined period. In step S6, these signals are output from the signal output unit 14 to the liquid crystal panel 2.

  In the display area of a part or the whole of the liquid crystal panel 2 (a part of the display area is shown as indicated by reference numeral 10 in FIG. 1), display by the video signal is performed, and the display result is optically displayed. When taken in by the light receiving element 4 and analyzed by the waveform analysis device 5, the processing of steps S1 to S6 is repeated for the other OS signal level C. The analysis result is taken into the control device (not shown), the optimum OS parameter C is determined for each gradation A and B, and an LUT is created.

  The temperature inside the thermostatic chamber 6 is kept at 25 ° C., the optical response waveform of switching of the liquid crystal panel 2 by the video signal shown in FIG. 12 is used as the optical light receiving element 4, and the waveform analyzing apparatus 5 FIG. 13 to FIG. 16 show an example of the results obtained by taking in and analyzing the oscilloscope. 13 to 16, the gradation A before the change is constant at 64 gradations, and the reaching gradation B is constant at 192 gradations.

  First, FIG. 16 shows waveforms when the OS is not driven, that is, when the OS signal level C is the same level as the arrival gradation B. When the OS signal level C is gradually increased from here, a response waveform with slightly weak OS driving is obtained, which is shown in FIG. When the OS signal level C is further increased, a response waveform with sufficient OS driving is obtained, which is shown in FIG. When the OS signal level C is further increased, an angle starts to appear in the response waveform as shown in FIG. At this time, since the response waveform exceeds the reached gradation B, it appears to the human eye to shine white immediately before the target gradation is displayed. Thus, the state immediately before the excessive response, that is, the state shown in FIG. 13 can be determined as the optimum OS signal level.

  Table 1 shows an example of the OS parameter C in an arbitrary gradation A and B determined by the method as described above. By storing the LUT in Table 1 in the controller of the liquid crystal panel 2, optimum OS driving can be performed between any gradations including halftones and halftones.

  Table 2 shows the calculation results of the response waveform arrival rate at the end of the field in which the signal level of the optimum OS parameter C shown in Table 1 is input. As is apparent from Table 2, the arrival rate showed a value close to 100% in almost all gradations, and it was confirmed that a necessary and sufficient OS signal was given.

  Here, as a comparative example, as described in the prior art, the response waveform of the liquid crystal panel 2 is measured by a normal driving method, and the OS signal is applied from the trigger point (for one field in the above example). Table 3 shows LUTs obtained by calculating the tone arrival rate after a predetermined time and calculating the OS parameter C from the result. Similarly to Table 2, OS driving is performed using this LUT, and the arrival rate of the response waveform in the field to which the OS signal is input is calculated from the waveform.

  As apparent from comparison between Table 1 and Table 3 and Table 2 and Table 4, the LUT according to the prior art does not have a sufficient OS signal level as shown in FIG. Is much less than 100%, and the OS signal is excessive as shown in FIG. 14, and many gradations in which the arrival rate of the OS signal application period exceeds 100% are observed. It turned out to be incomplete.

  FIG. 4 shows an example of a display result by OS driving using the LUT according to the present invention. In this example, as the gradation A before the change, a gray scale G that gradually becomes white as it goes from the upper side to the lower side of the screen is displayed, and an arbitrary reaching gradation B having an appropriate width is displayed thereon. The bar is scrolled from left to right with the OS signal C. The scroll bar is a value between the maximum value (white) and the minimum value (black) of the grayscale G gradation level.

  From FIG. 4, even if the background is a gray scale G having an arbitrary gradation, the effect of OS control can be confirmed by maintaining the scroll bar at a constant density. The B, C and G levels can be switched independently by an external circuit. Further, as described above, the reached gradation B can be switched in increments of 16 gradations, and the OS parameter C can be switched in increments of 1 gradation.

  Further, FIG. 5 shows a display result in which the scroll bar is black with the minimum gradation level. As a comparative example, FIG. 6 shows a display result when no OS drive is applied. As can be seen from FIGS. 5 and 6, the tailing phenomenon that becomes noticeable when the response is slow is remarkably alleviated in the image to which the proper OS signal is applied, compared with the case where the OS signal is not applied. It also has a natural appearance. Also, if the OS drive is working correctly, the bar of any gradation will minimize the effect of white spots (or black sun) due to excessive OS and tailing due to lack of OS. The nature can be evaluated to some extent with the patterns shown in FIGS.

  As described above, in the present invention, the optimum OS parameter C can be obtained easily and with high accuracy. In addition, measurement using an OS signal is possible even for a liquid crystal panel that is not OS-driven, and when OS driving is introduced to the panel later, circuit design and OS parameter C Although the two operations of determination are necessary, according to the present invention, the parameter C for driving the OS can be obtained even when the circuit is not completed, that is, even when the OS cannot be driven.

  In the above description, the rise response as shown in FIG. 12, that is, an example of A <B, is shown. However, in the case of a decay response where A> B, for any gradations A and B, The OS signal level C is equal to or lower than the attainment gradation B, and the response waveform is observed by changing C. By searching for the minimum C in which the response waveform does not excessively respond to the B level, an accurate OS is obtained. Parameter C can be determined.

  In the present invention, the response waveform is analyzed by changing the overshoot signal C for the gradation A before the gradation change and the gradation B to be reached, and the response waveform at each overshoot level C is analyzed. Among them, an evaluation method is employed in which the level that has reached the arrival gradation B fastest without excessive response is stored in association with the gradation A and the arrival gradation B before the change. An overshoot drive circuit using an overshoot level C (optimum OS parameter C) obtained by this evaluation method as an LUT can apply an optimum signal showing response characteristics without excess or deficiency to the liquid crystal panel. That is, in the liquid crystal display device (liquid crystal display) provided with the overshoot drive circuit, display quality without video breakdown is realized with excellent response characteristics.

  The following will describe another embodiment of the present invention with reference to FIGS.

  It should be noted in this embodiment that the OS drive is performed by dividing it into n (n is an arbitrary integer of 1 or more), that is, divided into multi-field periods. Such driving is performed when a desired gradation change is difficult in one field, and adjustment is performed toward the final reached gradation B over several frames.

  Here, when the OS signal level with the passage of time is C1, C2,..., Cn in order, in the case of the rise response where A <B, C1 to Cn are given for arbitrary gradations A and B. 7, B ≦ C1 ≧ C2 ≧ ... ≧ Cn and A <C1 ≦ ... ≦ Ck <B ≦ Ck + 1 ≧ ... ≧ Cn (k is 1 ≦ k ≦ n) as shown in FIG. (Integer) and B ≦ C1 = C2 =... = Cn as shown in FIG. In FIG. 7, FIG. 8, FIG. 10 and the following description, n = 3.

  Similarly, in the case of a decay response, for any gradations A and B, C1 to Cn are B ≧ C1 ≦ C2 ≦... ≦ Cn corresponding to FIG. 7 and A corresponding to FIG. > C1≥ ... ≥Ck> B≥Ck + 1≤ ... ≤Cn and B≥C1 = C2 = ... = Cn corresponding to FIG.

  Although it is not desirable from the viewpoint of circuit scale to simultaneously process the one-field OS as shown in FIG. 12 and the multi-field OS as shown in FIGS. When a multi-field OS is selected, this multi-field OS is effective particularly when there are gradation transitions whose parameters change greatly as C1, C2,.

  FIG. 11 is a flowchart for explaining the video signal creation operation as shown in FIGS. In this operation, in the evaluation apparatus 1 shown in FIG. 1, the video signal generation circuit 3 includes switches for individually setting the three OS signal levels C1, C2, and C3, and A → C1 → C2 → C3. → The video signal whose level changes in the order of B is output (trial drive over a plurality of field periods), and the waveform analysis apparatus 5 obtains the OS parameters (the respective output periods corresponding to the optimum output waveform). This can be realized by storing the test signal levels C1, C2 and C3 corresponding to the optimum detection (display) of the overshoot signal level. 3 is similar to the operation of FIG. 2, and corresponding portions are denoted by the same reference numerals, and description thereof is omitted.

  In the present embodiment, the signal levels A and B are set in steps S1 and S2, and the three OS signal levels C1 to C3 are set in steps S31 to S33. In step S50, in response to the clock signal input in step S4, the level changes in the order set by the switches of each system and in the order of A → C1 → C2 → C3 → B. Video signals are output, and these signals are output from the signal output unit 14 to the liquid crystal panel 2 in step S6.

  In this way, the switches for setting the OS signal levels C1 to C3 are also independent between the systems, and each switch is configured with two types of coarse adjustment and fine adjustment, for example, as described above. In the case of 256 gradations in all gradations, the OS signal levels C1 to C3 that need to be switched for each gradation are 256 × n in total, and evaluation by changing this for each gradation takes time. However, accurate measurement is possible in a short time.

  Here, Table 5 shows the LUT of the OS parameter C obtained in one field OS, and consider a method of driving the liquid crystal panel in a multi-field OS.

  First, as shown in FIG. 7, the first OS signal level C1 is the highest, such as B ≦ C1 ≧ C2 ≧ ... ≧ Cn in the case of a rise response, and B ≧ C1 ≦ C2 ≦ ... ≦ Cn in the case of a decay response. The driving that is large and then gradually decreases is effective when the response is not completed by one field OS at a low temperature or the like, and the shaded portion in the LUT of Table 5 is suitable for this driving method. For example, when considering a gradation transition from 192 to 32 with a decay response, up to 32 gradations cannot be reached with only one field of OS driving, so in a multi-field OS, 0 is given as C1, and the liquid crystal is maximized. Then, as C2, a value that gives the transition closest to 32 is searched, and although not shown, 32 is reached at 8 from the reached gradation at C1. In this case, the number after C3 is 32, and C3 = B. That is, B (32)> C1 (0) <C2 (8) <C3 (32) = ... = B (32). In the case of a rise response, the reverse is true (however, the rise response has good responsiveness. In 32 → 192, if C1 = 244, C2 = C3 =... = B = 192, so 0 → 255, 224, etc.).

  Next, as shown in FIG. 8, in the case of a rise response, A <C1 ≦ ... ≦ Ck <B ≦ Ck + 1 ≧ ... ≧ Cn, and in the case of a decay response, A> C1 ≧ ... ≧ Ck> B ≧ Ck + 1 ≦ ... ≦ Like Cn, the OS signal levels C1 to Ck are intentionally weak undershoot levels (undershoot signal level and undershoot test signal level) in the 1st to kth fields, and the liquid crystal is made to respond slightly. Thus, in the subsequent k + 1 to nth fields, the driving of setting the OS signal level (overshoot signal level, overshoot test signal level) Ck + 1 to Cn to the original overshoot level is particularly performed by switching the liquid crystal. This is effective in a region that is difficult to perform, and in the LUT of Table 5, the shaded portion is suitable for this driving method.

  This part of the data is characterized in that the liquid crystal response hardly occurs for some reason, and the OS amount is abnormally large in one field OS. Therefore, if the OS signal is forcibly switched with a large amount of OS or if the OS signal is cut off in the second and subsequent fields, the display gradation level drops greatly, and after a while, the predetermined gradation level is reached again. This LUT is VA type liquid crystal data, and switching from zero gradation, that is, from a state in which liquid crystal molecules are completely vertically aligned, is not limited until the direction in which the liquid crystal is tilted is determined immediately after the switching signal is applied. This is due to the existence of a time lag.

  Here, when considering the gradation transition from 0 to 96, first, 32 is given as C1, whereby the liquid crystal molecules are slightly tilted, and then 200 is given as C2, so that the gradation is changed to 96. Transition is smooth. In addition, since it has reached 96, it becomes 96 after C3, and the OS driving is ended, but the drop of the gradation level seen in the OS driving with only one field is largely eliminated. That is, in the case of the above rise response, A (0) <C1 (32) <B (96) <C2 (200). The decay response is the opposite.

  Here, FIG. 9A shows the time required for the rise response from 0 gradation to a predetermined target gradation (220 gradation to 255 gradation) in normal driving (no OS driving). As shown in the figure, the response time from the 0th gradation to the 255th gradation is the maximum, and the response time from the 0th gradation to the 240th gradation is almost the minimum.

  Therefore, in FIG. 9B, in the rise response to 0 to 255 gradations, A (0 gradation) <U (undershoot signal level) <B (255 gradations), and U is 240 gradations. In the three cases, the case where U is set to 251 gradation, and the case where U is not given (when the signal level corresponding to 255 gradation is directly given without giving the signal for undershoot). Indicates the response status.

  As shown in the figure, when an overshoot signal of 255 gradations is directly given without giving an undershoot signal, or after an undershoot signal of 251 gradations is given, When an overshoot signal is given, a response time far exceeding 50 ms is required. On the other hand, when an overshoot signal of 255 gradations is given after giving an undershoot signal of 240 gradations, a response time shorter than 50 ms can be achieved.

  As described above, when the original gradation is A and the reached gradation is B, normal driving (without OS driving) is performed with the original gradation being A and the reaching gradation being smaller than the parameter gradation Up. A gradation Umin whose response time is almost minimized is found, and this gradation Umin (corresponding to 240 gradations in FIG. 9A) is used as the signal level for undershoot (that is, the original gradation). For the gradation transition of A and the arrival gradation B, the signal corresponding to the original gradation A, the undershoot signal corresponding to the gradation Umin, and the signal corresponding to the arrival gradation B in order. Giving to the liquid crystal panel 2 is also effective.

  Subsequently, as shown in FIG. 10, all the OS signal levels are B ≦ C1 = C2 =... = Cn in the case of the rise response and B ≦ C1 = C2 =... = Cn in the case of the decay response. The equal driving is effective for all the driving including those shown in FIGS. That is, rather than setting different parameters, measurement can be facilitated because all the same parameters can be set.

  As described above, in the case of the rise response where A <B, the OS signal levels C1 to Cn are set to B ≦ C1 ≧ C2 ≧. The k-th OS signal level Ck is determined as the maximum value at which the response waveform due to the OS signal level Ck does not excessively respond to the level of the arrival gradation B, and the response waveform due to the OS signal level Ck is the arrival gradation B Ck + 1 to Cn = B, and in the case of a decay response where A> B, the OS signal levels C1 to Cn are set such that B ≧ C1 ≦ C2 ≦. The arbitrary k-th OS signal level Ck is determined to be the minimum value at which the response waveform due to the OS signal level Ck does not excessively respond to the level of the arrival gradation B, and the response waveform due to the OS signal level Ck arrives. Near to the level of gradation B If this is the case, by determining Ck + 1 to Cn = B, it is possible to realize a multi-field OS in which the initial OS signal level C1 is the largest and gradually decreases thereafter as shown in FIG. This is effective when the response is not completed by the one-field OS at a low temperature or the like.

  In the case of a rise response with A <B, the OS signal levels C1 to Cn are set to A <C1 ≦... ≦ Ck <B ≦ Ck + 1 ≧. An arbitrary jth (k + 1 ≦ j ≦ n) OS signal level Cj is determined to be the maximum value in which the response waveform of the OS signal level Cj does not excessively respond to the level of the reached gradation B, and If the response waveform by the OS signal level Cj is substantially equal to the level of the reached gradation B, it is determined that Cj + 1 to Cn = B. In the case of a decay response in which A> B, the OS signal levels C1 to Cn are set to A > C1 ≧ ... ≧ Ck> B ≧ Ck + 1 ≦ ... ≦ Cn, and an arbitrary j-th OS signal level Cj is over-responsive to the level of the reached gradation B when the response waveform by the OS signal level Cj is The minimum value that is not If the response waveform by the level Cj is substantially equal to the level of the reached gradation B, by determining Cj + 1 to Cn = B, the OS signal level in the 1-kth field as shown in FIG. After allowing the liquid crystal to respond slightly with C1 to Ck as a weak undershoot level on purpose, a multi-field OS is realized in which the OS signal levels Ck + 1 to Cn are the original overshoot levels in the subsequent k + 1 to nth fields. This is effective in a region where the liquid crystal is difficult to switch.

  Furthermore, in the case of a rise response where A <B, the OS signal levels C1 to Cn are set to B ≦ C1 = C2 =... = Cn for any gradations A and B, and any kth The OS signal level Ck is determined to be the maximum value in which the response waveform of all the OS signal levels C1 to Cn does not excessively respond to the level of the reached gradation B, and in the case of a decay response where A> B, the OS signal Levels C1 to Cn are B ≧ C1 = C2 =... = Cn, and any k-th OS signal level Ck is a level at which the response waveform of all the OS signal levels C1 to Cn reaches the reach gradation B By determining the minimum value that does not excessively respond to the above, it is possible to realize a multi-field OS in which all the same parameters are set as shown in FIG.

  Then, by mounting the LUT obtained as described above on the controller of the liquid crystal panel 2, it is possible to realize a liquid crystal display device capable of high-speed response and causing no video failure.

  In the present invention, the level C1, C2,..., Cn of the overshoot signal over the n field period is changed with respect to the gradation A before the gradation change and the gradation B to be reached, and the response waveform thereof. And the combination of C1, C2,..., Cn that has reached the arrival gradation B the fastest in the response waveform by the combination of C1, C2,. An evaluation method of storing in association with A and the reached gradation B is adopted. The overshoot drive circuit that uses the combination of overshoot levels C1, C2,..., Cn (optimum OS parameters C1 to Cn) obtained by this evaluation method as an LUT is an optimum signal that exhibits a response characteristic without excess or deficiency. Can be applied to the liquid crystal panel. That is, in the liquid crystal display device (liquid crystal display) provided with the overshoot drive circuit, display quality without video breakdown is realized with excellent response characteristics.

  In the above description, the reaching gradation B is given, but this reaching gradation B that functions to brake the OS drive is not necessarily given. That is, C = B, and the reached gradation B may not be reached even at the end of the OS drive period when the gradation is particularly large. In such a case, even if the arrival gradation B is not given, An optimal OS signal level can be determined. However, when there is a margin in the gradation change, it is possible to measure with high accuracy by giving this ultimate gradation B that functions to brake the OS drive as described above. Therefore, since the influence of noise is large particularly in a low gradation region and at a low temperature, it is effective to increase the accuracy by giving the reached gradation B.

  Although the present invention aims to perform measurement by OS driving, for example, by incorporating the evaluation apparatus 1 of the present invention into an existing liquid crystal panel evaluation apparatus, conventional evaluation and evaluation by OS driving can be performed. It is possible to create a liquid crystal evaluation apparatus capable of performing both. For example, it can be combined with a device for measuring voltage-luminance characteristics.

  As described above, the evaluation apparatus for a liquid crystal display device of the present invention includes a signal unit that gives a signal to a liquid crystal panel to be evaluated, a display detection unit that detects the display of the liquid crystal panel, and a detection result of the display detection unit. An analysis unit for analyzing, and the signal unit gives a test drive that gives a signal corresponding to the original gradation to the liquid crystal panel, then gives an overshoot signal, and then gives a signal corresponding to the reached gradation The overshoot signal is configured to be performed while sweeping the level of the overshoot signal, and the analysis unit analyzes each detection result from the display detection unit obtained by the trial drive, and an overshoot signal corresponding to the optimum detection result. Are stored in association with the original gradation and the reached gradation.

  The signal unit is configured to sequentially supply overshoot signals of different levels to the liquid crystal panel according to the gradation transition from the original gradation to the reached gradation. Each level of the overshoot signal corresponding to the detection result may be stored in association with the original gradation and the reached gradation.

  The signal unit may be configured to sequentially supply an overshoot signal to the liquid crystal panel so that the level gradually decreases for a predetermined gradation transition satisfying the original gradation <the reached gradation. I do not care. In addition, the signal unit may be configured to sequentially provide an overshoot signal to the liquid crystal panel so that the level gradually increases with respect to a predetermined gradation transition satisfying the original gradation> the reached gradation. I do not care.

  The signal section may be configured to give one level of overshoot signal to the liquid crystal panel for one field period.

  In addition, the signal unit gives an undershoot signal to the liquid crystal panel after giving a signal corresponding to the original gradation and before giving an overshoot signal in accordance with the gradation transition from the original gradation to the reached gradation. And the test drive is performed while sweeping the levels of the overshoot signal and the undershoot signal, and the analysis unit outputs the overshoot signal and the undershoot signal corresponding to the optimum detection result. It may be configured to store in association with the original gradation and the reached gradation.

  The signal unit is configured to sequentially supply different levels of undershoot signals to the liquid crystal panel with respect to a predetermined gradation transition, and the analysis unit generates an undershoot signal corresponding to an optimum detection result. Each level may be stored in association with the original gradation and the reached gradation. In addition, the signal section is configured to sequentially give an undershoot signal to the liquid crystal panel so that the level gradually increases for a predetermined gradation transition satisfying the original gradation <the reached gradation. Is preferred. Further, the signal unit may be configured to sequentially supply an undershoot signal to the liquid crystal panel so that the level gradually decreases with respect to a predetermined gradation transition satisfying the original gradation> the reached gradation. I do not care.

  The signal unit may be configured to give an undershoot signal of one level to the liquid crystal panel for one field period.

  The present invention is not limited to the above-described embodiment, and can be widely implemented in determining the OS drive level of the liquid crystal panel.

  Furthermore, the present invention is not limited to the above-described embodiments, and various modifications can be made within the scope shown in the claims, and the technical means disclosed in the different embodiments can be appropriately combined. Such embodiments are also included in the technical scope of the present invention.

  The evaluation apparatus for a liquid crystal display device according to the present invention can easily and accurately determine an optimum overshoot signal that becomes a lookup table when overshoot driving is performed on a liquid crystal display panel. For this reason, it can utilize as an evaluation apparatus of the liquid crystal display device which performs an overshoot drive.

1 Evaluation device (Evaluation device for liquid crystal display devices)
2 Liquid crystal panel 3 Video signal generation circuit (signal part)
4 Optical receiver (display detector)
5 Waveform analyzer (analysis unit)
6 Thermostatic chamber 7 Liquid crystal display device 9 Window 11 OS signal generator (signal unit)
12 Clock signal input part (signal part)
13 Switch part (signal part)
14 Signal output part (signal part)

Claims (11)

A video signal generating circuit for giving a signal to the liquid crystal panel to be evaluated, an optical light receiving element for detecting the display of the liquid crystal panel, and a waveform analyzer for receiving an output from the optical light receiving element;
The video signal generation circuit is configured to perform a test drive that gives a signal corresponding to the original gradation to the liquid crystal panel and then gives an overshoot signal while sweeping the level of the overshoot signal. The waveform analysis apparatus has a relationship between a maximum or minimum level and a level corresponding to a desired arrival gradation for each output waveform from the optical light receiving element input corresponding to each trial drive, and Analyzing the time required to reach the level corresponding to the desired arrival gradation, and based on the result, the level of the overshoot signal at the time of the trial drive that reached the arrival gradation fastest without excessive response Is stored in association with the original gradation and the reached gradation. A signal unit that gives a signal to the liquid crystal panel to be evaluated, a display detection unit that detects display of the liquid crystal panel, and an analysis unit that analyzes a detection result of the display detection unit,
The signal unit provides a signal corresponding to the original gradation to the liquid crystal panel, and then an overshoot test signal or an overshoot test signal according to the transition of the gradation from the original gradation to the reached gradation. And a test drive that gives both the undershoot test signal while sweeping the level of the test signal, and the analysis unit includes each of the display detection units obtained by the test drive. Analyze the detection result, and based on the result, store the level of the test signal at the time of the trial drive that has reached the arrival gradation fastest without any excessive response in association with the original gradation and the arrival gradation. An apparatus for evaluating a liquid crystal display device, characterized in that it is configured as described above.   The signal unit is configured to give a test signal for overshoot consisting of a plurality of levels to the liquid crystal panel with respect to a predetermined gradation transition, and the analysis unit does not have an excessive response and has a reached gradation. 3. The apparatus according to claim 2, wherein a plurality of levels of the test signal at the time of trial driving that reaches the fastest time are stored in association with the original gradation and the arrival gradation. Evaluation device for liquid crystal display devices.   The signal unit gives a test signal for undershoot consisting of at least one level after giving a signal corresponding to the original tone for a predetermined gradation transition, and then for overshoot consisting of at least one level. The test section is configured to give the test signal to the liquid crystal panel, and the analysis section has no excessive response, and the level and overshoot of the test signal for undershoot during the trial drive that has reached the arrival gradation fastest 3. The evaluation apparatus for a liquid crystal display device according to claim 2, wherein the level of the test signal for shooting is stored in association with the original gradation and the reached gradation.   5. The apparatus for evaluating a liquid crystal display device according to claim 3, wherein the signal section is configured to give one level in the test signal to the liquid crystal panel for one field period. An optical light receiving element provided in the display detection unit, and a waveform analysis device provided in the analysis unit, to which an output waveform from the optical light receiving element is input,
For each output waveform input from the optical light receiving element corresponding to each trial drive, the waveform analysis apparatus determines the relationship between the maximum or minimum level and the level corresponding to the arrival gradation, and the arrival gradation. Analyzing the time required to reach the corresponding level, and based on the result, the test signal level at the time of trial driving that reached the reached gray level the fastest without the excessive response is the original gray level and the reached gray level. 3. The apparatus for evaluating a liquid crystal display device according to claim 2, wherein the evaluation device is configured to store in association with each other.   After giving a signal corresponding to the original gradation to the liquid crystal panel to be evaluated, an overshoot test signal or an overshoot test signal according to the gradation transition from the original gradation to the reached gradation The process of analyzing the display result by giving both the undershoot test signal and the test signal is repeated while sweeping the level of the test signal. The method of evaluating a liquid crystal display device is characterized in that the level of the image is stored in association with the original gradation and the reached gradation. A liquid crystal display device comprising a liquid crystal panel and a drive circuit,
The drive circuit has an optimum level of an overshoot signal or a combination of an overshoot signal and an undershoot signal according to the gradation transition from the original gradation to the reached gradation. The level is stored as a lookup table,
As the optimum level, after giving a signal corresponding to the original gradation to the liquid crystal panel, an overshoot test signal or an overshoot test signal and an undershoot test signal according to the gradation transition The process of analyzing the display result by giving both of the above is obtained by repeating the test signal level while sweeping the level of the test signal. A liquid crystal display device characterized by being used. In the drive circuit, an optimal combination of a plurality of signal levels is stored as a lookup table as an optimal level of the overshoot signal for a predetermined gradation transition,
As the optimum combination, a step of applying a test signal for overshoot having a plurality of signal levels to the liquid crystal panel after giving a signal corresponding to the original gradation and analyzing the display result 9. A combination of a plurality of signal levels obtained when the signal reaches the fastest arrival gradation without an excessive response, which is obtained repeatedly while sweeping the signal level is used. Liquid crystal display device. In the drive circuit, an optimum combination of the level of the overshoot signal and the level of the undershoot signal is stored as a lookup table for a predetermined gradation transition,
As the optimum combination, after giving a signal corresponding to the original gradation to the liquid crystal panel, an undershoot test signal and an overshoot test signal are sequentially given in this order to analyze the display result. The process is repeated while sweeping the level of each test signal, and there is no excessive response, and the combination of the levels of each test signal when the arrival gradation is reached the fastest is used. The liquid crystal display device according to claim 8.   The liquid crystal display device according to claim 8, wherein the look-up table is stored corresponding to each of a plurality of temperatures.