JP2004134963A - Matrix switch incorporating scan converter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a downsized matrix switch capable of easily and quickly performing adjustment of parameters and switching operations or the like even when the matrix switch receives image signals adopting different systems and various display apparatuses adopting different standards are connected to the outputs of the matrix switch. <P>SOLUTION: Scan converters 2-1 to 2-m receive image signals adopting the NTSC or RGB system via the matrix switch 1. The scan converters 2-1 to 2-m convert the received image signals into image signals of the RGB system and store the result to respective memories. The image signals stored in the memories are read in a read timing in compliance with the standards of the display apparatuses connected to the outputs and the display apparatuses 21, 22 display the signals. Connection information of the matrix switch 1, the read timing, and the image adjustment parameters or the like are stored in a nonvolatile storage section of a control section 3 and set to the matrix switch 1 and the scan converters 2-1 to 2-m. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a matrix switch having a built-in video signal converter (hereinafter referred to as a scan converter) for selecting a plurality of video signals and outputting them to one or more displays.
[0002]
[Prior art]
A matrix switch is used as a switch for selecting a plurality of video signals and outputting them to one or a plurality of displays.
FIG. 4 shows an example of using a matrix switch.
The matrix switch has a plurality of human terminals and a plurality of output terminals, selects a plurality of signals input from an input terminal, and outputs the selected signal from an arbitrary output terminal.
For example, the matrix switch shown in FIG. ₁ ~ I ₄ And four output terminals O ₁ ~ O ₄ And the input terminal I ₁ ~ I ₄ Are connected to cameras C1 to C4, respectively, and output terminals O ₁ ~ O ₄ Are connected to display devices D1 to D4, respectively.
By setting the connection of the changeover switch SW, four video signals input from the cameras C1 to C4 are ₁ ~ O ₄ Output from any output terminal.
For example, the video signal of the camera C1 is ₁ ~ O ₄ Can be output from one output terminal, or can be output from all terminals. Therefore, when four input signals are output from four output terminals as in this example, the output can be switched in 4 × 4 × 4 × 4 = 256 combinations.
The matrix switch is used, for example, in a studio of a television station to display images shot by a plurality of television cameras on a plurality of television monitors.
[0003]
On the other hand, a video signal used in a general television is called an NTSC signal, and a luminance signal, a chrominance signal, and a synchronization signal are superimposed on one signal. A video signal generally used in a display device such as a computer is called an RGB signal, and is composed of RGB signals and horizontal and vertical synchronization signals. The NTSC signal and the RGB signal are not compatible. In recent years, it has been active to display television images, which are NTSC signals, on a computer display or projector that uses RGB signals.
Therefore, it is necessary to convert the input frequency of the video signal to another frequency, such as converting an NTSC signal to an RGB signal. To perform the above conversion, a scan converter (also referred to as a scan converter) is used.
FIG. 5 shows a usage example of the scan converter (scan converter). As shown in the figure, an NTSC signal used in a television receiver is input to a scan converter and converted into an RGB signal, so that it can be displayed on a display device such as a personal computer.
[0004]
FIG. 6 shows a schematic configuration of the scan converter. The operation of each part of the scan converter will be described with reference to FIG.
An image signal based on the NTSC signal is input to an input terminal of the scan converter. As described above, in the NTSC signal, a luminance signal, a chrominance signal, and a synchronization signal are superimposed on one signal.
The input signal is divided into two. One of the divided signals is for a video signal, and the other is for a synchronization signal.
A signal used for video is input to the YC separation circuit 11 via the buffer Bf. Y indicates a luminance signal, and C indicates a color signal. The signal is separated into a Y (luminance) signal and a C (color) signal by a YC separation circuit 11.
The Y signal and the C signal are input to the color space converter 12, converted into analog RGB signals, and input to the A / D converter 14.
On the other hand, the signal used for the synchronization signal is input to the synchronization separation circuit 13 and divided into a horizontal synchronization signal HD and a vertical synchronization signal VD.
HD and VD are input to the read timing generation circuit 15 and input to the A / D converter 14 at timing synchronized with the NTSC signal.
[0005]
The A / D converter 14 associates the video display position with the timing based on the input analog RGB signal, the horizontal synchronization signal HD synchronized with the NTSC signal, and the vertical synchronization signal VD, and outputs a digitized RGB signal. . The output digital RGB signals are temporarily stored in the memory 16.
When the video signal is stored in the memory 16, the horizontal synchronizing signal HD and the vertical synchronizing signal VD become unnecessary. This is because the information of the horizontal synchronizing signal HD and the vertical synchronizing signal VD is converted into the address of the memory 16.
The RGB signals stored in the memory 16 are output based on a timing signal from the read timing generation circuit 17. The read timing generation circuit 17 is a circuit that outputs a horizontal synchronizing signal HD and a vertical synchronizing signal VD at a timing synchronized with an image signal of a display device connected to the output side of the scan converter. That is, the video signal stored in the memory 16 is called from each stored address at a timing synchronized with the horizontal synchronization signal HD and the vertical synchronization signal VD of the display device, and is output as an RGB signal.
The digital RGB signals output from the memory 16 are input to a D / A converter 18, converted into analog RGB signals, and output from an output terminal.
At the same time as the above, the horizontal synchronization signal HD and the vertical synchronization signal VD are output from the read timing generation circuit 17 at timing synchronized with the image signal of the display device, and output from the output terminal.
By connecting the five signals of the RGB signal, the horizontal synchronizing signal HD, and the vertical synchronizing signal VD to the display device, an image corresponding to the NTSC image signal input from the input terminal of the scan converter is displayed on the display device. Is done.
[0006]
On the other hand, recently, even for an RGB-compatible display, signals of various standards have been used due to differences in resolution. For example, signals of standards such as VGA, SVGA, XGA, SXGA, and UXGA have been used. Is being used.
As a result, the following problems have occurred.
For example, if a low-resolution VGA signal is directly input to a high-resolution UXGA-compatible display, it is displayed at a low VGA-level resolution, and the high-resolution function of the display is not useful.
In order to cope with this, the read timing generation circuit 17 incorporated in the scan converter needs to be adapted to the resolution of the display device. If a UXGA compatible display is connected, the timing for reading the RGB signals from the memory, that is, the timing for outputting the horizontal synchronizing signal HD and the vertical synchronizing signal VD must be synchronized with the UXGA signal. Because. That is, a single scan converter cannot support display devices having different standards. Therefore, it is necessary to prepare as many scan converters as the number of standards of the display device connected to the output side, which is inconvenient.
Therefore, there is known a matrix switch (hereinafter abbreviated as SCMS) with a built-in scan converter, which is a combination of the above matrix switch and scan converter (for example, see Patent Document 1).
[0007]
[Patent Document 1]
JP-A-5-165449
[0008]
The receiving circuit 4, the NTSC / RGB converter 3, the analog switch 5, and the changeover switch 6 described in FIG. 1 of the above document correspond to the SCMS, and the receiving circuit 4, the NTSC / RGB converter 3 corresponds to the scan converter. Correspondingly, the analog switch 6 and the changeover switch 7 correspond to matrix switches, respectively.
In the document described above, the NTSC signal from the VTR 9 is converted into an RGB signal by the NTSC / RGB converter 3 and output to the CRT display 2 via the analog switch 5, and the RGB from the computer (PC) 10. The signal is output to the CRT display 2 via the receiving circuit 4 and the analog switch 5. Then, by switching the analog switch 6, the video signal from the VTR 9 or the PC 10 is displayed on the CRT display 2 (corresponding to RGB signals) connected to the output side.
Such SCMS is used, for example, in exhibitions that introduce new products by making full use of images.
[0009]
[Problems to be solved by the invention]
In the document described in FIG. 1 of the above document, if the display 2 on the output side is, for example, a display of the SXGA standard and an input from the PC 10 is a signal of the VGA standard, a signal of the VGA standard is provided between the PC 10 and the analog switch 5. An RGB (VGA) / RGB (SXGA) conversion unit for converting a signal into an SXGA standard signal is required. Also, the NTSC / RGB converter 3 needs to be an NTSC / RGB (SXGA) converter.
Here, when the display 2 on the output side is changed from the SXGA standard to the UXGA standard, the RGB (VGA) / RGB (SXGA) conversion unit is converted to an RGB (VGA) / RGB (UXGA) conversion scan converter. The NTSC / RGB (SXGA) conversion section must be replaced with an NTSC / RGB (UXGA) conversion scan converter. That is, the scan converter must be replaced each time the output display standard changes, which is very inconvenient.
In addition, in order to display a beautiful image on the display screen, it is necessary to adjust various parameters such as “hue”, “color density”, “contrast”, and “brightness (brightness)” according to the display device. is there.
[0010]
In particular, when the projector PR is connected to the output side, an image is projected upward or downward from the projector toward the screen. Therefore, in order to project the image on the screen as a square without distortion, in the case of upward irradiation, the image from the projector is gradually narrowed toward the upper side, and in the case of downward irradiation, as the image approaches the lower side. It is necessary to make adjustment so that the width gradually becomes narrower (this is called trapezoidal correction or pincushion control).
For these adjustments, a monitor or a projector, which is originally a display device, may be provided with an adjustment knob, and may be adjusted there. However, when such a system is used in an exhibition, a video studio, or the like, usually, the display device is installed at a high position that is out of reach of the audience, or is located at a distance from each other so that many viewers can see it. It is often provided.
In such a case, it is inconvenient that the knob provided on the display device cannot adjust each parameter or is difficult. A knob (trimmer) for adjusting each parameter may be provided inside the SCMS. However, there are a large number of parameters for adjustment, and the knob is provided according to the number of displays to which the SCMS is connected, that is, the number of terminals on the output side. Therefore, as a high-performance SCMS capable of inputting / outputting a large number of devices requires an enormous number of trimmers inside, it hinders miniaturization of the device.
[0011]
As described above, when an NTSC signal or RGB signal is input and a projector, a display device of various standards such as VGA and SXGA or the like is connected to the output side, trapezoid correction is performed according to the projector, and each display is adjusted. It is necessary to adjust various parameters such as “hue”, “color intensity”, “contrast”, “brightness (brightness)” according to the device, and to select a scan converter according to the standard of the display device. This makes parameter adjustment and switching operations extremely complicated.
In particular, SCMS is often used in exhibitions and the like that introduce new products as described above. At the exhibition site, it is required to perform parameter adjustment and switching operations quickly. Was unable to respond to the request.
Further, in order to adjust various parameters, it is necessary to provide a knob or the like for adjusting each parameter inside the SCMS as described above, but this has hindered miniaturization.
In view of the above circumstances of the present invention, even when an NTSC signal or an RGB signal is input from the input side and various displays or projectors of different standards are connected to the output side, various parameters are set. It is an object of the present invention to provide a matrix switch having a built-in scan converter that can easily and quickly perform the adjustment and switching operation of the device and can reduce the size of the device.
[0012]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the present invention provides a matrix switch having a built-in scan converter, a switching circuit for selectively inputting an NTSC or RGB image signal connected to an input side to the scan converter, And control means for controlling switching of the switching circuit.
A conversion unit for converting the input NTSC image signal into an RGB image signal; a memory for storing the converted RGB image signal or the input RGB image signal; An image readout circuit having a plurality of timing signal generation circuits for reading out image signals from the memory at a readout timing corresponding to a standard of a display device connected to the output side, and an image adjustment of the image signals read out from the memory And an image adjustment circuit for performing the above.
Each read timing generation circuit provided in the image read circuit generates a horizontal synchronizing signal (HD) and a vertical synchronizing signal (VD) at timings according to the respective standards of VGA, SVGA, XGA, SXGA, and UXGA.
The image adjustment circuit adjusts the brightness, contrast, color tone, etc. of the image read from the memory.
Further, the control means selects a first setting means for setting a switching state of the switching circuit, and a timing signal generation circuit provided in an image reading circuit of the scan converter, and sets a read timing by the image reading circuit. A second setting unit for setting and setting an image adjustment parameter of the image adjustment circuit; and a non-volatile storage unit for storing the readout timing and the image adjustment parameter corresponding to a switching state of the switching circuit. Provide.
The control means reads the switching state of the switching circuit from the non-volatile storage unit, sets the switching circuit, and stores the switching state in correspondence with the switching state. And read out the image adjustment parameters corresponding to the input-side image signal and the output-side display device, and read out the timing signal corresponding to the read-out timing from among the timing generation circuits provided in the image read-out circuit. A generation circuit is selected, and read timing by the image read circuit is set. Further, image adjustment parameters of the image adjustment circuit are set.
[0013]
In the present invention, since the above-mentioned configuration is adopted, even if an NTSC image signal or an RGB image signal is input from the input side and a display device of various standards is connected to the output side, the input image signal is transmitted through the switching circuit. It can be handled by setting to be connected to the input terminal of the corresponding scan converter, and setting the read timing of the scan converter, image adjustment parameters, etc. according to the standard of the display device connected to the output side. it can. Therefore, it is not necessary to prepare a scan converter in accordance with the method of the input image signal and the standard of the display device connected to the output side.
In addition, the switching state of the switching circuit, the readout timing, image adjustment parameters, and the like are set in advance in accordance with the method of the image signal connected to the input side and the display device connected to the output side. By storing the information in the non-volatile storage unit, by reading the setting information from the non-volatile storage unit, the switching circuit, readout timing, image adjustment parameters, and the like can be set quickly.
Furthermore, since the read timing and image adjustment parameters of a plurality of scan converters are set by a common control unit, even if the number of input / output terminals and the number of built-in scan converters increase, The number of knobs or the like for adjusting each parameter can be reduced.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a diagram showing the overall configuration of a matrix switch (SCMS) incorporating a scan converter according to an embodiment of the present invention.
In the figure, reference numeral 1 denotes a matrix switch, and the matrix switch 1 has a plurality of input terminals MI as described above. ₁ ~ MI _n And multiple output terminals MO ₁ ~ MO _2m , And according to the setting of the matrix switch 1, the input terminal I of the SCMS ₁ ~ I _n The image signals of the NTSC system or the RGB system input from the scan converter 2-1 to 2-m can be selectively input to the NTSC input terminals and the RGB input terminals of the scan converters 2-1 to 2-m.
The scan converters 2-1 to 2-m include a circuit for converting an NTSC image signal into an RGB image signal, a memory for storing the RGB image signal, an image adjustment circuit, and an SCMS, as described later. The display device connected to the output side of the device has an image readout circuit for reading out image data from the memory at a readout timing according to the standard.
[0015]
Reference numeral 3 denotes a control unit, and 4 denotes a setting unit. The setting unit 4 sets the connection state of the matrix switch 1, and sets image adjustment parameters and image adjustment parameters of image adjustment circuits included in the scan converters 2-1 to 2-m. The read timing and the like by the read circuit are set. The output side of the scan converters 2-1 to 2-m, that is, the SCMS output terminal O ₁ ~ O _m Is connected to a display device such as a monitor 21 and a projector 22, and displays image signals output from the scan converters 2-1 to 2-m.
The control unit 3 includes a nonvolatile storage unit such as a flash memory. The control unit 3 stores the setting of the setting unit 4 in the nonvolatile storage unit, controls the connection state of the matrix switch 1, and controls the input terminal I ₁ ~ I _n Is switched so that the image signals of the NTSC system or the RGB system input from the scan converter 2-1 to 2-m are connected to the set input terminals. Further, according to the setting of the setting unit 4, the parameters of the image adjustment circuits of the scan converters 2-1 to 2-m and the read timing of the image read circuit are set.
[0016]
In FIG. 1, an NTSC or RGB image signal is input to an input terminal I. ₁ ~ I _n To SCMS.
The image signal can be selectively input to an NTSC terminal or an RBG terminal of any of the scan converters 2-1 to 2-m by setting a connection state of the matrix switch 1.
When an image signal of the NTSC system is input from the NTSC terminal, the scan converters 2-1 to 2-m convert the image signal of the NTSC system into an image signal of the RGB system, store the image signal in the memory, and connect to the output side. The image data is read from the memory and output at a read timing according to the standard of the display device to be executed.
When an RGB image signal is input from an RGB terminal, the scan converters 2-1 to 2-m store the RGB image signal in a memory and comply with the standard of a display device connected to the output side. At the read timing, the image data is read from the memory and output.
Outputs of the scan converters 2-1 to 2-m are output to an output terminal O ₁ ~ O _m Through the display device such as the monitor 21 and the projector 22 connected to the output side. ₁ ~ I _n Is displayed.
The connection of the matrix switch 1, the read timing from the memory, the image quality of the image, the image profile, the trapezoidal correction parameters, and the like can be set from the setting unit 4. These setting information are stored in the nonvolatile storage of the control unit 3. It is stored in the section.
Therefore, the setting information is stored in advance in the non-volatile storage unit of the control unit 3, and when the image is displayed on the display device, the setting information is read out from the non-volatile storage unit to be set in advance. An image based on the setting information can be displayed.
[0017]
FIG. 2 is a diagram showing a configuration example of the scan converters 2-1 to 2-m.
The scan converters 2-1 to 2-m shown in FIG. 2 have basically the same configuration as the one shown in FIG. 6 and the operation is also the same. An RGB input terminal for inputting a signal is provided.
Further, in addition to the A / D converter 14a for converting the RGB signal output from the color space converter 12 shown in FIG. 6 into a digital signal, the A / D converter for converting the RGB signal input from an RGB input terminal into a digital signal. The converter 14b is provided. As described above, there are five RGB signals, R, G, B, VD, and HD, which are directly input to the A / D converter 14b.
Further, between the memory 16 and the D / A converter 18, an image adjustment circuit 19 for adjusting the image quality and the like (brightness, contrast, saturation, hue, sharpness, etc.) of the image signal is provided.
The image adjustment circuit 19 includes a table usually called a look-up table (LUT), and converts input image information based on the table data and outputs it. The table data can be rewritten by the control unit 3, and the setting unit 4 sets the image adjustment parameters stored in the table.
[0018]
Further, it comprises a plurality of read timing generation circuits for generating a read timing signal corresponding to the standard of the display device connected to the output side, such as a VGA timing generation circuit, an XGA timing generation circuit, and a UXGA timing generation circuit. An image reading circuit 20 is provided.
The read timing generation circuit generates a horizontal synchronizing signal (HD) and a vertical synchronizing signal (VD) at timings according to respective standards such as VGA, SVGA, XGA, SXGA, and UXGA.
Then, the table data of the image adjustment circuit 19 is rewritten by the image adjustment parameter control signal output from the control unit 3, and the image adjustment circuit 19 reads the image read from the memory 16 based on the image adjustment parameters stored therein. Adjust the image quality of the signal.
The timing signal selection control signal, the trapezoidal correction control signal, and the image contour control signal output from the control unit 4 are given to the image reading circuit 20. The image readout circuit 20 selects a readout timing signal generation circuit based on the timing signal selection control signal, and supplies an output of the selected timing generation circuit to the memory 16. The timing signal is adjusted by the trapezoidal correction control signal and the image contour control signal.
[0019]
FIG. 3 is a diagram illustrating a configuration example of the control unit and the setting unit illustrated in FIG.
The control unit 3 includes a processing device 31 including a CPU and the like, and a non-volatile storage unit 32. As described above, the non-volatile storage unit 32 stores the connection state of the matrix switch 1 set by the setting unit 4, Setting information such as an image adjustment parameter of the adjustment circuit 19 and a read timing by the image read circuit 20 is held.
The processing device 31 stores the setting information set by the setting unit 3 in the nonvolatile storage unit 32 and controls the connection state of the matrix switch 1 based on the setting information stored in the nonvolatile storage unit 32. At the same time, it controls the parameters of the image adjustment circuit 19 of the scan converters 2-1 to 2-m, the read timing of the image read circuit 20, and the like.
The setting unit 4 includes a setting switch 41 for setting the connection state of the matrix switch 1, an image adjustment parameter setting unit 42, and an output setting unit 43.
The setting switch 41 includes a plurality of switches 41a arranged in a matrix, and presses an intersection (portion indicated by a circle in the figure) of an input side and an output side of the switch 41a to obtain the connection information. Is sent to the processing device 31, and the processing device 31 receives the input terminal MI of the matrix switch 1. ₁ ~ MI _n And output terminal MO ₁ ~ MO _2m Are selectively connected based on the connection information.
[0020]
The image adjustment parameter setting unit 42 includes a setting button 42a for image adjustment, a selection button 42b, and a storage button 42c. After selecting a parameter to be adjusted with the selection button 42b and adjusting the parameter with the setting button 42a, By pressing the storage button 42c, the setting information is stored in the nonvolatile storage unit 32. Then, the image adjustment circuits 19 of the scan converters 2-1 to 2-m are set by these parameters.
The output setting unit 43 includes a scan select button 43a for selecting a scan timing of the image reading circuit 19 of the scan converters 2-1 to 2-m, a select button 43b, and setting buttons 43c for trapezoid correction and image outline setting. , A storage button 43d, the scan select button 43a is used to set the scan timing, the select button 43b is used to select a setting item to be adjusted, and the set button 43c is used to set a trapezoidal correction parameter and an image adjustment parameter. I do.
The setting information is stored in the nonvolatile storage unit 32 by pressing the storage button 43d. The read timing and the like in the image read circuit 19 of the scan converters 2-1 to 2-m are set based on the setting information.
[0021]
Next, how to use the SCMS of this embodiment will be described.
Before use at a site such as an exhibition, adjustment of image parameters, readout timing, and the like is performed in advance as described below.
Input terminal I of the SCMS shown in FIG. ₁ ~ I _n , An image of the NTSC system or the RGB system is input. Also, the output terminal O of SCMS ₁ ~ O _m And a display device such as a monitor 21 and a projector 22.
Then, the setting switch 41 of the setting unit 4 inputs the NTSC or RGB image signal to the corresponding input terminal (NTSC input terminal or RGB input terminal) of the scan converters 2-1 to 2-m. The connection state of the matrix switch 1 is set as described above.
Further, the scan converters 2-1 to 2--2 are operated by the scan select button 43a of the output setting section 43 of the setting section 4 so that the image signal is read from the memory 16 at a read timing corresponding to the standard of the display device. The read timing of the m image read circuit 19 is set.
After the above settings are made, the storage button 43e of the output setting section 43 is pressed. Thereby, the readout timing corresponding to the connection state of the matrix switch 1 set by the setting switch 41 is stored in the nonvolatile storage unit 32 of the control unit 3.
[0022]
For example, the input terminal I of FIG. ₁ From the scan converter 2-m, that is, the output terminal O of the SCMS. _m When the VGA standard projector 22 is connected, the connection state of the matrix switch 1 is changed to [input terminal I ₁ ] → [NTSC input terminal of scan converter 2-m], and the read timing of the image read circuit 19 is set to VGA.
When the storage button 43d is pressed in this state, the following data is stored in the nonvolatile storage unit 32, for example.
▲ 1 ▼ [I ₁ → SC2-m, 1]: [VGA]
Here, "I ₁ Is the input terminal I ₁ , “SC2-m, 1” means the NTSC input terminal of the scan converter 2-m, and “→” indicates the connection relationship. That is, [I ₁ → SC2-m, 1] is the input terminal I ₁ Is connected to the NTSC input terminal of the scan converter 2-m. VGA means that it is a VGA standard.
[0023]
Next, image adjustment parameters, keystone correction parameters, and the like are set while viewing the image displayed on the projector 22 connected to the output side of the SCMS.
To set the image adjustment parameters, a selection button 42a of the image adjustment parameter setting unit 42 is pressed. As a result, an image adjustment menu for selecting luminance, contrast, saturation, hue, sharpness, and the like is displayed on the screen of the projector 22.
The menu is displayed by, for example, writing image data for displaying a menu image into the memory 16 of the scan converter 2-m by the processing device 31 of the control unit 3 and superimposing the image data on the display screen of the projector 22. Can be realized.
[0024]
The user selects a parameter to be adjusted from the menu using the selection button 42b of the image adjustment parameter setting unit 42 of the setting unit 4. Then, while watching the image displayed by the projector 22, the parameter is increased or decreased by the setting button 42a, and the parameter is set to an appropriate value.
For example, when adjusting the brightness, “brightness” is selected from the menu, and the brightness of the screen is adjusted with the increase / decrease button 42a while viewing the screen. At the same time as this adjustment, the look-up table of the image adjustment circuit 19 is rewritten, and the image displayed by the projector 22 changes.
When the brightness of the image is set to an appropriate value, the storage button 42c of the image adjustment parameter setting unit 42 is pressed, and the set brightness is stored in the nonvolatile storage unit 32.
As a result, a luminance value is added to the non-volatile storage unit 32 to the data of (1) as follows.
▲ 1 ▼ [I ₁ → SC2-m, 1]: [VGA]: [brightness value d1]
[0025]
Similarly, similar settings are made for the contrast, saturation, hue, and sharpness, and stored in the nonvolatile storage unit 32.
Accordingly, the data of (1) in the nonvolatile storage unit 32 is as follows.
▲ 1 ▼ [I ₁ → SC2-m, 1]: [VGA]: [brightness value d1: contrast d2: saturation d3: hue d4: sharpness d5]
The connection setting of the matrix switch 1 and the setting of the read timing of the image read circuit 20 may be set by displaying a menu screen on the screen displayed by the projector as described above.
[0026]
Next, keystone correction is performed. When the projector 22 is connected to the output side as described above, the image is projected upward or downward from the projector toward the screen. Must be adjusted so that the image from the projector gradually narrows toward the upper side, and in the case of downward irradiation, the image gradually narrows toward the lower side.
To perform keystone correction, image contour adjustment, and the like, the selection button 43b of the output setting unit 43 is pressed. As a result, a menu for selecting a setting item is displayed on the screen of the projector 22.
Next, the user selects a setting item from the above menu by the selection button 43b of the output setting unit 43, and increases or decreases the parameter by the setting button 43c while watching the image displayed by the projector 22, and sets the parameter to an appropriate value. I do.
For example, to perform keystone correction, select “keystone correction” from the above menu, and adjust the length of the upper side, the lower side, the length in the vertical direction, and the like by using the setting button 43c while viewing the screen. At the same time as this adjustment, the image displayed by the projector 22 changes.
When keystone correction is performed and an appropriate screen is displayed by the projector 22, the storage button 43d is pressed, and the set keystone correction parameter is stored in the nonvolatile storage unit 32.
Thus, the data of (1) in the nonvolatile storage unit 32 is as follows.
▲ 1 ▼ [I ₁ → SC2-m, 1]: [VGA]: [luminance value d1: contrast d2: saturation d3: hue d4: sharpness d5]: [trapezoid correction parameters α1, α2,...]
[0027]
The above description is for the case where the projector is connected to the output side. However, when the monitor 22 is connected to the output side, the connection state of the matrix switch 1, the image reading timing, and the image Set the adjustment parameters and image outline adjustment parameters.
For example, the input terminal I of FIG. _k From the scan converter 2-1, ie, the output terminal O of the SCMS. ₁ When a monitor 21 of the UXGA standard is connected, the above settings are made and stored. For example, the following data (2) is stored in the nonvolatile storage unit 32.
▲ 2 ▼ [I _k → SC2-1, [UXGA]: [Brightness value d11: Contrast d12: Saturation d13: Hue d14: Sharpness d15]: [Image section adjustment parameters β1, β2,...]
In the above description, SC2-1 and SC2-1 mean the RGB terminals of the scan converter 2-1.
The setting information stored in the nonvolatile storage unit 32 is retained even when the power is turned off. When the power is turned on again, the setting information is read out, and the matrix switch 1, the scan converters 2-1 to 2- m can be reset based on the setting information.
[0028]
The above setting is performed, and the setting information is stored in the nonvolatile storage unit 32. At an exhibition site or the like, the SCMS input terminal I ₁ ~ I _n Is connected to a device or the like that generates an image signal of the NTSC system or the RGB system.
Also, the output terminal O of SCMS ₁ ~ O _m To the monitor and projector according to the above settings.
Then, the data of (1) and (2) stored in the non-volatile storage unit 32 are read, and the matrix switch 1, the image adjustment parameters of the image adjustment circuit 19 of the scan converters 2-1 and 2-m, and the image readout are read. The read timing and the like of the circuit 20 are set by the setting information.
This makes it possible to display a beautiful image on the screen of the display at a site such as an exhibition without special setting.
[0029]
In the above, the input terminal I ₁ Input the NTSC image signal from the _m In the above description, the setting when the VGA standard projector 22 is connected has been described. ₁ , An NTSC image signal is input from the _m In the case where a monitor of the SVGA standard is sometimes connected, the following data (3) may be stored in the nonvolatile storage unit 32 in addition to the data (1) and (2). .
▲ 3 ▼ [I ₁ → SC2-m, 1]: [SVGA]: [brightness value d1 ': contrast d2': saturation d3 ': hue d4': sharpness d5 ']: [image section adjustment parameters β1', β2 ',...]
If the data of (3) is stored in the non-volatile storage unit 32, the output terminal O can be used, for example, at the site of an exhibition or the like. _m When the display device connected to is changed, the beautiful image is output immediately without any special adjustment by setting the matrix switch 1 and the scan converter according to the data of (3) above. _m Can be displayed on a monitor connected to the.
[0030]
【The invention's effect】
As described above, in the present invention, the following effects can be obtained.
(1) Since the matrix switch having the built-in scan converter is configured as described above, an image signal of the NTSC system or an image signal of the RGB system is input from the input side, and a display device of various standards is connected to the output side. However, it is not necessary to prepare a scan converter in accordance with the method of the input image signal or the standard of the display device connected to the output side. For this reason, it can respond flexibly to various uses.
(2) The readout timing, image adjustment parameters, and the like are set in advance in accordance with the switching state of the switching circuit, and the setting information is stored in the nonvolatile storage unit. By reading the setting information, the switching circuit, readout timing, image adjustment parameters, and the like can be quickly set. For this reason, for example, a beautiful image can be displayed immediately without having to take time to set up at an exhibition site or the like.
(3) The setting of the switching circuit, the setting of the read timing of a plurality of scan converters, the setting of image adjustment parameters, and the like can be performed from a commonly provided control unit, so that the number of input / output terminals and the built-in scan converter Even if the number increases, the number of knobs or the like for adjusting each parameter can be reduced. Therefore, the size of the apparatus can be reduced, and the cost can be reduced.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an overall configuration of a matrix switch including a scan converter according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration example of a scan converter illustrated in FIG. 1;
FIG. 3 is a diagram illustrating a configuration example of a control unit and a setting unit illustrated in FIG. 1;
FIG. 4 is a diagram illustrating a usage example of a matrix switch.
FIG. 5 is a diagram illustrating an example of use of a scan converter (scan converter).
FIG. 6 is a diagram showing a schematic configuration of a scan converter.
[Explanation of symbols]
1 Matrix switch
2-1 to 2-m scan converter
3 control part
4 Setting section
21 Monitor
22 Projector
Bf buffer
11 YC separation circuit
12 Color Space Converter
13 Sync separation circuit
15 Read timing generation circuit
14a, 14b A / D converter
16 memory
18 D / A converter
19 Image adjustment circuit
20 Image readout circuit
31 Processing equipment
32 Non-volatile storage unit
41 Setting switch
42 Image adjustment parameter setting section
43 Output setting section

Claims (1)

A matrix switch having a built-in scan converter that receives an NTSC or RGB image signal, converts the input image signal into RGB signals of a standard corresponding to a plurality of display devices, and outputs the converted RGB signal.
A switching circuit for selectively inputting an NTSC or RGB image signal connected to the input side to the scan converter;
Control means for controlling the switching of the switching circuit,
A conversion unit configured to convert the input NTSC image signal into an RGB image signal;
A memory for storing the converted RGB image signal or an input RGB image signal;
An image readout circuit having a plurality of timing signal generation circuits that read out image signals from the memory at a readout timing corresponding to the standard of the display device connected to the output side;
An image adjustment circuit that performs image adjustment of an image signal read from the memory,
The control means includes a nonvolatile storage unit that stores the readout timing and the image adjustment parameter in accordance with the switching state of the switching circuit. From the nonvolatile storage unit, a switching state of the switching circuit, The readout timing corresponding to the display device connected to the display side, the image signal on the input side and the image adjustment parameter corresponding to the display device on the output side are read out, and the switching state of the switching circuit is set. A matrix switch having a built-in scan converter, wherein a timing signal generation circuit is selected, read timing by the image read circuit is set, and image adjustment parameters of the image adjustment circuit are set.

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