JPH0570076U - On-screen display controller - Google Patents

Abstract

(57) [Abstract] [Purpose] To enable on-screen display at a fixed position in the image display area even if the frequency of the synchronization signal is switched. The vertical synchronization detection circuit 9 counts the horizontal synchronization signal H in one cycle of the vertical synchronization signal V, and the frequency dividing circuit 11 divides the count output. The vertical position determination circuit 13 counts the frequency-divided signal by the size corresponding to the vertical display start position in the image display area. The horizontal sync detection circuit 17 detects the frequency of the horizontal sync signal H, and the F / V conversion circuit 19 converts it into a DC voltage. The oscillation circuit 21 oscillates a frequency signal according to the converted voltage. The horizontal position determination circuit 23 counts the frequency signal for the dimension corresponding to the horizontal display start position. The vertical and horizontal drive circuit 15 outputs the characters for on-screen display to the display circuit 27 based on the count-up of the vertical and horizontal position determination circuits 13 and 23.

Description

[Detailed description of the device]

[0001]

[Industrial application]

 The present invention relates to an on-screen display control device for displaying code information in an image display area in an overlapping manner, and is particularly suitable for being mounted on an image display device capable of displaying an image by a plurality of synchronization signals having different frequencies, a so-called multi-sync display device. The present invention relates to an on-screen display control device.

[0002]

[Prior Art]

 Recent television receivers display so-called on-screen display, which displays television programs and video images on a color cathode ray tube and also displays symbols such as television and video mode, channel number and volume that are composed of letters and symbols on the image. It has a function. FIG. 4 shows an example in which the on-screen display code “VIDEO” 3 indicating the video mode is displayed from the position away from the upper end and the left end in the image display area 1 of the color CRT.

Conventionally, as an apparatus for controlling such an on-screen display, for example, as shown in FIG. 5, an LC oscillation circuit 5 having a variable capacitor VC for fine adjustment of an oscillation frequency and outputting a predetermined oscillation signal A is used. It is known that the microcomputer mainly includes horizontal and vertical synchronizing signals H and V, and an on-screen signal generating circuit 7 that outputs an on-screen video signal and a blanking signal from the oscillation signal A of the oscillation circuit 5. ..

In such an on-screen display control device, a count number when the size and minutes in the image display area 1 of FIG. 4 are counted by the horizontal synchronizing signal H is set in advance, and as shown in FIGS. When the vertical and horizontal synchronizing signals V and H are applied to the on-screen signal generating circuit 7, the on-screen signal generating circuit 7 counts a predetermined number of horizontal synchronizing signals H from the rising edge of the vertical synchronizing signal V, Generates vertical on-screen start timing signal when counting up. On the other hand, in the horizontal direction, as shown in FIG. 7, the on-screen signal generation circuit 7 counts the oscillation signal A by a predetermined number from each rising edge of the horizontal synchronizing signal H, and when it counts up, the horizontal on-screen start is started. Generates timing signals. 6 and 7 are schematic waveform diagrams.

The on-screen signal generation circuit 7 is based on the vertical and horizontal on-screen start timing signals, and is incorporated in or externally attached to the on-screen signal generation circuit 7 or a character generator ( On-screen display control is performed by outputting the code signal from either (not shown) as an RGB on-screen video signal and outputting a blanking signal for blanking the part corresponding to the on-screen video signal. is doing.

[0006]

[Problems to be solved by the device]

 However, the above-described conventional on-screen display control device counts a predetermined number of horizontal sync signals H from each rising edge of the vertical sync signal V at the vertical on-screen display start position, while starting the horizontal on-screen display start. Regarding the position, the oscillation signal A is counted by a predetermined number from each rising edge of the horizontal synchronizing signal H, so that there is no problem in the configuration in which the color braun tube is driven by the vertical and horizontal synchronizing signals V and H of one kind of frequency. However, in the multi-sync display device, there is a drawback that the on-screen display position is not fixed when the frequency of the vertical and horizontal sync signals changes.

For example, when the frequency of the horizontal synchronizing signal H is increased from 15 KHz to 30 KHz while keeping the vertical synchronizing signal V constant, as shown in FIGS. 6A and 6C, when the vertical synchronizing signal V is a horizontal synchronizing signal of 15 KHz, Since the horizontal synchronizing signal H of 30 KHz is counted by the same count number, the count-up time is advanced, and the vertical on-screen start position in the image display area 1 in FIG. 4 is shifted upward. In the horizontal direction, when the frequency of the horizontal synchronizing signal H becomes high as shown in FIG. 7c, the frequency of the oscillation signal A is constant, so even if the same count number is counted as shown in FIG. The up time is delayed, and the horizontal on-screen start position is shifted to the right of the image display area 1.

As a result, the on-screen start position moves to the upper right end of the image display area 1 in FIG. 4, and there is a problem that good on-screen display cannot be performed. The on-screen start position also moves when the frequency of the vertical synchronizing signal V changes.

As described above, in the conventional on-screen display control device, when the frequencies of the vertical and horizontal synchronizing signals V and H change, it becomes difficult to keep the on-screen start position constant, and in particular, a solution is desired in a multi-sync display device. Was there. The present invention has been made to solve such a conventional drawback, and provides an on-screen display control device capable of on-screen display of characters and the like at a fixed position even if the frequency of a vertical and / or horizontal synchronizing signal changes. With the goal.

[0010]

[Means for Solving the Problems]

 In order to solve such a problem, the present invention provides a vertical sync detection circuit that counts the number of horizontal sync signals in one cycle of a vertical sync signal, and a count output of the number of horizontal sync signals is preset in an image display area. The vertical position determination circuit that counts the vertical display start position to determine the vertical display start timing, the horizontal synchronization detection circuit that detects the frequency of the horizontal synchronization signal, and the detection signal that corresponds to the frequency of the horizontal synchronization signal. Frequency / voltage conversion circuit for converting to a DC voltage signal, an oscillation circuit that oscillates an oscillation signal according to the DC voltage signal, and count the oscillation signal for a preset horizontal display start position in the image display area. Based on the horizontal position determination circuit that determines the horizontal display start timing and the determined vertical and horizontal display start timing, It is provided with vertical and horizontal driving circuit for driving the Shimesuru display circuit.

Then, the present invention is arranged to display the above-mentioned symbols in a ratio size corresponding to the count number of the horizontal synchronizing signal from the vertical synchronizing detecting circuit and the DC voltage signal converted by the frequency / voltage converting circuit. A size switching circuit for controlling the vertical and horizontal driving circuits may be provided.

[0012]

[Action]

 In the present invention equipped with such means, the vertical sync detection circuit counts the horizontal sync signal within one cycle of the vertical sync signal, and the vertical position determination circuit counts the count signal for the vertical display start position to perform the vertical display. The display start timing is determined. For example, even if the frequency of the horizontal synchronizing signal changes, the vertical position determination circuit counts a predetermined vertical display start position in the image display area to determine the same vertical display start timing.

Further, the horizontal sync detection circuit detects the frequency of the horizontal sync signal, the frequency conversion circuit converts the frequency signal into a level signal corresponding to the horizontal sync frequency, and the oscillation circuit converts the frequency signal corresponding to the level signal. It oscillates and the horizontal position determination circuit counts the frequency signal for the horizontal display start position to determine the horizontal display start timing.When the frequency of the horizontal sync signal changes, the level signal and frequency signal are changed in response to this change. Then, the horizontal position determination circuit counts a predetermined horizontal display start position in the same image display area and determines the same horizontal display start timing.

Then, the vertical and horizontal drive circuits drive the display circuit so as to display the code based on the vertical and horizontal display start timings. Further, in the configuration in which the size switching circuit is provided, the size switching circuit controls the vertical and horizontal driving circuits so that the code is displayed in a ratio size corresponding to the count number and the level signal.

[0015]

【Example】

 An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of an on-screen display control device according to the present invention. In FIG. 1, the vertical sync detection circuit 9 to which the vertical sync signal V and the horizontal sync signal H are input counts the number of horizontal sync signals H in one cycle of the vertical sync signal V as shown in FIGS. It has a counter function of outputting as an output and is connected to the frequency dividing circuit 11.

The frequency dividing circuit 11 finely divides the counter output from the vertical synchronization detecting circuit 9 to improve position setting accuracy, and is connected to the vertical position determining circuit 13. Further, it is unnecessary depending on the configurations of the vertical synchronization detection circuit 9 and the vertical position determination circuit 13 described later. The vertical position determining circuit 13 counts the frequency-divided signal B from each rising edge of the vertical sync signal V from the vertical sync detection circuit 9 by the size of the image display area 1 (see FIG. 4 described above). It has a function of outputting a vertical on-screen start timing signal to the vertical and horizontal drive circuits 15 when the count-up is performed.

Therefore, as shown in FIG. 2, for example, when the frequency of the vertical synchronizing signal V is constant and the frequency of the horizontal synchronizing signal H becomes higher, the frequency of the divided signal B also becomes higher, and the same size in the image display area 1 is obtained. Even if it counts, the number of counts in the vertical position determination circuit 13 increases. The horizontal synchronization detection circuit 17 counts the number of periods of the horizontal synchronization signal H which is the same as the horizontal synchronization signal input to the vertical synchronization detection circuit 9 to detect the frequency, and detects the frequency, and the frequency conversion circuit (hereinafter referred to as F / V conversion circuit). It is omitted. The same applies to the figure.).

As shown in FIG. 3b, the F / V conversion circuit 19 converts and outputs a DC voltage corresponding to the number of counts in the horizontal synchronization detection circuit 17, and the oscillation signal A having a frequency corresponding to the DC voltage level. Is connected to a horizontal position determining circuit 23 via an oscillation circuit 21 that oscillates. Therefore, the frequency of the oscillation signal A increases or decreases according to the level of the DC voltage level. The solid line in FIG. 3b shows the DC voltage level when the frequency of the horizontal synchronizing signal H is low, and the broken line shows the DC voltage level when the frequency is high, and they correspond to the oscillation signals A in FIGS.

The horizontal position determining circuit 23 counts the oscillation signal A for each dimension in the image display area 1 (see FIG. 4 described above) from each rising edge of the horizontal synchronization signal H from the horizontal synchronization detection circuit 17. , And has a function of outputting a horizontal on-screen start timing signal to the vertical and horizontal drive circuits 15 when counting up. Since the horizontal synchronizing signal H is converted into the oscillation signal A corresponding to its frequency through the DC voltage, even if the frequency of the horizontal synchronizing signal H becomes high and its cycle becomes short, the oscillation signal A The frequency also increases, and the number of counts in the horizontal position determining circuit 23 is almost constant.

The vertical and horizontal drive circuit 15 receives characters and symbols from a character pattern storage circuit (not shown) when the vertical and horizontal on-screen start timing signals are output from the vertical position determination circuit 13 and the horizontal position determination circuit 23. The display circuit 27 is driven so as to display the code signals such as from the positions of and in FIG. The code signal includes the on-screen video signal and the blanking signal as described above with reference to FIG. 5, but is not limited to these.

A size switching circuit 25 is connected to the vertical and horizontal drive circuits 15. The size switching circuit 25 determines the vertical and horizontal sizes of the display code in the image display area 1 of FIG. 4 from the DC voltage level according to the count number from the vertical synchronization detection circuit 9 and the horizontal synchronization frequency from the F / V conversion circuit 19. Is calculated and the code read from the vertical / horizontal drive circuit 15 is switched between vertical and horizontal sizes so that the code can be easily seen, and is output to the vertical / horizontal drive circuit 15 again. To drive.

The above-described structure is actually composed mainly of a microcomputer having a CPU and a ROM storing an operation program of this CPU, and counts counted by the vertical position determination circuit 13 and the horizontal position determination circuit 23. The number is calculated by the vertical position determining circuit 13 and the horizontal position determining circuit 23 or a circuit (not shown) so that the display start position in the image display area 1 becomes constant according to the frequencies of the vertical and horizontal synchronizing signals V and H. It

Next, the operation of the on-screen display control device according to the present invention will be briefly described. When the vertical synchronization signal V and the horizontal synchronization signal H are input to the vertical synchronization detection circuit 9, as shown in FIG. 2, the number of periods of the horizontal synchronization signal H in one period of the vertical synchronization signal V is counted and the count output Are added to the frequency dividing circuit 11. The count output is frequency-divided by the frequency dividing circuit 11, and the vertical position determining circuit 13 counts up the frequency-divided signal B from each rising edge of the vertical synchronizing signal V by the size of the image display area 1. A vertical on-screen start timing signal is output to the vertical and horizontal drive circuits 15.

If the frequency of the vertical sync signal V is kept constant and the frequency of the horizontal sync signal H is increased, the count number from the vertical sync detection circuit 9 is increased and the frequency division signal B from the frequency division circuit 11 is increased. 2d also becomes higher as shown in FIG. 2d, the vertical position determining circuit 13 counts the frequency-divided signal B to a position corresponding to the same size, and the vertical timing of the on-screen start timing signal in the vertical direction is determined by the same timing. Output to the horizontal drive circuit 15. On the other hand, the frequency of the horizontal sync signal H input to the horizontal sync detection circuit 17 is detected by the count number, converted by the F / V conversion circuit 19 into a DC voltage level according to the count number, and then the oscillation circuit 21 outputs the horizontal sync signal H. An oscillation signal A having a frequency corresponding to the DC voltage level is output to the horizontal position determining circuit 23.

The horizontal position determining circuit 23 counts the oscillation signal A for each dimension from each rising edge of the horizontal synchronizing signal H, and outputs a horizontal on-screen start timing signal to the vertical and horizontal driving circuits 15 when counting up. To do. Here, when the frequency of the horizontal synchronizing signal H increases as shown in FIG. 3d, the DC voltage level from the F / V conversion circuit 19 increases from the solid line level to the broken line level in FIG. The frequency of the oscillation signal A also becomes high as shown in FIG.

The horizontal position determining circuit 23 counts the oscillation signal A to a position corresponding to the same size, and outputs a horizontal on-screen start timing signal to the vertical and horizontal drive circuits 15 at the same timing. Then, the vertical and horizontal drive circuit 15 outputs the display code signal for on-screen display to the size switching circuit 25, and the size switching circuit 25 switches the vertical and horizontal sizes according to the frequencies of the vertical and horizontal synchronizing signals. When a timing signal for starting the on-screen is input from the vertical position determining circuit 13 and the horizontal position determining circuit 23, the signal is fetched again and output to the display circuit 27 for on-screen display control.

The operation of the vertical position determining circuit 13 is the same when the frequency of the vertical synchronizing signal V changes. As described above, the on-screen display control device of the present invention automatically calculates the dimension corresponding to the on-screen display position in the image display area 1 even if the frequencies of the vertical and horizontal synchronizing signals change. Since the output timing of the display code signal is obtained, the on-screen display code can be displayed at a fixed position in the image display area 1.

Moreover, since the size switching circuit 25 is provided, it is possible to automatically change the display vertically and horizontally in the same ratio according to the frequencies of the vertical and horizontal synchronizing signals. By the way, in the above-described on-screen display control device according to the present invention, the configuration has been described in which both the vertical and horizontal fixed display positions are automatically positioned according to the frequencies of the vertical and horizontal synchronizing signals.

However, in the multi-sync display device, there is a case where on-screen display fixed at a fixed display position in the vertical direction or the horizontal direction may be performed. Therefore, in the above-mentioned configuration, the vertical on-screen display position is kept constant by the vertical synchronization detection circuit 9, the frequency dividing circuit 11, the vertical position determination circuit 13, and the vertical and horizontal drive circuits 15 regardless of the frequency of the vertical synchronization signal. Can be fixed.

Further, the horizontal sync detection circuit 17, the F / V conversion circuit 19, the oscillation circuit 21, the horizontal position determination circuit 23, and the vertical and horizontal drive circuits 15 make it possible to display the horizontal on-screen display position regardless of the frequency of the horizontal sync signal. Can be fixed to a constant value, and the vertical and horizontal drive circuits 15 can be changed to a dedicated vertical drive circuit or horizontal drive circuit. However, when commercializing a multi-sync display device, positioning in both vertical and horizontal directions is necessary, so the embodiment shown in FIG. 1 is preferable.

Further, in the above-described embodiment, the vertical synchronization detection circuit 9 is configured to count one cycle of the vertical synchronization signal V with the horizontal synchronization signal H. However, the frequency of the vertical synchronization signal V is detected and the frequency is detected. It is also possible to convert to a DC voltage according to the above, oscillate a frequency signal according to this DC voltage level, and count this frequency signal for the display start position in the vertical direction. That is, the horizontal synchronization detection circuit 17, the F / V conversion circuit 19, the oscillation circuit 21 and the horizontal position determination circuit 23 in FIG. 1 can be separately provided for the vertical synchronization signal.

[0032]

[Effect of the device]

 As described above, according to the present invention, even if the frequency of the vertical and / or horizontal synchronizing signals changes, characters or the like can always be displayed on-screen at a fixed position in the image display area. Further, in the configuration in which the size switching circuit is provided, the code size can be switched and displayed at a fixed ratio according to the vertical and horizontal synchronizing frequencies, and the display quality can be kept high. Therefore, in the multi-sync display device equipped with the on-screen display control device of the present invention, the mode display corresponding to the frequencies of the vertical and horizontal sync signals, the operation switch for switching, etc. are not required, and the operability is improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of an on-screen display control device of the present invention.

FIG. 2 is a timing chart explaining an operation in a vertical direction in the on-screen display control device of FIG.

FIG. 3 is a timing chart explaining an operation in the horizontal direction in the on-screen display control device of FIG.

FIG. 4 is a schematic diagram showing an example in which a code is displayed on-screen in an image display area.

FIG. 5 is a schematic block diagram showing a conventional on-screen display control device.

FIG. 6 is a timing chart for explaining the operation in the vertical direction in the conventional on-screen display control device.

FIG. 7 is a timing chart illustrating an operation in the horizontal direction in the conventional on-screen display control device.

[Explanation of symbols]

 1 Image Display Area 3 On-Screen Display Code 5 Oscillation Circuit 7 On-Screen Signal Generation Circuit 9 Vertical Sync Detection Circuit 11 Frequency Dividing Circuit 13 Vertical Positioning Circuit 15 Vertical and Horizontal Drive Circuit 17 Horizontal Sync Detection Circuit 19 F / V Converter Circuit 21 Oscillation circuit 23 Horizontal position determination circuit 25 Size switching circuit 27 Display circuit

Claims (2)

[Scope of utility model registration request] 1. An on-screen display control device for displaying a code in an image display area in a superimposed manner, a vertical sync detection circuit for counting the number of horizontal sync signals in one cycle of a vertical sync signal, and the counting of the number of horizontal sync signals. A vertical position determination circuit that determines the vertical display start timing by counting the output by a preset vertical display start position in the image display area, a horizontal synchronization detection circuit that detects the frequency of the horizontal synchronization signal, and the detected horizontal A frequency / voltage conversion circuit for converting to a DC voltage signal according to the frequency of the synchronizing signal, an oscillation circuit for oscillating an oscillation signal according to the DC voltage signal, and a horizontal display preset for the oscillation signal in the image display area. A horizontal position determination circuit that counts the start position to determine the horizontal display start timing, and the determined vertical and horizontal positions. On-screen display control device including a vertical and a horizontal driving circuit for driving the display circuit to display the code on the basis of the horizontal display start timing, the. 2. The vertical and horizontal drive so as to display the code at a ratio size corresponding to the count number of the horizontal sync signal from the vertical sync detection circuit and the DC voltage signal converted by the frequency / voltage conversion circuit. The on-screen display control device according to claim 1, further comprising a size switching circuit for controlling the circuit.