JP2005156964A - Projector and projector system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a projector provided with a drive control circuit having an image processing circuit omitted, and to provide a projector system incorporating the projector. <P>SOLUTION: A correction control part 65 outputs a request for read of connection information and a correction parameter to the side of a projector 30 via an input/output control part 64, when detecting that the projector 30 and a computer 50 are connected. On the side of the projector 30, a main control circuit 100 properly operates an interface part 34 at a proper timing to output connection information, such as a display format and a correction parameter, such as a shape correction data in a memory 36, to the side of the computer 50, in response to request. On the side of the computer 50, a correction control part 65 fetches the connection information and the correction parameter via an interface 53. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a projector for projecting an image and a projector system incorporating such a projector.

As a conventional projector, there is one that incorporates an image processing circuit for correcting trapezoidal distortion or the like of a projected image projected on a screen (see, for example, Patent Document 1).
JP 2003-319293 A

  However, since the projector as described above incorporates a high-performance image processing circuit, the drive control circuit becomes complicated as a whole, resulting in an increase in cost.

  SUMMARY An advantage of some aspects of the invention is to provide a projector including a drive control circuit in which an image processing circuit is omitted, and a projector system incorporating such a projector.

  In order to solve the above problems, a projector according to the present invention relates to (a) a projection unit that projects an image according to an input image signal, and (b) an image process to be performed on the image signal input to the projection unit. Storage means for storing predetermined information, and (c) an interface unit for outputting the predetermined information stored in the storage means to the outside.

  In the projector described above, the interface unit outputs the predetermined information stored in the storage means to the outside, so that the image signal input to the projection means can be extracted and used by a personal computer or the like separately provided outside. The image processing to be performed can be performed. By using an image signal subjected to image processing in this way, it is possible to form an appropriate desired image in which correction or the like is applied to the light modulation device provided in the projection means without incorporating an expensive image processing unit in the projector. Can do. Therefore, it is possible to easily project an image with excellent image quality while making the projector inexpensive.

  In the projector according to a specific aspect of the present invention, the projection unit projects the illumination device, the light modulation device illuminated by the illumination light from the illumination device, and the projection optical that projects the image light from the light modulation device. Device. In this case, the projector is a projection-type device, and image degradation such as trapezoidal distortion, color balance deviation, and color unevenness is likely to occur during projection, but such image degradation can be easily compensated.

  In another specific aspect of the invention, the predetermined information includes information related to correction of an image to be input to the projection unit. In this case, it is possible to perform image processing that corrects the characteristics of the projector and the influence of the environment in which the projector is placed, and quick adjustment is performed when an image is projected by connecting a personal computer or the like to the projector.

  According to another specific aspect of the invention, the correction information includes correction including at least one of spatial deformation, color adjustment, contrast adjustment, and brightness adjustment of an image to be input to the projection unit. Information.

  In another specific aspect of the present invention, a drive circuit is further provided that operates the light modulation device based on image data input from the outside. In this case, image processing is performed on image data input from the outside in advance, and an appropriate desired image that has been subjected to correction or the like can be formed by appropriately operating the light modulation device using a drive circuit.

  In another specific aspect of the present invention, the interface unit transfers image data input from the outside to the drive circuit. In this case, the light modulation device can be operated based on the image data itself without providing a special circuit in front of the drive circuit.

  Another specific aspect of the present invention further includes a buffer circuit that temporarily stores the image data input to the interface unit before the image data is transferred to the drive circuit. In this case, a desired image can be formed on the light modulation device at an appropriate timing regardless of the data format and data amount of image data from the outside.

  The projector system according to the present invention reads (a) the above-described projector, (b) an input / output unit connectable to the interface unit, and predetermined information stored in the storage unit of the projector via the input / output unit. A computer having a processing information management unit that holds the image data to be projected and a correction processing unit that performs processing on the image data to be projected based on predetermined information held in the processing information management unit.

  In the projector system, the processing information management unit reads the predetermined information stored in the storage unit of the projector, and the correction processing unit processes the image data to be projected based on the predetermined information held in the processing information management unit. Therefore, it is possible to perform image processing on the computer side using the predetermined information set on the projector side, enabling high-speed and various image processing, and high-quality and diverse without increasing the circuit on the projector side A simple image can be projected.

  Further, in the projector system according to a specific aspect of the present invention, the image data after being processed by the correction processing unit is output to the projector via the input / output unit and the interface unit. In this case, since the predetermined information and the image data can be exchanged using a common path, the connection between the projector and the computer can be simplified.

  In another specific aspect of the present invention, the information processing unit further includes an information input unit for setting, in the processing information management unit, the content of processing performed on the image data to be projected by the operator. In this case, the operator can arbitrarily set or correct the content of the process performed on the image data to be projected by the projector.

  In another specific aspect of the present invention, the input / output unit and the interface unit are connected via a communication network. In this case, users of a plurality of computers on the communication network can share the projector.

[First Embodiment]
The projector system according to the first embodiment of the present invention will be specifically described below with reference to the drawings.

  FIG. 1 is a block diagram illustrating the structure of the projector system according to the first embodiment. The projector system 10 includes a projector 30 for projecting an image on a screen (not shown), and a computer 50 connected to the projector 30 for performing image processing and the like.

  The projector 30 includes, as an optical system of a projection unit, an illumination device 31 that generates white illumination light, a liquid crystal light valve 32 that is a light transmission type light modulation device that is illuminated by illumination light from the illumination device 31, and liquid crystal. A projection lens 33 which is a projection optical device for projecting image light from the light valve 32 onto a screen (not shown) is provided. In addition, the projector 30 has, as a circuit system, an interface unit 34 that exchanges data with the outside, and a driver circuit that generates a drive signal for the liquid crystal light valve 32 based on image data received via the interface unit 34. 35, a memory 36 that is a storage unit that stores setting information regarding image processing, and a buffer circuit 37 that temporarily stores image data as needed before being transferred to the driver circuit 35. A light source driving circuit 38 for the illumination device 31 and a main control circuit 100 that comprehensively controls the overall operation of the projector 30 are provided. Here, the interface unit 34, the memory 36, and the buffer circuit 37 are an interface unit 40 formed on an integrated board. The interface unit 40 is detachably fitted into the case 42 and has the same function but different standards. The interface unit can be replaced.

  In the projector 30, the illumination device 31 includes a light source lamp, a concave mirror, a condenser lens, and the like, and uniformly illuminates the entire surface of the liquid crystal light valve 32 with white light. The liquid crystal light valve 32 is composed of a color liquid crystal panel in which RGB filters are arranged in each pixel, and the illumination light incident on the liquid crystal light valve is modulated on a pixel basis in accordance with a drive signal input to the liquid crystal light valve. The The projection lens 33 is a zoom lens that projects the color image formed on the liquid crystal light valve 32 onto the screen at an appropriate magnification, and the magnification at the time of projection can be appropriately changed by manual or electric control.

  The interface unit 34 is connected to a connector 43 exposed outside the case 42 of the projector 30. The connector 43 is not limited to a specific type, and a plurality of appropriate connectors can be prepared according to the data communication format (high-speed serial interface, parallel data interface, etc.) with the computer 50. The interface unit 34 is for transferring various data such as image data and setting information, and does not perform special image processing on the image data input via the connector 43.

  The driver circuit 35 is a drive circuit for the liquid crystal light valve 32 and forms an image signal, that is, a drive signal necessary for driving the liquid crystal light valve 32 based on the image data received from the interface unit 34. Therefore, the driver circuit 35 includes, for example, a gate driver and a data driver that respectively form a gate signal for selecting a display pixel from image data and a data signal corresponding to the display state of each pixel.

  First, the memory 36 stores various connection information regarding the projector 30. This connection information includes a) a product code related to the model type of the projector 30, b) a display format related to resolution, refresh rate, and the like, a signal transfer method in data communication, and the like. Secondly, the memory 36 stores correction parameters that are correction information set in the projector 30. The correction parameters include, for example, a) shape correction data related to corrections such as trapezoid correction, pincushion distortion correction, and zoom adjustment, b) resolving correction data related to corrections such as edge enhancement and sharpness, and c) color unevenness, It includes color correction data relating to gamma, color temperature, screen color cancellation, d) data for contrast correction, and e) data for brightness correction.

  When the computer 50 is connected to the projector 30, connection information such as a display format is read from the memory 36 and read into the computer 50 via the interface unit 34. Similarly, correction parameters such as shape correction data are read from the memory 36 and read into the computer 50 via the interface unit 34. Note that the former connection information is data that cannot be rewritten in principle, but the latter correction parameter is data that can be rewritten from the computer 50 side, for example. The latter correction parameter can also be set independently on the projector 30 side. That is, correction parameters such as trapezoidal correction of the projected image by the projector 30 and pincushion distortion correction can be manually set by the user using operation keys provided on the projector 30. Further, the correction parameters are set using an automatic measurement device for the installation angle and screen color provided in the projector 30, an automatic calculation device for correction amounts such as keystone correction and display color based on measurement values, an automatic setting device for such correction amounts, and the like. It can also be automatically stored in the memory 36.

  The buffer circuit 37 temporarily stores image data and the like when data communication is performed between the projector 30 and the computer 50. Such a buffer circuit 37 is necessary when the standard of the image data sent from the computer 50 side does not match the standard of the image data used by the projector 30 and the signal processing is delayed on the projector 30 side. Become. Therefore, when the signal processing on the projector 30 side is sufficiently fast, for example, when no substantial image processing is performed at the interface unit 34, the buffer circuit 37 is not necessary.

  The light source driving circuit 38 controls the lighting of the light source lamp provided in the illumination device 31 and operates in an appropriate light emission state while preventing the light source lamp from being heated.

  The main control circuit 100 controls the operation of the interface unit 34. When there is a request for reading connection information or correction parameters from the computer 50 side, the main control circuit 100 reads these information from the memory 36 and outputs the information to the computer 50 side. . Further, when there is a correction parameter correction request from the computer 50 side, the main control circuit 100 reads the correction information from the computer 50 side and stores it in the memory 36.

  The connector 43 connected to the interface unit 34 conforms to the data communication specifications used in the interface unit 34. For example, a serial connector corresponding to USB, IEEE 1394, etc., a parallel connector corresponding to DVI, etc. are adopted. Is done.

  The computer 50 is composed of, for example, a general personal computer, and includes a central processing unit 51 that performs arithmetic processing and control, a storage unit 52 that includes a memory and a recording medium, and an input / output unit that communicates with the outside. An interface unit 53 and an input / output device 54 for an operator to input and output information are provided. The interface unit 53 includes a connector 43 for enabling communication with the interface unit 34 provided on the projector 30 side.

  In recent years, personal computers have remarkably improved processing capability, and not only can send image data from the computer 50 side, but also high-speed various image processing such as keystone correction required due to the installation conditions of the projector 30 and the like. And it can be done precisely. In other words, the image correction function of the conventional projector is handled on the computer 50 side, so that the built-in circuit of the projector 30 can be made simple and inexpensive while preventing deterioration of the image quality of the projected image. Therefore, a program for reading correction parameters and the like from the projector 30 and performing necessary image processing on the image data in advance is installed in the computer 50.

  FIG. 2 is a block diagram illustrating the functional structure of the computer 50 shown in FIG. The computer 50 includes an image data forming unit 61 that generates image data, an image output unit 63 that converts the image data formed by the image data forming unit 61 into a display format suitable for projection by the projector 30, and a post-conversion process A correction processing unit 62 that performs correction processing on the image data, an input / output control unit 64 that converts the image data output from the image output unit 63 into an appropriate communication format and outputs it, a correction processing unit 62, and input / output control The correction control part 65 which controls operation | movement of the part 64, and the correction value input part 66 which sets the content of the correction process in the correction process part 62 are provided.

  Here, the image data forming unit 61 mainly corresponds to the central processing unit 51, the storage unit 52, and the like of FIG. 1, and generates image data accompanying the activation and operation of various application programs. The image data generated by the image data forming unit 61 has a format such as TIFF, JPEG, MPEG, or BMP.

  The image output unit 63 mainly corresponds to the central processing unit 51, the storage unit 52, and the like of FIG. 1, generates an output image as a general computer, and based on connection information read from the projector 30. Perform signal processing. Specifically, first, the image data output from the image data forming unit 61 is arranged or superimposed according to the operation state of the application software, and then converted into RGB image data. Next, based on the display format information set in the projector 30, scaling processing corresponding to the standard of the projector 30 is performed to convert the RGB image data into image data suitable for display on the projector 30. . Note that the connection information such as the above-described display format is captured in the image output unit 63 in advance via the input / output control unit 64 and the correction control unit 65.

The correction processing unit 62 mainly corresponds to the central processing unit 51, the storage unit 52, and the like of FIG. 1, and performs image processing based on the correction parameters read from the projector 30. Although described in detail later, the correction parameter is stored in the correction control unit 65, and the correction processing unit 62 performs processing corresponding to the correction parameter based on a command signal from the correction control unit 65. Specifically, shape corrections such as keystone correction, distortion aberration, and zoom are performed based on various correction parameters such as shape correction data, resolution correction data, color correction data, contrast correction data, and brightness correction data. In addition, resolution correction such as edge enhancement and sharpness is performed, and color correction in a broad sense such as color unevenness, gamma, color temperature, and screen color cancellation is performed.

  The input / output control unit 64 is an input / output unit mainly corresponding to the interface unit 53 of FIG. 1. For example, as a high-speed serial interface, the image data from the correction processing unit 62 is converted into a signal format suitable for communication with the projector 30. Convert.

  The correction control unit 65 is a processing information management unit that mainly corresponds to the central processing unit 51, the storage unit 52, and the like of FIG. 1, and at the stage of detecting that the projector 30 and the computer 50 are connected, input / output A request for reading connection information and correction parameters is output to the projector 30 via the control unit 64. In response to this, on the projector 30 side, the main control circuit 100 causes the interface unit 34 to operate appropriately at an appropriate timing to read out connection parameters such as display format in the memory 36 and correction parameters such as shape correction data, and the computer. Output to 50 side. On the computer 50 side, the correction control unit 65 captures connection information and correction parameters via the interface unit 53. If there is no correction parameter in the memory 36, the correction control unit 65 does not receive the correction parameter, but in this case, the correction parameter is processed as unset and no correction image processing is performed.

  The correction value input unit 66 is an information input unit mainly corresponding to the input / output device 54, the central processing unit 51, and the like of FIG. 1, and sets correction parameters according to the operation of the computer 50 operator. The correction parameters set according to the operation of the operator in this way are output to the projector 30 side via the correction control unit 65 and the input / output control unit 64. In response to this, on the projector 30 side, the main control circuit 100 appropriately operates the interface unit 34 at an appropriate timing, and stores the correction parameters received from the computer 50 side in the memory 36. That is, the content of the correction processing in the correction processing unit 62 can be corrected by reflecting the intention of the operator of the computer 50.

  Hereinafter, the operation of the projector system 10 according to the first embodiment will be described. First, when the projector 30 and the computer 50 are turned on and connected to each other via the connectors 43 and 45, the projector 30 side connects to the memory 36 in response to a request from the computer 50 side. Information and correction parameters are output to the computer 50 side. In such a state, the software connection between the projector 30 and the computer 50 can be completed, and an appropriate image prepared on the computer 50 side can be displayed on the projector 30. A specific operation will be described. On the computer 50 side, the image output unit 63 converts the image data output from the image data forming unit 61 into the projector 30 based on the connection information such as the display format read from the projector 30. Convert to image data suitable for display. Further, the correction processing unit 62 controlled by the correction control unit 65 performs image processing such as keystone correction on the image data from the correction processing unit 62 based on the correction parameters read from the projector 30. The image data obtained in this way is output to the projector 30 via the input / output control unit 64. In the projector 30, the input image data is transferred to the driver circuit 35 through the interface unit 34 almost as it is or with a slightly changed data format. The driver circuit 35 forms a drive signal based on the image data received from the interface unit 34 and causes the liquid crystal light valve 32 to appropriately perform a display operation. On the other hand, the illumination light from the illumination device 31 enters the liquid crystal light valve 32 and uniformly illuminates the liquid crystal light valve 32. As described above, the illumination light, that is, the image light that has been modulated through the liquid crystal light valve 32 is incident on the projection lens 33 and projected onto a screen (not shown). The image projected on the screen is a high-quality image that has been subjected to processing such as keystone correction.

  The above description is about the operation when the projector 30 and the specific computer 50 are connected. However, even when the projector 30 and another computer are connected, the above-described operation is performed on such another computer. If application software for driving the projector similar to that of the computer 50 is incorporated, the correction processing for the image data as described above can be performed on the other computer side. In other words, the projector 30 can be shared by two or more computers incorporating appropriate application software, and the projector 30 can perform a projection operation as if it is performing correction processing on the projector 30 side. Can do.

[Second Embodiment]
Hereinafter, the projector system according to the second embodiment will be specifically described with reference to the drawings. Note that the projector system according to the second embodiment is obtained by changing the projector system according to the first embodiment to a communication network type. Common parts are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 3 is a block diagram illustrating the structure of the projector system according to the second embodiment. In addition to the projector 30, the projector system 210 includes a plurality of computers 250A, 250B, 250C connected to the projector 30 via a network bus (communication network) 270. That is, the single projector 30 is shared by these computers 250A, 250B, 250C. As a result, the correction parameters set in the projector 30 by the computer 250A can be used as they are in the other computers 250B and 250C, so that the convenience in sharing the projector 30 with each other is enhanced.

  Each of the computers 250A, 250B, 250C has the same structure as the computer 50 of the first embodiment shown in FIG. However, since the network bus 270 is used for communication between devices, the interface unit 53 provided in each of the computers 250A, 250B, and 250C corresponds to a network communication standard such as Ethernet (registered trademark). . Similarly, the interface unit 34 of the projector 30 corresponds to a network communication standard such as Ethernet. Further, a master-slave superiority relationship is set between these computers 250A, 250B, 250C, and if there is no permission from the master computer 250A operated by the administrator, control from other computers 250B, 250C. As a result, the operation of the projector 30 cannot be controlled. Thereby, various connection information and correction parameters stored in the memory 36 of the projector 30 can be prevented from being rewritten without permission, and the projector 30 can be shared smoothly.

  As described above, the present invention has been described according to the embodiment, but the present invention is not limited to the above embodiment. For example, in the above embodiment, the color liquid crystal light valve is illuminated with a white light source in the projector 30, but the three liquid crystal light valves are illuminated with RGB colors, and the images of the liquid crystal light valves are displayed with a cross dichroic prism. It goes without saying that the present invention can be applied to a type of projector to be combined. The light modulation device is not limited to a transmission type such as a liquid crystal light valve, but may be a reflection type. The target for projecting the image light from the projector 30 can be a rear projection screen, but can also be a front projection screen that projects an image from the front.

  Further, the image projected by the projector 30 is not limited to an original image such as a presentation image prepared inside the computer 50, but can be an image file acquired from the outside, for example, a commercial or the like in a store or a station premises. 1 can also be used for the projector system 10 shown in FIG. In this case, by adopting a server / client system using the Internet or the like, it is possible to construct a system capable of displaying various moving images at a low cost.

  In the above embodiment, the image processing performed in the computer 50 can also correct the aberration of the projection lens 33. In this case, the projection lens 33 can be made relatively inexpensive.

  In the above embodiment, if a video capture board is incorporated in the computer 50, an analog video signal or the like can be projected onto the projector 30, and a high-quality image is projected by correcting the image data on the computer 50 side. be able to.

It is a block diagram explaining the structure of the projector system of 1st Embodiment. It is a block diagram functionally explaining the structure of a computer. It is a block diagram explaining the structure of the projector system of 1st Embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Projector system, 30 ... Projector, 31 ... Illuminating device, 32 ... Liquid crystal light valve, 33 ... Projection lens, 34 ... Interface part, 35 ... Driver circuit, 36 ... Memory, 37 ... Buffer circuit, 43 ... Connector, 50 ... Computer 51. Central processing unit 52. Storage unit 53. Interface unit 54 Input / output device 61 Image data forming unit 62 Correction processing unit 63 Image output unit 64 Input / output control unit 65 ... Correction control unit 66 ... Correction value input unit 100 ... Main control circuit

Claims (11)

Projection means for projecting an image according to the input image signal;
Storage means for storing predetermined information relating to image processing to be performed on the image signal input to the projection means;
A projector comprising: an interface unit for outputting the predetermined information stored in the storage unit to the outside.   The projection unit includes an illumination device, a light modulation device illuminated by illumination light from the illumination device, and a projection optical device that projects image light from the light modulation device. The projector according to 1.   The projector according to claim 1, wherein the predetermined information includes information related to correction of an image to be input to the projection unit.   The information on the correction is correction information including at least one of a spatial deformation, color adjustment, contrast adjustment, and brightness adjustment of an image to be input to the projection unit. projector.   The projector according to any one of claims 1 to 4, further comprising a drive circuit that operates the light modulation device based on image data input from outside.   The projector according to claim 5, wherein the interface unit transfers the image data input from the outside to the drive circuit.   The projector according to claim 6, further comprising a buffer circuit that temporarily stores the image data input to the interface unit before the image data is transferred to the drive circuit. A projector according to any one of claims 1 to 7,
An input / output unit connectable to the interface unit, a processing information management unit that reads and holds the predetermined information stored in the storage unit of the projector via the input / output unit, and image data to be projected A projector system comprising: a computer having a correction processing unit that performs processing based on the predetermined information held in the processing information management unit.   9. The projector system according to claim 8, wherein the image data processed by the correction processing unit is output to the projector via the input / output unit and the interface unit.   10. The projector system according to claim 8, further comprising an information input unit configured to set, in the processing information management unit, processing contents to be performed on image data to be projected by an operator. 10. .   The projector system according to claim 8, wherein the input / output unit and the interface unit are connected via a communication network.

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