JPH08101658A - Crt display device - Google Patents

Abstract

PURPOSE: To always and properly low band-adjust moire in many synchronizing frequencies by setting moire adjustment amounts proportional to respective sizes of a horizontal synchronizing frequency and a vertical synchronizing frequency on the CRT display device side. CONSTITUTION: A horizontal deflection frequency fH is converted into voltage by an f/V converter 15-1, and is multiplied by constant (a) in a multiplication circuit 16-1, and the voltage in proportion to afH is outputted. Similarly, a vertical deflection frequency fV is converted into voltage by a f/V converter 15-2, and is multiplied by constant (b) in a multiplication circuit 16-2, and the voltage in proportion to bfV is outputted. An addition circuit 17 adds the voltages in proportion to the afH and bfV to generate an output (afH+bfV), and a moire adjustment VR (volume) 9 adjusts the level of the (afH+bfV). That is, when the moire adjustment VR is moved, the voltage is varied within the range from minimum 0 to maximum (afH+bfV).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention is a multi-scan type C
The present invention relates to an RT display device, and more particularly to a CRT display device suitable for correcting moire regardless of horizontal and vertical sync frequencies, and particularly for automatically adjusting the moiré to a minimum.

[0002]

2. Description of the Related Art In a CRT display device, the beam spot diameter is made small in order to make an image clear. However, since the CRT has a shadow mask, it is easy to generate gradual light and dark stripes called moire. Become so.

Japanese Unexamined Patent Publication No. 63-275284 discloses that the landing position of the electron beam with respect to the shadow mask hole is slightly shifted in the horizontal direction for each frame of the display image to reduce moire. That is, in order to change the screen position in the horizontal direction, a phase control circuit is provided in the preceding stage of the horizontal deflection circuit, and a flip-flop (F / F / F / F / F) whose output is switched to "1" or "0" for each vertical frequency corresponding to the frame frequency. The output of F) is adjusted by the moire adjustment VR and applied to the phase control circuit to perform the moire adjustment.

[0004]

Many of the recent multi-scan CRT display devices are compatible with a plurality of horizontal and vertical sync frequencies, and these automatically adjust the screen size and position for each horizontal and vertical sync frequency. Although properly controlled, the moire is related to the resolution, and therefore the user often adjusts the moire according to his / her desired resolution or pattern.

However, in the prior art disclosed in Japanese Patent Laid-Open No. 63-275284, since the deviation amount of the beam landing position is always constant, this deviation amount is insufficient depending on the synchronizing frequency, and moire cannot be reduced. However, there is a problem in that the moire looks like screen jitter due to an excessive amount of deviation.

An object of the present invention is to provide a CRT display device capable of always properly reducing and adjusting the above moire at various synchronizing frequencies.

[0007]

The features of the present invention for solving the above-mentioned problems are the horizontal synchronizing frequency f _H and the vertical synchronizing frequency f.
CRT sets the moire adjustment amount proportional to each _V value.
This is to be set on the display device side.

Therefore, the moire adjustment amount (af _H + bf _V ) is calculated using a and b as constants of the CRT display device, and the horizontal position of the display screen is calculated as (af _H + b).
f _V ) is alternately changed for each vertical synchronizing frequency by a distance proportional to f _V ).

[0009]

The moire can be adjusted by alternately shifting the horizontal landing position of the electron beam with respect to the shadow mask hole of the CRT for each frame of the display image by a distance proportional to (af _H + bf _V ).

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments will be described below with reference to the drawings.

FIG. 1 is a block diagram of a CRT display device according to an embodiment of the present invention.

In FIG. 1, a sync separation circuit 1 separates an input signal into a horizontal sync signal, a vertical sync signal, and a video signal. The video signal is input to the video circuit 10. Further, the horizontal synchronizing signal is input to the phase control circuit 2. The output of the phase control circuit 2 is horizontal PL
It is input to the high voltage output circuit 4 and the horizontal deflection circuit 5 via the L circuit 3. Further, the vertical synchronizing signal is input to the vertical deflection circuit 6.

The CRT device 8 displays an image based on the outputs of the video circuit 10, the high voltage output circuit 4, the horizontal deflection circuit 5, the vertical deflection circuit 6 and the like.

Further, the microcomputer 11 performs the following calculation by using the horizontal synchronizing signal and the vertical synchronizing signal, and the phase control circuit 2 adjusts the horizontal position of the screen adjusted according to the horizontal deflection frequency and the vertical deflection frequency. The voltage V is supplied.

The horizontal deflection frequency is f _H and the vertical deflection frequency is f _V, and a and b are proportional constants determined by the shadow mask pitch of the CRT and the like.

That is, a has a value of 1/2 of the horizontal shadow mask pitch of the CRT. b is a CRT
Value of 1/2 of the vertical shadow mask pitch. The microprocessor 12 in the microcomputer 11 performs the operation of the following formula (1), and the D / A converter 14 converts the operation result into an analog signal and outputs the horizontal position adjusting voltage V. The memory 13 stores the above f _H , f _V ,
a, b, and other parameters (mask pitch, etc.)
Etc. are stored.

V = af _H + bf _V (1) FIG. 2 is a relationship diagram of the horizontal position adjusting voltage V according to the above formula (1) and the horizontal synchronizing frequency and the vertical synchronizing frequency.

In FIG. 2A, for example, when the horizontal deflection frequency is f _H1 and the vertical deflection frequency is f _V1 , the horizontal position adjusting voltage V is Va. At this time, if the horizontal deflection frequency is changed to f _H3 , the horizontal position adjusting voltage becomes Vc.

Further, the vertical deflection frequency f _V is from f _V1 to f _V2
Even when it changes to, the horizontal position adjusting voltage V changes corresponding to the change of the horizontal deflection frequency.

The magnitude of the horizontal position adjusting voltage V in the prior art disclosed in the above-mentioned JP-A-63-275284 is as shown in FIG.
It was constant regardless of horizontal and vertical deflection frequencies as shown by Vd in (a).

That is, in FIG. 2A, Va is
The horizontal position adjustment voltage is shown when the horizontal deflection frequency is f _H1 and the vertical deflection frequency is f _V1 , and its variable range (from 0 to Va) is indicated as Vb. In the figure, Vd represents a constant horizontal position adjustment voltage regardless of horizontal straight lines, that is, f _H and f _V. Further, Vc represents a horizontal position adjustment voltage when the horizontal deflection frequency is f _H3 and the vertical deflection frequency is f _V1 . Vd is a constant variable range of the horizontal position adjusting voltage regardless of f _H and f _{V. In} this way, when the variable range of the horizontal position adjusting voltage is constant, for example, the horizontal deflection frequency is f _H2 and the vertical range is vertical. When the deflection frequency is f _V1 , the horizontal position adjustment voltage V is insufficient and sufficient moire adjustment cannot be performed. That is, when the horizontal deflection frequency is f _H2 and the vertical deflection frequency is f _V1 , a horizontal position adjustment voltage of Vd ′ is required, and therefore, with a constant voltage Vd, sufficient moire adjustment cannot be performed.

Further, in FIG. 2B, a straight line showing a horizontal position adjusting voltage capable of minimizing moire for a certain vertical deflection frequency f _V1 and horizontal deflection frequency f _H is a straight line g in the figure. Shown. Here, the minimum moiré is defined as the moiré that occurs when an image with a light and dark pitch is displayed on the screen and cannot be detected by the observer with the naked eye.

Actually, if the voltage output from the microcomputer 11 is set higher than the straight line g like the straight line f,
It is possible to give a margin to the variable width of the horizontal position adjusting voltage for adjusting the moire. That is, the straight line f is set to be larger than the point where the moire is minimum, and the moire is set to 0.
Even if it is not possible, the user has a margin for the variable width of the moire adjustment for the purpose of making it easy for the user to find the point where the moire is the minimum.

It is possible to obtain the horizontal position adjusting voltage V with a margin for a wider horizontal deflection frequency range and vertical deflection frequency range.

As an example, when f _H = 80 KHz and the horizontal position adjusting voltage is 5 v, the horizontal movement amount of the beam landing position is 0.2 mm. Also, f _H = 30 KHz
When the horizontal position adjustment voltage is 1 V, the horizontal movement amount of the beam landing position is set to 0.2 mm.

The amount of movement that can eliminate or minimize moire is
CRT dot pitch (shadow mask pitch)
However, in the case of 0.3 mm, the experimental data has been obtained that only half of that, 0.15 mm, is obtained.
_In both cases of _H = 80 KHz and f _H = 30 KHz, the moire can be eliminated or minimized if the horizontal movement amount is 0.2 mm.

However, the horizontal position adjustment voltage is set to a constant voltage,
For example, regardless of the f _H, when a 2.5V, f _H = 80
At KHz, the horizontal movement of the beam landing position is
It will be 0.1 mm. However, when the dot pitch (shadow mask pitch) of the cathode ray tube is 0.3 mm, the horizontal movement amount for eliminating or minimizing the moire is 0.15 mm, which is half of that. Since the amount of movement is insufficient, it becomes difficult to erase or minimize moire.

FIG. 3 is a block diagram of an embodiment of the present invention in which the function performed by the microcomputer 11 is replaced with an individual circuit.

The horizontal deflection frequency f _H output from the sync separation circuit 1 in FIG. 1 is converted into a voltage by the f / V converter 15-1 and multiplied by a constant a in the multiplication circuit 16-1.
Outputs a voltage proportional to af _H. Similarly, the vertical deflection frequency f _V is converted into a voltage by the f / V converter 15-2, multiplied by a constant b in the multiplication circuit 16-2, and a voltage proportional to bf _V is output.

The adder circuit 17 adds the voltages proportional to the above af _H and bf _V and outputs (af _H + b) shown in the equation (1).
f _V ), and the moire adjustment VR (volume) 9 adjusts the level of (af _H + bf _V ). That is, when the moire adjustment VR is moved, the minimum 0 to the maximum (af _H + b
The voltage can be varied within the range of f _V ). Since the flip-flop (F / F) 7 outputs 0 and 1 at f _V , the output of the multiplication circuit 18 is (moiré adjustment VR) × C, where the maximum value of the moire adjustment VR is af _H + bf _V. Become. Also, C
Is a correction value for correcting the output of the flip-flop (F / F) 7 to be “1” and “0”. With this moire adjustment VR, the horizontal position adjustment voltage is changed from 0 to af _H + so that the moire is minimized at a specific frequency even if the output of the moire changes due to the cathode ray tube.
Adjustable up to bf _V. Alternatively, a flip-flop (F / F) that becomes “1” and “0” for each vertical frequency
The output of 7 switches the output of the multiplication circuit 18. That is, when the output of the flip-flop (F / F) 7 is “0”, it is a normal beam landing position, and when the output of the flip-flop (F / F) 7 is “1”, it is a normal beam landing position. The beam landing position is displaced in the horizontal direction from the position by the amount corresponding to the horizontal position adjustment voltage V.

The multiplication circuit 18 operates in the same manner as in FIG. 4, and the output level of the flip-flop (F / F) 7 whose output is switched to "1" or "0" for each vertical frequency is set to the moire adjustment V.
It is controlled by the output signal of R9 and its output is applied to the phase control circuit 2 to adjust the horizontal position of the screen.

Next, FIG. 4 shows an embodiment of the present invention in which the horizontal synchronizing frequency and the vertical synchronizing frequency are generated in the CRT display device and the width of the moire adjusting voltage similar to the above can be automatically set. This will be described with reference to the flowchart shown.

In FIG. 4, the presence or absence of the vertical frequency f _V in the input signal (specifically, the synchronizing signal) is detected in step S1. Specifically, the vertical synchronizing signal is input to the microcomputer port, an interrupt is inserted by the vertical synchronizing signal, and the presence or absence of f _V is detected by the presence or absence of the interrupt. If f _V cannot be detected, the process proceeds to step S2 to generate the horizontal synchronizing frequency f _H from the system clock. Specifically, f _H is generated by measuring how many horizontal synchronization signals are input within the period of the clock obtained by dividing the system clock and calculating from the period of the system clock. In step S3, to generate a f _V using the f _H. Specifically, f _H is from 45KHz to 60 KHz, the number of display lines on the assumption that 1024, and f _V = f _H / 1024. When f _H is 60 or more, assuming that the number of display lines is 1280, f _V = f _H / 1280. f _H is up to 45KHz, assuming the number of display lines and _{640, f V = f H /} 64
Set to 0.

When the vertical frequency f _V is detected in step S1, f _H is detected in step S4.

[0035] Next, each calculated to af _H and bf _V in step S5 and S6 by using the f _H and f _V,
In step S7, (af _H + bf _V ) is calculated, and this is used as a moire adjustment signal. That is, instead of the output voltage of the adding circuit 17 in FIG. 3, the calculation result is converted into a voltage by the D / A converter and used.

A feature of the present invention is that it is possible to provide a CRT display device in which a moire adjustment range can be appropriately set according to horizontal and vertical frequencies.

Further, in the present invention, it is not necessary to form a complicated display system including an image recognition device for detecting the moire by the display itself.

In the present invention, the user can automatically set the adjustment width within the range in which the moire can be appropriately adjusted on the display side in accordance with the frequency.

The user is satisfied with the demand for adjustment and the ability to adjust to his or her preference, even if it is not optimal. For such a user, as in the present invention, from the adjustment voltage value 0 to the adjustment voltage value that can minimize the moire, the display side can automatically set it in accordance with the frequency.

When the user has fixed the adjustment width for adjusting the moire as in the prior art, it is necessary to take an extremely wide adjustment width so as to be able to deal with all conditions (frequency etc.). For users, especially inexperienced users, it is not possible to know which is the most suitable among the adjustment range of this extremely wide range, so the effort for adjustment becomes excessive and the usability decreases, but In the present invention, the upper limit of the adjustment width including the point where the moire is minimized is CR.
Since it can be set on the T display device side, the adjustment range is in an appropriate range, which is convenient.

[0041]

According to the present invention, it is possible to provide a CRT display device capable of properly setting a moire adjustment range according to horizontal and vertical frequencies.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention.

FIG. 2 is a characteristic diagram of a moire adjusting voltage according to the present invention.

FIG. 3 is a block diagram of another embodiment according to the present invention.

FIG. 4 is a flowchart of the present invention.

[Explanation of symbols]

1 ... Sync separation circuit, 2 ... Phase control circuit, 3
... Horizontal PLL, 4 ... High voltage output circuit, 5 ... Horizontal deflection circuit,
6 ... Vertical deflection circuit, 7 ... Flip-flop, 8 ... CRT
Device, 9 ... Moire adjustment volume, 10 ... Video circuit,
11 ... Microcomputer, 12 ... Microprocessor, 13 ... Memory, 14 ... D / A converter, 15-
1, 15-2 ... F / V converter, 16-1, 16-
2 ... Multiplier circuit, 17 ... Adder circuit.

Claims (2)

[Claims] 1. A multi-scan CRT display device corresponding to a plurality of synchronizing frequencies, comprising moire adjustment amount generating means proportional to respective magnitudes of a horizontal synchronizing frequency f _H and a vertical synchronizing frequency f _V. Characteristic CRT display device. 2. A CRT display device according to claim 1, wherein said moire adjustment amount generating means calculates (af _H + bf _V ) using a and b as constants.