JP4016676B2 - projector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a projector that hardly causes unevenness in a projected image even when the light source unit is replaced, and a portable storage medium for the light source unit of the projector.
[0002]
[Prior art]
Today, as a method for displaying a large screen image, a projector using a transmissive or reflective liquid crystal device or a digital micromirror device (DMD: trademark of TI) as a light valve is known. In such projectors, light beams from a light source unit are modulated by a light valve for each of three color lights of R, G, and B, and the modulated light beams are projected on a screen by a projection optical system to display an image. In the light source unit, a light source lamp having a structure in which a light source lamp is installed at a predetermined position in a parabolic reflector is used. As the light source lamp, for example, a metal halide lamp, a xenon lamp, a high-pressure mercury lamp, a halogen lamp, or the like is used, and as the reflector, an ellipsoidal reflector or a spherical reflector is used in addition to a parabolic reflector.
[0003]
Now, the image displayed by the projector is preferably a uniform image without unevenness. However, in practice, the displayed image may be uneven depending on the input / output characteristics of the light valve, the manufacturing accuracy of the light source unit, and the like. Conventionally, in order to suppress such image unevenness, correction of image data of pixels in which unevenness has occurred has been performed. Such a correction method is disclosed in, for example, Japanese Patent Laid-Open No. 3-18822, and a specific example is shown below.
[0004]
FIG. 10 is a conceptual diagram showing an example of a conventional image correction method. In FIG. 6A, an image 501 (half-tone gray solid image) projected from the projector onto the projection surface is entirely uneven due to various factors. For example, the A position, the B position, There is a difference in luminance at the C position. FIG. 4B shows the luminance difference at each position in the X-axis direction. In this case, the maximum luminance b is obtained at the B position which is substantially the center, and subsequently the luminance a is obtained at the A position and the luminance c is obtained at the C position. That is, luminance c> luminance a> luminance c. In such a case, for example, if the reference luminance is luminance a, it is applied to the pixel of the light valve so that luminance a is realized not only at the A position but also at the B position and the C position. What is necessary is just to correct | amend a voltage. Specifically, the voltage applied to the pixel corresponding to the A position on the screen is left as it is, the voltage applied to the pixel corresponding to the C position on the screen is reduced by a predetermined level, and the pixel corresponding to the C position. What is necessary is just to increase the voltage applied to a predetermined level.
[0005]
[Problems to be solved by the invention]
According to the above conventional image correction method, as shown in FIG. 12A, when the image is projected onto the screen S, the light source unit 503 built in the projector 502 is used, and the image correction is performed for each projector. Like to do. For this reason, when the light source unit 503 is replaced due to a cause such as a lifetime, the manufacturing accuracy of the light source unit 503 is different for each light source unit, and thus there is a problem that uneven brightness occurs in the projected image. For example, the reflector of the light source unit 503 is made of glass, and it is difficult to form an accurate curved surface, and the accuracy of fixing the light source lamp to the reflector is low. When the part 503 is replaced, it appears as luminance unevenness of the projected image.
[0006]
Accordingly, the present invention has been made in view of the above, and an object of the present invention is to provide a projector and a portable storage medium for the light source unit of the projector, in which even if the light source unit is replaced, projection images are less likely to be uneven. .
[0007]
[Means for Solving the Problems]
In order to achieve the above-described object, the projector according to the present invention irradiates the light modulation means with a light beam, and corrects luminance unevenness of a projected image based on a light source unit mounted on the projector and a reference light source unit. The rewritable storage means for storing data, and the luminance unevenness of the projected image based on the light source section with respect to the reference correction data acquired in the comparison between the light source section mounted on the projector and the reference light source section and stored in the storage means. The correction data to be corrected is overlaid, the correction means for rewriting the contents of the storage means to the superimposed superposition correction data, the image signal is corrected by the superposition correction data stored in the storage means, and based on the corrected image signal Control means for controlling the light modulation means.
[0008]
That is, according to the present invention, an image is projected using a reference light source unit that is precisely manufactured at a factory or the like, luminance unevenness of the projected image is measured, and reference correction data for suppressing the luminance unevenness is acquired. This reference correction data is stored in a rewritable storage means. The light source unit mounted on the projector is a mass-produced product, and the brightness unevenness of the light source unit and the brightness unevenness of the reference light source unit are compared to obtain correction data specific to the light source unit that can suppress the difference in brightness unevenness. . Next, when mounting the light source unit on the projector, the correction unit superimposes correction data specific to the mounted light source unit on the reference correction data stored in the storage unit, and the contents of the storage unit are added to the characteristics of the light source unit. Rewrite to superimposition correction data that takes into account. If the image signal is corrected using such superposition correction data, it is possible to obtain a good projected image with suppressed luminance unevenness even if the light source unit is replaced.
[0009]
Note that the light source unit mounted on the projector includes a light source unit mounted at the time of shipment of the projector and a light source unit for replacement. The light modulation means includes, for example, a liquid crystal panel or DMD. Further, the correction means is normally mounted on a projector, but when the projector is configured as a system by a plurality of devices including a personal computer, it is provided on the information source side of a personal computer or the like for sending an image signal. May be. Similarly, the control means can be provided on the information source side.
[0010]
Further, the projector according to the present invention irradiates the light modulation means with a light beam, and stores a light source unit mounted on the projector and reference correction data for correcting luminance unevenness of a projected image based on the reference light source unit. Storage means, correction data acquired in comparison between a light source unit mounted on the projector and a reference light source unit, and a portable storage medium associated with the light source unit, and corrections stored in the portable storage medium The data is read and superimposed on the reference correction data, the correction means for rewriting the contents of the storage means to the superimposed superposition correction data, and the image signal is corrected by the superposition correction data stored in the storage means. Control means for controlling the light modulation means based on the image signal.
[0011]
That is, the projector stores correction data in a portable storage medium, reads the stored correction data from the portable storage medium, and superimposes the correction data on the reference correction data. Examples of portable storage media include flexible disks, IC cards, CD-ROMs, and the like. Further, the correction means includes a correction data reading means (whether it is a dedicated reading means or a general-purpose reading means for the portable storage medium). In addition, associating a portable storage medium with a light source unit may be a transaction form such as selling as an accessory of the light source unit or separately ordering the light source unit after purchase, but these are not a problem and are not portable. It means at least that the correction data stored in the storage medium corresponds to the light source unit. According to this projector, as described above, even when the light source unit is replaced, it is possible to obtain a good image with suppressed luminance unevenness, and further by storing the correction data in a portable storage medium, the correction data can be obtained with simple means. Can be provided to the user.
[0012]
Further, the projector according to the present invention irradiates the light modulation means with a light beam, and stores a light source unit mounted on the projector and reference correction data for correcting luminance unevenness of a projected image based on the reference light source unit. The correction data acquired in the comparison between the storage unit and the light source unit mounted on the projector and the reference light source unit is stored, and the correction data is acquired from the external storage unit connected via the communication line, and the correction The data is read and superimposed on the reference correction data, the correction means for rewriting the contents of the storage means to the superimposed superposition correction data, and the image signal is corrected by the superposition correction data stored in the storage means. Control means for controlling the light modulation means based on the image signal.
[0013]
The correction means acquires correction data via a communication line constituting a network such as the Internet or a LAN. This correction data is stored in an external storage means such as a manufacturer's Web server. In order to acquire the correction data, for example, information such as the identification number of the light source unit mounted on the projector may be transferred to the Web server and a correction data transfer request may be made. Further, when the projector includes a plurality of devices including a personal computer having a WWW browser function, the correction means can be provided on the PC side. As described above, if the correction data is acquired via the communication line, the portable storage medium can be omitted and the correction data can be easily acquired using the widespread Internet or the like.
[0014]
Further, the projector according to the present invention irradiates the light modulation means with a light beam, and stores a light source unit mounted on the projector and reference correction data for correcting luminance unevenness of a projected image based on the reference light source unit. Storage means, brightness measurement means for measuring the brightness of the light source section, and self-diagnosis means for acquiring the brightness of the light source section from the brightness measurement means and transferring the brightness information to the Web server via a communication line under a predetermined condition Brightness correction data that is generated or selected by the Web server based on the brightness information and that corrects the brightness is received from the Web server via the communication line, and the brightness correction data is stored in the storage unit. Superimposing and rewriting the contents of the storage means to the superimposed superposition correction data, and the superposition correction data stored in the storage means. Correcting the image signal by data, and a control unit for controlling the light modulating means based on the corrected image signals.
[0015]
This projector corrects this luminance reduction in view of the fact that the luminance of the light source unit decreases as it is used. In this projector, the self-diagnosis unit acquires the luminance of the light source unit from the luminance measurement unit, and transfers the luminance information to the Web server under a predetermined condition. Here, examples of the predetermined condition include that the luminance of the light source unit has fallen below a threshold value, that the usage time of the light source unit has reached 250 hours, 500 hours, and 750 hours. On the other hand, the Web server generates brightness correction data of the light source unit based on this brightness information, or selects brightness correction data stored in a database or the like. The correction unit receives the luminance correction data from the Web server via the communication line, and superimposes the luminance correction data on the correction data stored in the storage unit. As a result, not only when the light source unit is replaced, but also when the light source unit reaches the end of its life, a good image can be obtained while correcting the decrease in luminance.
[0016]
In the projector according to the aspect of the invention, the luminance measurement unit may be provided on an optical path between the light source unit and the light modulation unit, and may be a branch unit that branches a light beam from the light source unit, and a light beam branched by the branch unit. And a luminance meter installed on the optical path. Thus, by providing the branching unit on the optical path between the light source unit and the light modulation unit, the luminance of the light source unit can be measured without being affected by the light modulation unit.
[0017]
Further, the projector according to the present invention is a rewritable memory that irradiates a light beam to the light modulation means and stores reference correction data for correcting luminance unevenness of a projected image based on a reference screen and a light source unit mounted on the projector. The screen correction data for correcting the brightness unevenness of the projected image based on the screen is superimposed on the reference correction data acquired in the comparison between the means and the screen to be used and the reference screen and stored in the storage means, and the contents of the storage means are Correction means for rewriting the superimposed superposition correction data, and control means for correcting the image signal by the superposition correction data stored in the storage means and controlling the light modulation means based on the corrected image signal. Yes.
[0018]
The uneven brightness of the projected image is caused not only by the light source unit but also by the screen used. Therefore, it is possible to obtain a good image in which luminance unevenness is suppressed by correcting the reference correction data with the screen correction data and correcting the image signal based on the correction data. The reference correction data is obtained by measuring the luminance using a reference screen. By using the reference light source unit as the light source unit at the time of measurement, the reference correction data is obtained by using the reference screen and the reference The content is based on the correction unit. The screen correction data includes a case where correction data is provided for each screen and a case where correction data is provided for each type of screen. The correction data based on the light source unit can be superimposed on the reference correction data together with the correction data of the screen.
[0019]
Further, the projector according to the present invention is a rewritable memory that irradiates a light beam to the light modulation means and stores reference correction data for correcting luminance unevenness of a projected image based on a reference screen and a light source unit mounted on the projector. Means, screen identifying means for identifying the screen to be used, and screen correction data identified by the screen identifying means from the correction data for each screen acquired in the comparison between the screen to be used and the reference screen, and this is read as reference correction data. And correcting means for rewriting the contents of the storage means to the superimposed superposition correction data, correcting the image signal by the superposition correction data stored in the storage means, and based on the corrected image signal, the light modulation means Control means for performing control.
[0020]
The screen identification means identifies a screen to be used. A screen is specified from this identification content, and screen correction data to be used is determined and read from correction data for each screen based on this identification information. Then, the reference correction data is corrected by the screen correction data, and the image signal is corrected based on the superposition correction data. As a result, it is possible to obtain a good projected image in which luminance unevenness is suppressed. Here, as the screen identification means, the screen can be recognized using a known image processing technique such as reading bar code information displayed on the screen. Further, the correction data for each screen may be stored in a storage device of the projector, or may be stored in a database of a Web server and acquired via a communication line each time.
[0021]
The portable storage medium for the light source unit of the projector of the present invention irradiates the light modulation means with a light beam and is associated with the light source unit of the projector mounted on the projector. In order to superimpose on the reference correction data for correcting the brightness unevenness, correction data for correcting the brightness unevenness of the projected image based on the light source unit is obtained by comparing the light source unit mounted on the projector with the reference light source unit. Is remembered.
[0022]
When the light source unit is replaced, the correction data is read from the portable storage medium provided in the light source unit, and is superimposed on the reference correction data based on the reference light source unit provided on the projector side. Then, by correcting the image signal with this correction data and controlling the light modulation means, it is possible to obtain a good projected image with suppressed luminance unevenness. Note that “related to the light source unit of the projector” at least means that the correction data stored in the portable storage medium corresponds to the light source unit as described above.
[0023]
The portable storage medium for the light source unit of the projector according to the present invention irradiates the light modulation means with a light beam and is associated with the light source unit of the projector mounted on the projector, and the brightness of the projected image based on the reference screen In order to superimpose on the reference correction data for correcting the unevenness, correction data for correcting the uneven brightness of the projected image based on the reference screen is acquired in the comparison between the screen to be used and the reference screen, and stored.
[0024]
When a plurality of screens are used, the correction data is read from the portable storage medium provided in the light source unit, and is superimposed on the reference correction data based on the reference screen provided on the projector side. Then, by correcting the image signal with this correction data and controlling the light modulation means, it is possible to obtain a good projected image with suppressed luminance unevenness on each screen even when a plurality of screens are used. Note that “related to the light source unit of the projector” at least means that the correction data stored in the portable storage medium corresponds to the light source unit as described above.
[0025]
Further, the projector according to the present invention irradiates the light modulation means with a light beam, and stores a light source unit mounted on the projector and reference correction data for correcting luminance unevenness of a projected image based on the reference light source unit. The image correction data is selectively acquired from the storage means and the external storage means connected via a communication line, storing a plurality of types of image correction data so that an image having an arbitrary characteristic can be obtained. The image correction data is read and superimposed on at least the reference correction data, the correction means for rewriting the contents of the storage means to the superimposed superposition correction data, and the image signal is corrected by the superposition correction data stored in the storage means. And a control means for controlling the light modulation means based on the corrected image signal.
[0026]
According to the above configuration, the external storage means stores a plurality of types of image correction data that can obtain an image having an arbitrary characteristic, and the image correction data is selectively acquired and superimposed on the reference correction data. . Here, at least the reference correction data may be stored in the rewritable storage unit, and further, superimposition correction data obtained by superimposing the correction data based on the light source unit on the reference correction data may be stored. Thus, by selectively acquiring specific image correction data and rewriting the contents of the storage means, it is possible to obtain a projected image having a desired characteristic. For example, when it is desired to obtain image characteristics like a foreign movie, the corresponding image correction data is selected and the contents of the storage means are rewritten.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments. In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art or those that are substantially the same. In addition, the constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art.
[0028]
(Embodiment 1)
FIG. 1 is a schematic configuration diagram showing a liquid crystal projector according to a first embodiment of the present invention. The liquid crystal projector 100 includes a light source unit 1 composed of a light source lamp 1a and a parabolic reflector 1b, a light valve 2 composed of R, G, and B liquid crystal panels, a driver circuit 3 that drives the light valve 2, a light valve 2 includes a controller 4 that performs predetermined control on the power source 2 and a power supply device 5.
[0029]
The light source unit 1 is attached with an IC card 6 which is a dedicated memory, and the IC card 6 stores individual correction data corresponding to each light source unit 1. This individual correction data is for correcting the characteristic of luminance unevenness caused by the manufacturing accuracy of the original light source unit 1s (light source unit 1 attached at the time of shipment). In addition to the IC card 6, a portable storage medium such as a flexible disk or a magneto-optical disk can be used as the dedicated memory. On the other hand, an IC card R / W 7 (reader / writer) is connected to the controller 4. The IC card R / W 7 reads the stored contents of the IC card 6 attached to the light source unit 1 and records various information on the IC card 6 from a memory (not shown) provided on the liquid crystal projector side as necessary.
[0030]
The controller 4 is provided with a correction unit 8 and an LUT memory 9 constituted by rewritable storage means, and the LUT memory 9 stores reference correction data for a projected image. The reference correction data is data that cancels the spatial luminance unevenness of the reference light source unit 1r. Specifically, when the projector includes the reference light source unit 1r, when data representing a uniform gray image (solid gray image) is given from a certain image source (for example, a personal computer) to the projector, the reference light source unit This is correction data that prevents 1r luminance unevenness from appearing on the screen (an intended uniform gray image is obtained). The reference correction data is acquired using a reference light source unit 1r described later, and has the same contents for all the liquid crystal projectors 100.
[0031]
FIG. 2 is an explanatory diagram showing a correction data acquisition method for a light source unit in a factory. Since the manufacturing accuracy of the light source unit 1 varies to some extent as described above, the spatial luminance unevenness of the light emitted from each light source unit 1 varies depending on the light source unit 1. In a factory, a light source unit (reference light source unit 1r) made with very high accuracy is used, and projection light Gr by the reference light source unit 1r and projection light Gs by the shipping light source unit 1s are imaged by a CCD or the like. Correction data for correcting luminance unevenness is acquired by taking in, comparing, and subtracting with the apparatus. Whether the light source unit 1 for shipment is the original light source unit 1s attached at the time of shipment of the liquid crystal projector 100 or the replacement light source unit 1k for replacement, it is similarly compared with the reference light source unit 1r. Get correction data. This correction data is stored in the IC card 6 attached to each light source unit 1 at the factory.
[0032]
Here, the correction data stored in the portable storage medium such as the IC card 6 needs to be provided to the user in association with at least the light source unit 1. Associating the correction data with the light source unit 1 includes at least that the correction data corresponds to the light source unit 1, and the provision form thereof includes, for example, the IC card 6 as an accessory of the light source unit 1 as described above. Supplying simultaneously, supplying the IC card 6 and the light source unit 1 separately in time, and correction data stored in the IC card 6 are combined with other information (for example, lifetime information of the light source unit). Supplied. Further, the correction data may be provided via a medium other than a portable storage medium. For example, the correction data may be downloaded via a communication line by a user accessing a manufacturer's website.
[0033]
Initially, what is stored in the LUT memory 9 of the controller 4 is reference correction data created based on the reference light source 1r. For this reason, when the original light source unit 1s is mounted on the liquid crystal projector 100, naturally, a new luminance unevenness occurs in the projected image due to the difference in characteristics between the reference light source unit 1r and the original light source unit 1s. Therefore, when the original light source unit 1 s is mounted on the liquid crystal projector 100, the correction data of the original light source unit 1 s is read from the IC card 6 attached to the light source unit 1, and the reference correction data initially stored by the correction unit 8 and the relevant data The read correction data is overlapped to obtain superposition correction data, and the contents of the LUT memory 9 are rewritten to the superposition correction data. Here, superimposing the reference correction data and the correction data is not a problem if the image data is corrected using both the reference correction data and the correction data as a result. Preferably, the reference correction data and the correction data are added and stored in the LUT memory 9.
[0034]
The reference correction data stored in the LUT memory 9 from the beginning is temporarily stored in another memory (not shown) before rewriting, and when the light source unit 1 is replaced later, the reference correction data is stored from the memory. The contents of the LUT memory 9 can be returned to the initial value by reading. Note that superimposing correction data of the light source unit 1 may be left to the user's selection. That is, there are various user preferences for images, and there are cases where it is desired to display an image with the reference correction data as it is, and in that case, it is not necessary to read the correction data attached to the light source unit 1. On the other hand, when the user always wants to obtain an optimal projection image, the correction data attached to the light source unit 1 is read and superimposed with the reference correction data to obtain the superposition correction data. In this way, by using the rewritable LUT memory 9 as the LUT memory 9, even when the light source unit 1 is replaced, an optimum image can be obtained by superimposing correction data of the replaced light source unit 1. Obtainable.
[0035]
Further, as another form, the reference correction data of the reference light source unit 1r is stored in a non-rewritable storage means (not shown) such as a ROM, the reference correction data is read by the controller 4, and the original light source unit 1s. The correction data may be read from the IC card 6 and may be stored in the rewritable LUT memory 9 in a superimposed manner. Furthermore, as another form, a first LUT memory storing reference correction data based on the reference light source unit 1r and a rewritable second LUT memory storing the correction data based on the original or replacement light source unit 1 (Both not shown), and the lookup operation for the signal data voltage can be performed in two stages based on the first and second LUT memories.
[0036]
In performing image correction by the liquid crystal projector 100, first, an image signal is input to the controller 4 from an information source such as a personal computer (PC) 10, and the image signal is converted into a digital signal by an A / D converter (not shown). Convert. The image signal data is converted into corresponding image signal data stored in the LUT memory 9 and output. Thereby, the image correction based on the reference light source unit 1r and the original light source unit 1s is completed. The corrected image signal data is processed by a D / A converter (not shown) and sent from the controller 4 to the driver circuit 3. The driver circuit 3 drives the light valve 2 with the corrected image signal. When the LUT memory 9 is installed in two stages, the image signal data is corrected based on the reference light source unit 1r in the first lookup operation, and then this correction data is used in the second lookup operation. May be corrected based on the original light source unit 1s.
[0037]
Next, when the original light source unit 1 s reaches the end of its life or needs to be replaced due to failure, the user replaces the original light source unit 1 s with a replacement light source unit 1 k. An IC card 6 is also attached to the replacement light source unit 1k as described above. First, the controller 4 erases the superposition correction data stored in the LUT memory 9 and reads the reference correction data which is the initial value from the memory, and temporarily develops the contents in the LUT memory 9. Subsequently, the correction data based on the replacement light source unit 1k is read from the attached IC card 6 by the IC card R / W 7 and superimposed on the content of the reference correction data in the LUT memory 9. As a result, the correction data in the LUT memory 9 is rewritten to the superposition correction data based on the reference light source unit 1r and the replacement light source unit 1k. Further, when the replacement light source unit 1k has a life or failure and needs to be replaced, the contents of the superposition correction data in the LUT memory 9 are rewritten by the same procedure as described above.
[0038]
As a result, even when the light source unit 1 is newly replaced, the image signal is corrected based on the superposition correction data based on the characteristics of the replacement light source unit 1k. The resulting brightness unevenness of the projected image G is effectively suppressed. Even when the replacement light source unit 1k is replaced with a new replacement light source unit 1k, the optimum projection image G can be obtained by rewriting the superposition correction data based on the characteristics of the replacement light source unit 1k replaced in the same manner as described above. Obtainable.
[0039]
(Embodiment 2)
FIG. 3 is a block diagram showing a liquid crystal projector according to the second embodiment of the present invention. The liquid crystal projector 200 is characterized in that the unevenness of the projected image due to the characteristics of the screen to be used is corrected. Since the other configuration is the same as that of the liquid crystal projector 100 of the first embodiment, the difference will be mainly described. As shown in the figure, a liquid crystal projector 200 includes a light source unit 1 composed of a light source lamp 1a and a parabolic reflector 1b, a light valve 2 composed of R, G, and B liquid crystal panels, and a driver for driving the light valve 2. A circuit 201, a controller 201 that performs predetermined control on the light valve 2, and a power supply device 5 are provided. The controller 201 includes a correction unit 202 and an LUT memory 203 configured by rewritable storage means, and further reads a screen correction unit 204, an image processing unit 205, a screen data memory 206, and correction data for each screen. And a data reading unit 207.
[0040]
The controller 201 is connected to a camera 209 for reading the barcode 208 formed on the screen S. The camera 209 is installed integrally with the casing of the liquid crystal projector 200 and is arranged toward the screen S. Further, the camera 209 may be a separate unit from the liquid crystal projector 200 and may be compatible with another liquid crystal projector. Screen correction data for each screen is stored in a portable storage medium 210 attached to the screen S, such as a flexible disk or an IC card. In the barcode 208, information for recognizing a specific screen S or the type of the screen S is encoded.
[0041]
In the case of the projection type liquid crystal projector 200, a plurality of screens S are often used by one unit. Further, the luminance unevenness of the projected image G is corrected as in the first embodiment. However, since the characteristics of the luminance distribution are different for each screen, the characteristics vary when different screens S are used. As a result, uneven brightness occurs in the projected image G. For example, since the position of the hot spot is different for each screen, a part of the luminance may be increased and displayed. Therefore, in order to correct the luminance unevenness of the projected image G between the screens, the screen correction data is stored in the portable storage medium 210 for each screen, and this screen correction data is read by the data reading unit 207 for screen data. Store in the memory 206.
[0042]
The screen correction data is acquired by comparing a difference between a projected image projected on a reference screen (not shown) and a projected image projected on the screen S to be shipped. Since the reference correction data is obtained using the reference screen, the contents stored in the LUT memory 203 are reference correction data based on the reference screen and the reference light source unit 1r. The user reads the screen correction data stored in the portable storage medium 210 attached to the screen S by the data reading unit 207 and stores it in the screen data memory 206 of the own liquid crystal projector 200. By obtaining the screen correction data for each screen, it is possible to further suppress uneven brightness in the projected image G. Note that the screen correction data may be shared for each type of the screen S without acquiring the screen correction data corresponding to each screen S. In this way, the screen correction data can be obtained and prepared for the screen S lineup, which is simple.
[0043]
Next, the operation of the liquid crystal projector 200 will be described. First, when the liquid crystal projector 200 is turned on toward the screen S, the barcode 208 provided on the screen Sa is read by the camera 209. Then, the image is converted into an electrical signal by a CCD (charge coupled device) built in the camera 209 and A / D converted, and then the content of the barcode 208 is read by the image processing unit 205. The screen data memory 206 stores the screen correction data of the plurality of screens S that can be used by the user as described above together with the recognition code, and the screen correction unit 204 has a recognition code that matches the content of the barcode 208. The screen correction data of the screen Sa is read from the screen data memory 206.
[0044]
On the other hand, the LUT memory 203 stores superposition correction data obtained by superimposing the reference correction data based on the reference light source unit 1r and the correction data based on the original light source unit 1s. The controller 201 again superimposes the superposition correction data and the screen correction data, generates double superposition correction data that takes into account the characteristics of the screen Sa to be used, and overwrites this in the LUT memory 203.
[0045]
Next, when a screen Sb different from the screen Sa is used, the screen correction data of the screen Sb is read from the barcode 208 provided on the screen Sb as described above, and the screen correction data is superposed on the original light source unit 1s. Overlay the correction data. Thereby, even when different screens Sb are used, it is possible to correct the image signal in consideration of the characteristics. In this way, when the screen S is used, the barcode 208 is automatically read to automatically recognize the screen S, so that a correction that will occur each time the user installs the liquid crystal projector 200 and projects an image. Work can be greatly simplified. Note that after the liquid crystal projector 200 is turned on, the screen correction may be executed by a user pressing a switch (not shown).
[0046]
When an image signal is input to the controller 201 from an information source such as the PC 10, the controller 201 converts the image signal into a digital signal by an A / D converter (not shown), and this image signal data is stored in the LUT memory 203. It converts into the corresponding image signal data stored and outputs it. Thereby, the image correction based on the reference light source unit 1r, the original light source unit 1s, and the screen S to be used is completed. The corrected image signal data is D / A converted and sent from the controller 201 to the driver circuit 3. The driver circuit 3 drives the light valve 2 based on the image signal.
[0047]
In the second embodiment, the camera 209 reads the barcode 208 to recognize the screen S. However, other means, for example, the user inputs the identification number of the screen S from an input unit such as a numeric keypad. Alternatively, the barcode 208 may be read by a normal barcode reader. In addition, the screen S related to the screen correction data stored in the screen data memory 206 is displayed on the display unit of the operation panel of the liquid crystal projector 200 with a symbol such as a number, and the screen S is recognized by the user selecting it. It may be. Furthermore, the screen correction data for the screen S may be acquired via a communication line, for example, by the user accessing the manufacturer's website instead of the storage medium.
[0048]
(Embodiment 3)
4 is a block diagram showing a liquid crystal projector system according to Embodiment 3 of the present invention. The liquid crystal projector system 300 includes a light source unit 1 composed of a light source lamp 1a and a parabolic reflector 1b, a light valve 2 composed of R, G, and B liquid crystal panels, a driver circuit 3 that drives the light valve 2, a light The controller 301 includes a controller 301 that performs predetermined control on the valve 2, an IC card R / W 302, a power supply device 5, and a PC 360 having a browser function.
[0049]
The controller 301 includes a correction unit 303, an LUT memory 304 configured by rewritable storage means, a light valve data memory 305, and a self-diagnosis unit 306. Further, between the light source unit 1 and the light valve 2, a reflection unit 307 such as a mirror or a prism for branching the projection light is installed. This branched light is measured by a luminance meter 308 connected to the controller 301. Thus, if the projection light from the light source unit 1 is branched instead of the modulated light that has passed through the light valve 2, the luminance of the light source unit 1 can be measured accurately. The reflection unit 307 can be installed between the illumination optical system from the light source unit 1 to the lens array and the superimposing lens, and the color light separation optical system that separates the three colors of RGB, and particularly irradiates outside the effective area of the light valve 2. If it is installed on the optical axis of the irradiated light, it is preferable from the viewpoint that a useless light beam can be effectively used.
[0050]
The self-diagnosis unit 306 has a predetermined threshold value for determining the lifetime of the light source unit 1, and when the measurement signal from the luminance meter 308 becomes equal to or less than the threshold value, the controller 301 replaces the light source unit 1 with the controller 301. Send a signal to inform you. The light valve data memory 305 stores identification data of the light valve 2 used in the liquid crystal projector 350. The light source unit 1 includes an identification number 309 instead of the IC card 6 as in the first and second embodiments. The identification number 309 is assigned a different number for each light source unit 1, and is printed on a sticker or the like, for example, and attached to the back surface of the parabolic reflector 1 b of the light source unit 1.
[0051]
On the other hand, the manufacturer's Web server 370 includes a light source unit database 371 that stores correction data of the light source unit 1, a light source unit search unit 372 that searches the identification number 309 displayed on the light source unit 1 and reads out the corresponding correction data. A light valve database 373 that stores information related to the light valve 2, a light valve search unit 374 that retrieves the corresponding light valve information by searching for the light valve 2 identification code, and LV correction data from the read correction data and light valve information. And an LV correction data generation unit 375 for generation. The light valve information includes, for example, the type and year of the light valve 2, the degree of deterioration over time, the manufacturing location, and the like.
[0052]
The LUT memory 304 stores image reference correction data. The reference correction data is created by acquiring a luminance unevenness characteristic curve from a projected image and calculating the inverse transformation curve, as in the conventional case. Further, the reference correction data is obtained by using the reference light source unit 1r made with very high accuracy, and has the same contents in all the liquid crystal projectors. On the other hand, the correction data accumulated in the light source unit database 371 is obtained by comparing and comparing the projection image of the reference light source unit 1r with the projection image of the original light source unit 1s for shipping and the replacement light source unit 1k. An identification number 309 is assigned to the correction data, and this number is displayed on the light source unit 1.
[0053]
Next, the operation of this liquid crystal projector system will be described. FIG. 5 is a flowchart showing a procedure until correction data generation. When the user acquires correction data of the replacement light source unit 1k that has been replaced according to the lifetime of the original light source unit 1s, first, the user activates the PC 360 and connects to the manufacturer's Web server 370 via the Internet 380 (step S501). Transfers the Web page to the PC 360 (step S502). Next, in the PC 360, the user inputs an identification number into the identification number input field 61 provided on the correction data download Web page 60 (see FIG. 6) (step S503). Subsequently, when the light valve identification code input button 62 is selected (step S504), an acquisition command is transmitted to the liquid crystal projector 350, and the controller 301 acquires the identification code of the light valve 2 from the light valve data memory 305 (step S505). ) And transfer to the PC 360 (step S506). Note that it is up to the user to generate correction data in consideration of the light valve information.
[0054]
Subsequently, when the user selects the correction data generation button 63 on the screen, the identification number 309 of the light source unit 1 and the identification code of the light valve 2 are transferred to the Web server 370 together with the correction data generation request (step S507). ). Next, when receiving the identification number 309 of the light source unit 1 and the identification code of the light valve, the Web server 370 searches the light source unit database 371 based on the identification number 309 of the light source unit, and reads out the corresponding correction data (step). S508). Similarly, the light valve database 373 is searched based on the identification code of the light valve 2, and the corresponding light valve information is read (step S509). This light valve information is not essential for generating correction data. As described above, the correction by the light valve information can be made unselected, and when the light valve information cannot be searched, the light valve information It is also possible not to perform correction based on.
[0055]
Then, LV correction data is generated by the correction data generation unit 375 from the correction data of the light source unit 1 and the light valve information (step S510). This correction data is generated in consideration of the light valve information. For example, when the light valve 2 is old and the brightness thereof is reduced to a certain level, the voltage of the image signal data is reduced to the brightness reduction amount. Just lower. Subsequently, the generated LV correction data is transferred to the PC 360 (step S511). The PC 360 transfers the LV correction data to the liquid crystal projector 350 (step S512). As a result, the LV correction data is sent to the correction unit 303 of the liquid crystal projector 350, and the LV correction data is superimposed on the reference correction data. The contents of the LUT memory 304 are rewritten (step S513).
[0056]
In the above description, the case where the original light source unit 1s is replaced with the replacement light source unit 1k is shown for convenience of understanding. However, the replacement light source unit 1k has reached the end of its life and is replaced with a new replacement light source unit 1k. In this case, the superposition correction data is rewritten by the same procedure as described above. Similarly to the above embodiment, the reference correction data initially stored in the LUT memory 304 is temporarily stored in another memory (not shown) before being rewritten, and when the light source unit 1 is replaced, the reference correction data is stored in the memory. It is preferable to read out and return the contents of the LUT memory 304 to the initial values.
[0057]
Further, in the liquid crystal projector system 300, when the luminance of the light source unit 1 decreases with the passage of usage time, an optimum projected image can be obtained by measuring the luminance with a self-diagnosis function. FIG. 7 is a flowchart showing the procedure of automatic brightness adjustment by the self-diagnosis unit. First, when the liquid crystal projector 350 is projecting an image, the projection light from the light source unit 1 is branched by the reflecting means 307, and this branched light is measured by the luminance meter 308 (step S701). Subsequently, the measurement signal of the luminance meter 308 is sent to the controller 301, and the self-diagnosis unit 306 compares the measurement signal with a predetermined threshold value. If the luminance decreases due to the lifetime of the light source unit 1 and the measurement signal falls below the threshold value, the luminance measurement of the light source unit 1 is continued unless it falls below the threshold value determined as the lifetime (steps S702 and S703).
[0058]
On the other hand, if the luminance of the light source unit 1 falls below a predetermined threshold value, it is determined that the light source unit 1 has reached the end of its life, and a light source unit replacement instruction is issued to the display unit of the liquid crystal projector 350 (step S704). Next, when the light source unit 1 has not reached the end of its life, the controller 301 acquires the luminance data of the light source unit 1 from the self-diagnosis unit (step S705), and also obtains the identification code of the light valve 2 from the light valve data memory 305. Obtain (step S706). Note that the identification data of the light valve 2 can be excluded from consideration by the user. When the luminance data and the identification code can be acquired, the PC 360 is connected to the web server 370 (step S707), and the luminance data and the identification code are transferred to the correction data generation unit 375 of the web server 370 (step S708).
[0059]
The LV correction data generation unit 375 searches the light valve database 373 based on the identification code, and generates luminance correction data from the searched light valve information and luminance data (step S709). That is, by correcting the image signal data so as to compensate for the decrease in luminance of the light source unit 1, the occurrence of luminance unevenness due to the decrease in luminance is prevented. When the correction data is generated by the LV correction data generation unit 375, the correction data is downloaded by the PC 360 and further transferred to the controller 301, whereby the luminance correction data and the correction data of the original light source 1s that is initially stored (or The correction data of the replacement light source 1k is overlaid and overwritten in the LUT memory 304 (step S710). Thereby, even when the luminance of the light source unit 1 is reduced, the luminance reduction can be corrected, so that the luminance of the projected image can be kept constant. In particular, by using a combination of the luminance correction and the correction at the time of replacing the light source unit, it is possible to obtain a projected image with little luminance unevenness and a constant luminance.
[0060]
In the above description, when the light source unit 1 is replaced, correction data is obtained from the Web server 370 via the Internet 380. However, the identification number 309 of the light source unit 1 is obtained via the IC card R / W 302. The information may be input to the IC card 310 or filled in a predetermined paper 311 and sent to the manufacturer. Further, the identification code of the light valve 2 stored in the light valve data memory 305 can be stored in the IC card 310. On the manufacturer side, referring to the identification number 309 of the light source unit 1 and the identification code of the light valve 2 stored in the IC card 310, the LV correction data generation unit 375 generates LV correction data. The data is stored again in the IC card 310 and sent back to the user. The user superimposes the LV correction data stored in the IC card 310 with the reference correction data stored in the LUT memory 304 through the same procedure as described above.
[0061]
Further, in the liquid crystal projector system 300, the user can select an installer to obtain a favorite image. The manufacturer's Web server 370 is provided with an installer database 376 and an installer selection unit 377. The installer generally means a home theater specialist who performs operations such as installation adjustment of a liquid crystal projector and a screen and finishing of a viewing environment. The installer in this embodiment generates an image that the user likes. It means image correction data for this purpose.
[0062]
FIG. 8 is an explanatory diagram for displaying the contents of the installer selection screen. The installer is stored in the installer database 376 with a specific name added. For example, “Hollywood action”, “Takeshi Minamino”, etc. are added to the image correction data as installer names, and the installer names are displayed as a list on the screen of the PC 360. In the case of “Hollywood action”, the image correction data is such that the image can be corrected to the color of the American West Coast. The installer selection screen 80 displays a graphic 81 displaying the contents of the installer and a brief description 82 of the installer. For example, in the case of “Hollywood Action”, the figure where the action star jumps in front of the exploding flame and “The blue sky of the American West Coast is clearly displayed, and a fast-moving image is easy to see. A simple explanation such as “is displayed.
[0063]
When the user selects a specific figure 81, the screen shifts to a predetermined installer screen 90 as shown in FIG. On the installer screen 90, a selected installer name 91, a detailed description 92 of the installer, and a sample image 93 are displayed. The user confirms the displayed installer and selects the execution button 94. Thereby, a request for image correction data transfer is made from the PC 360 to the Web server 370, and the installer selection unit 377 reads out the image correction data of the selected installer and transfers it to the PC 360 via the Internet 380. The image correction data is stored in a storage device such as a hard disk of the PC 360.
[0064]
Next, image correction data is transferred from the PC 360 to the correction unit 303 of the liquid crystal projector 350, and the contents of the LUT memory 304 are rewritten based on the image correction data. For example, among the R, G, and B correction data stored in the LUT memory 304, the B correction data is further corrected by the image correction data to obtain an image in which blue is emphasized. Further, correction may be made so that the voltage of the output image signal is slightly lowered to lower the luminance of the entire image. Then, the image is corrected based on the rewritten correction data, and a user-preferred image is projected.
[0065]
In addition, the manufacturer changes the type of installer as needed. In addition, the user can store the downloaded image correction data in a hard disk or the like of the PC 360, and the installer can change the stored image correction data offline. The image correction data of the installer may be stored in the storage device of the liquid crystal projector 350 so that the installer can be selected on the liquid crystal projector side.
[0066]
If the installer can be selected by the user as described above, an image desired by the user can be projected. In the above description, the image correction data of the installer is downloaded from the Web server 370 via the Internet 380. However, the image correction is performed via a portable storage medium such as an IC card or a CD-ROM storing the image correction data. Data may be acquired.
[0067]
Furthermore, in the first to third embodiments, the liquid crystal projector has been described as an example. However, the above configuration can also be applied to a projector using a reflective light modulation element such as DMD. The same effect can be obtained even if the above configuration is applied to a rear projection type projector. Furthermore, a controller including the correction unit and the LUT memory can be provided on the Web server side.
[0068]
【The invention's effect】
As described above, in the projector of the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit is stored in the rewritable storage means, and the reference correction data is mounted on the projector. Superimposing correction data based on the light source, rewriting the contents of the storage means to the superimposed superposition correction data, correcting the image signal with the superposition correction data, and controlling the light modulation means based on the corrected image signal Since it performed, the favorable image which suppressed the brightness nonuniformity can be obtained even when the light source part is replaced.
[0069]
Further, in the projector according to the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit is stored in the rewritable storage unit, and on the other hand, the light source unit and the reference light source unit mounted on the projector The correction data acquired in the comparison is stored in a portable storage medium associated with the light source unit, the correction data stored in the portable storage medium is read by the correction means, and this is overlaid on the reference correction data, and the storage means Is overwritten with the superimposed superposition correction data, the image signal is corrected with the correction data, and the light modulation means is controlled based on the corrected image signal. A good image with reduced luminance unevenness can be obtained. Further, the correction data can be easily provided to the user.
[0070]
Further, in the projector according to the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit is stored in the rewritable storage means, and is obtained by comparing the light source unit mounted on the projector with the reference light source unit. The correction data is acquired from the external storage means that stores the corrected data via a communication line, the correction data is read and superimposed on the reference correction data, and the image signal is corrected with the correction data. The light modulation means is controlled based on the corrected image signal. In this way, even when the light source unit is replaced, correction data corresponding to the light source unit can be easily obtained, and a good image with reduced luminance unevenness can be obtained.
[0071]
In the projector according to the invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit is stored in the rewritable storage unit, and the luminance of the light source unit is acquired from the luminance measurement unit by the self-diagnosis unit. At the same time, the luminance information is transferred to the Web server via a communication line under a predetermined condition. Then, the correction means receives the brightness correction data generated or selected by the Web server based on the brightness information for correcting the brightness from the Web server via the communication line, and stores the brightness correction data in the storage means. Overlaying the reference correction data, the contents of the storage means are rewritten to the superposed superposition correction data. The control means corrects the image signal with the superposition correction data stored in the storage means, and controls the light modulation means based on the corrected image signal. As a result, even when the luminance of the light source unit decreases during use, it is possible to correct this and obtain a good projected image.
[0072]
In the projector according to the invention, the luminance measuring unit is provided on the optical path between the light source unit and the light modulating unit, and is installed on the optical path of the light beam branched by the branching unit and the branching unit for branching the light beam from the light source unit. Therefore, the luminance of the light source unit can be measured without being affected by the light modulation means. For this reason, the brightness | luminance of a light source part can be measured correctly.
[0073]
Further, in the projector according to the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference screen is stored in the rewritable storage means, acquired in the comparison between the screen to be used and the reference screen, and used as the reference correction data. On the other hand, the screen correction data for correcting the luminance unevenness of the projected image based on the screen is superimposed, the image signal is corrected by the screen correction data, and the light modulation means is controlled based on the corrected image signal. Regardless of which screen is used, it is possible to obtain a good image by suppressing luminance unevenness due to the screen.
[0074]
In the projector according to the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference screen is stored in the rewritable storage means, and each screen acquired in the comparison between the screen to be used and the reference screen is stored. The screen correction data identified by the screen identification means is read from the screen correction data and is superimposed on the reference correction data. Then, the image signal is corrected by the superimposed superposition correction data, and the light modulation means is controlled based on the corrected image signal. As a result, regardless of the screen used, it is possible to suppress luminance unevenness caused by the screen and obtain a good image.
[0075]
In the portable storage medium for the light source unit of the projector according to the present invention, correction data associated with the light source unit of the projector mounted on the projector and the light source unit and the reference light source unit When the light source unit is mounted on the projector, the stored correction data is superimposed on the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit. did. Therefore, by correcting the image signal using the superimposed correction data, it is possible to obtain a good image in which luminance unevenness is suppressed even when the light source unit is replaced.
[0076]
In the portable storage medium for the light source unit of the projector according to the present invention (claim 9), the correction data associated with the light source unit of the projector mounted on the projector is used while irradiating the light modulation means with the light flux When the light source unit is installed in the projector, the stored correction data is used for the reference correction data for correcting the luminance unevenness of the projected image based on the reference screen. It was made to overlap. Therefore, by correcting the image signal using the superimposed correction data, it is possible to obtain a good image in which luminance unevenness is suppressed even when the light source unit is replaced.
[0077]
In the projector according to the present invention, the reference correction data for correcting the luminance unevenness of the projected image based on the reference light source unit is stored in a rewritable storage means, and a plurality of types of image correction are performed so that an image having arbitrary characteristics can be obtained. The image correction data is selectively acquired from the external storage means storing the data via a communication line, and the image correction data is read and superimposed on at least the reference correction data. And the light modulation means is controlled based on the corrected image signal. In this way, a projection image having a desired characteristic can be obtained by selection by the user or the like.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing a liquid crystal projector according to a first embodiment of the invention.
FIG. 2 is an explanatory diagram showing a correction data acquisition method for a light source unit in a factory.
FIG. 3 is a configuration diagram showing a liquid crystal projector according to a second embodiment of the invention.
FIG. 4 is a configuration diagram showing a liquid crystal projector system according to a third embodiment of the present invention.
FIG. 5 is a flowchart showing a procedure until correction data generation.
FIG. 6 is an explanatory diagram illustrating an example of a correction data download Web page.
FIG. 7 is a flowchart showing a procedure for automatic brightness adjustment by a self-diagnosis unit;
FIG. 8 is an explanatory diagram for displaying the contents of an installer selection screen.
FIG. 9 is an explanatory diagram showing an example of an installer screen.
FIG. 10 is a conceptual diagram illustrating an example of a conventional image correction method.
[Explanation of symbols]
100 LCD projector
1s Original light source
1 Light source
1r Reference light source
1k replacement light source
2 Light valve
3 Driver circuit
4 Controller
5 Power supply
6 IC card
8 Correction part
9 LUT memory
200 LCD projector
201 controller
202 Correction unit
203 LUT memory
204 Screen correction unit
205 Image processing unit
206 Screen data memory
207 Data reading unit
208 barcode
209 Camera
210 Portable storage media
300 LCD projector system
301 controller
303 Correction unit
304 memory
305 Light valve data memory
306 Self-diagnosis unit
307 Reflection means
308 Luminance meter
309 identification number
310 cards
350 LCD projector
370 Web server
371 Light source database
372 Light source search unit
373 Light Valve Database
374 Light valve search unit
375 Correction data generation unit
376 Installer database
377 Installer selection part
380 Internet

Claims (2)

A light source unit that irradiates the light modulation means with a light beam and is mounted on the projector;
Rewritable storage means for storing reference correction data for correcting luminance unevenness of a projected image based on a reference light source unit;
A luminance measuring means for measuring the luminance of the light source unit;
Self-diagnosis means for acquiring the brightness of the light source unit from the brightness measurement means and transferring the brightness information to the Web server via a communication line under a predetermined condition;
Correction data that is generated or selected by the Web server based on the luminance information and corrects the luminance is received from the Web server via the communication line, and this correction data is superimposed on the reference correction data stored in the storage means. Correction means for rewriting the contents of the storage means to the superimposed superposition correction data;
Control means for correcting the image signal by the superposition correction data stored in the storage means and controlling the light modulation means based on the corrected image signal;
A projector comprising: The luminance measuring means is provided on an optical path between the light source section and the light modulating means, and includes a branching means for branching the light beam from the light source section, and a luminance meter installed on the optical path of the light beam branched by the branching means. The projector according to claim 1 , wherein the projector is configured.

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