JPS61142888A - Video projector - Google Patents

Abstract

PURPOSE:To suppress a face flicker and an inter-line flicker by using n sets of projective tubes to generate rasters having an interval of 1/n vertical period each and bringing the illuminant frequency of the screen into n times the field frequency. CONSTITUTION:A video signal is applied to n sets of projective tubes whose projected light beams are projected overlappingly on a screen while deviating the video signal sequentially at an interval of 1/n vertical period each and the deflection of the n sets of projecting tubes is shifted sequentially by the 1/n vertical period. In a video projector where two black/white projecting tubes 1P, 1Q whose projected light beams are projected on one screen 2 for example, a video signal is applied to one tube, e.g., to the tube 1Q while shifting it for the 1/2 vertical period, and the deflection of the projecting tube 1Q is shifted by the 1/2 vertical period.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a video glojictor equipped with n sets of projection type picture tubes that project the projected light from each onto the same screen in an overlapping manner.

[Conventional technology]

Conventional video glodictors have the disadvantage of being darker than those of the picture tube direct viewing type. In addition, the three-tube type, which uses red, green, and blue projection picture tubes (hereinafter referred to as projection tubes), has the disadvantage that the hue is different on the left and right sides of the screen because the images are projected from physically different positions. I feel sorry for that. Therefore,
In order to improve these shortcomings, another set of red, green, and blue projection tubes is prepared and arranged in reverse order to increase the brightness and also to prevent shading interference, i.e., different hues on the left and right sides of the screen. are improving.

[Problems to be Solved by the Invention] However, when such a bright image is obtained, flicker interference, which was not noticeable when the image was dark, appears.

For example, the CCIR method (62
5 lines/frame, 50 fields/second, 2:1 interlace), the flicker of 50 cycles (plane flicker) becomes large and the image quality deteriorates. Also, for example, in the NTSC system (525 lines/frame, 60 fields/second, 2:1 interlace) in Japan and the United States,
Interline flicker caused by interlaced scanning increases and degrades image quality.

In view of this point, the present invention is designed to improve the above-mentioned flicker interference.

[Means to solve the problem]

In order to solve the above-mentioned problems, the present invention supplies video signals sequentially shifted by 1/n vertical period to ni projection tubes that project the projection light from each projection tube onto the same screen in an overlapping manner. The deflection is sequentially shifted by 17n vertical periods. For example, the projected light from each can be projected onto the same screen (
2) two black and white projection tubes (IP), (IQ
), on the other hand, for example, a projection tube (IQ
) is supplied with a video signal shifted by v1/2 vertical period, and at the same time, the deflection of this projection tube (IQ) is performed shifted by 1/2 vertical period.

[For production]

In the above configuration, the n sets of projection tubes are separated by 17n vertical periods to form a raster, and the emission frequency of the screen is n times the field frequency of the signal.
Surface flicker and interline flicker are improved.

〔Example〕

Hereinafter, one embodiment of the present invention will be described with reference to FIG.

In the figure, (IP) and (IQ) are black and white projection tubes, respectively, and projection lights 1, . 1Q is configured to be projected onto screen (2).

Further, a video signal Sv is supplied to the terminal (3), and this video signal Sv is passed through an amplifier (5P)' to a projection tube (I
P). Further, the video signal Sv is supplied to a synchronization separation circuit (6P), and a synchronization signal P is obtained.

ync This synchronization signal P is supplied to the deflection circuit (7P), and y
ne A deflection signal is supplied from this deflection circuit (7P) to the deflection coil (8P) of the projection tube (IP).

Further, the video signal Sv supplied to the terminal (3) is supplied to the delay line (9Q). This delay line (9Q) is 1/! It has a delay time of a vertical period (hereinafter referred to as 1 vertical period'?, -IV), and the video signal Sv
A video signal Sv* delayed by 1/2v is obtained. This video signal Sv is supplied to the projection tube (IQ) via an fc5Q)'i. Also, the video signal Sv
are supplied to the synchronization separation circuit (6Q), and the synchronization signals ync * and neP delayed by 1/2v from the synchronization signal P described above are obtained. This synchronization signal P is the deflection port 17n.
6
17ne path (7Q), and a deflection signal is supplied from this deflection circuit (7Q) to the deflection coil (8Q) of the projection tube (IQ).

The example shown in FIG. At the same time, the deflection of the projection tube (IQ) is shifted by 1/2 V with respect to the projection tube (IP), so when viewed at the same time, the deflection of the projection tube (IQ) is shifted by 1/2 V with respect to the projection tube (IP).
IP) and (IQ) form a raster at positions separated by 1/2v. In other words, the projection tube (IQ
), a raster is formed at the same position with a delay of 1/2v after the projection tube (IP). Therefore, the emission frequency on the screen (2 screens) is twice the field frequency of the signal. In this case, as shown in Figure 2B, each field screen (& It appears to be displayed twice at a cycle of /2v. Therefore, according to the example shown in FIG. 1, surface flicker is completely suppressed even at high brightness, and incline flicker is also reduced.

By the way, in the conventional method (in the example in Figure 1, the delay line (9Q)
In the case of the projection tube (IP) and (IQ), when viewed at the same time, they are formed at the same position. Therefore, the emission frequency on the screen (2) is the same as the signal field frequency. in this case,
As shown in Figure 2A, the screen for each field (a+a
#b+b sc+c # .'') is displayed with a period of 1 V. Therefore, in this case, flicker interference becomes noticeable when the brightness is high.

In the example shown in FIG. 1, this is equivalent to using the previous or subsequent field signal as an interpolation signal between the input field signals, but other methods may be used as the interpolation signal. For example, it is conceivable to use the arithmetic mean value of the previous and subsequent field signals as the interpolation signal. In this case, the projection tube (
If either (IP) or (IQ) is driven by the arithmetic mean value, it becomes K.

The example in Figure 1 is an example of a two-tube black and white video logictor.
A tube-type color video groodictor may be constructed in a similar manner. FIG. 3 shows the configuration in this color case.

In the figure, (IPR), (IP, ), and (IP, ) are projection tubes that generate red, green, and blue images, respectively, and (IQR), (IQ, ), and (IQ, ) are also projection tubes that generate red, green, and blue images, respectively. , are projection tubes that generate red, green, and blue images, respectively. The projection lights from these projection tubes (IP,) to (IQ,) are projected onto a screen (not shown) in an overlapping manner.

In actuality, the projection tubes (IQ, ) to (IQII) are arranged horizontally opposite to the projection tubes (IPR) to (IP, ), in order to improve shading interference.

Further, a color video signal Scv is supplied to the terminal (3), and this video signal Scv is supplied to the brightness/color processing circuit (IOP).
). The red, green, and blue primary color signals Rt G t B obtained from this processing circuit (LOP) are sent to a projection tube (IPR) via an amplifier (5Pa) = (5Po) - (5PB), respectively.

(IP.), (IP,). In addition, the video signal S is supplied to the sync separation circuit (6P), and the sync signal C
The map Psync is obtained. This synchronization signal P is the deflection port y
nc tract (7P, ), (7Po), (7PII),
These deflection circuits (7PR) # (7PG), (7
Projection tube (IPB), (IP,) from P,).

(IP,) deflection coil (8P R) v (8PG)
A deflection signal is supplied to e (8P m).

Further, the video signal Scv supplied to the terminal (3) is supplied to the delay line (9Q). This delay a (9Q) is 1/
2v delay time? The output side of the
A video signal V S * delayed by 1/2v from the video signal S is obtained. This video signal S * is the brightness/color e
V
It is supplied to the eV processing circuit (IOQ). From this processing circuit (IOQ), red, green, and blue primary color signals R= G t B delayed by 1/2 vfI for the original R, a, B K are obtained, and these are respectively processed by an amplifier (
5Ql), (5Q,), (5QB) are supplied to the projection tubes CIQB), (IQ,), (IQIl) through the channels.

Further, the video signal Scv* passed through the delay line (9Q) is supplied to the synchronization separation circuit (6q), and the above-mentioned synchronization signal P
, a, synchronization signal P3 ane delayed by 1/2v, respectively.
is obtained. This synchronization signal P, A, *ki is supplied to the deflection circuits (7Q, B)-(7Q,), C7Q,), and these deflection circuits (7QR).

The example in Fig. 3 is configured as described above, and the projection tube (IQ, ) ~
(IQ,) contains a primary color signal R shifted by 1/2 V from the primary color signal R-B supplied to the projection tubes (IP,) to (IP,).
At the same time ~B* is supplied, the projection tube (IQR) ~(I
The deflection of the projection tube (IP,) ~ (IP,) K
Since it is shifted by 1/2v, the projection tube (IPR)
~(IP,) and projection tube (IQ,) ~(IQ,) and Ha1
This means that they form a terrasque separated by /2 V.

Therefore, the same effects as in the case of black and white shown in FIG. 1 can be obtained.

Next, FIG. 4 shows an example in which the present invention is applied to a three-tube type color video glodictor.

In the same figure, (IR), (IG), (IB)
are red and green.

These are projection tubes that each generate a blue image, and the projection light from each of the projection tubes (IR) to (IB) is projected onto a screen (not shown) in an overlapping manner.

Further, a color video signal Scv is supplied to the terminal (3), and this video signal Scv is supplied to the brightness/color processing circuit (10).The red primary color signal R obtained from this processing circuit αQ is sent to the amplifier (5R). '& is supplied to the projection tube (IR) through the green primary color signal G obtained from the processing circuit.
is fed to the delay line (IIG). This delay line (IIG
) has a delay time of 1/3V, and the green primary color signal G is delayed by 1/3V and obtained on the output side.
This is supplied to the projection tube (IG) via amplifier (5G) Y. In addition, the blue primary color signal B obtained from the processing circuit Q□
is fed to the delay line (IIB). This delay line (IIB
) has a delay time of V3V, and the blue primary color signal B is delayed by 2/3V on the output side, and this is supplied to the projection tube (IB) K via Anne f (5B). .

Further, the video signal S' is supplied to a synchronization separation circuit (6), and a synchronization signal P17ne is obtained. This synchronization signal P
is supplied to a deflection circuit 17ne (7R), and a deflection signal is supplied from this deflection circuit 17ne (7R) to a deflection coil (8R) of the projection tube (IR). Furthermore, the synchronization signal P from the separation circuit (6) is transmitted through a delay line (1) having a delay time of 1/3v.
2G)! 17ne l to the deflection circuit (7G), and this deflection circuit (
A deflection signal is supplied from the deflection coil (8G) of the projection tube (IG) from the deflection coil (8G). Furthermore, the synchronizing signal P from the separation circuit (6) is transmitted through a delay line (12B) having a delay time l of 2V.
7ne to the deflection circuit (7B), and this deflection circuit (
A deflection signal is supplied from 7B) to the deflection coil (8B) of the projection tube (IB).

The example in FIG. 4 is constructed as described above, and includes a projection tube (IA).

In (IG) and (IB), red and green are sequentially shifted by 1/3 V.

At the same time as the blue primary color signal ReGeB is supplied,
Projection tube (IR), (IG), (IB)+! , its deflection is shifted by 1/3 V, so the projection tube (IR)
, (IG), and (IB) are sequentially separated by 1/3v to form a raster.

In other words, in the projection tube (IG), the projection tube (IR
) A raster is formed at the same position with a delay of K 1/3 V.
A raster is formed at the same position with a delay of V.

Therefore, the emission frequency on the screen is three times the signal field frequency. In this case, as shown in FIG. 5B, the screens r*gskl of each color appear to be displayed sequentially at intervals of 1/3v. Therefore, in the example shown in FIG. 4 as well, flicker interference is reduced even at high brightness, similar to the example shown in FIG.

By the way, the conventional method (in the example in Figure 4, the delay line (IIG,)
(See examples excluding (IIB), (12G), and (12B)), projection tubes (IR), (IG), and (IB) form a raster at the same position when viewed at the same time. KotoK
Become. Therefore, the emission frequency on the screen is the same as the signal field frequency. In this case, as shown in FIG. 5A, a color screen (r+g+b) appears to be displayed at a period of Iv. Therefore, in this case, flicker interference becomes noticeable when the brightness is high.

In the case of the example shown in FIG. 4, when a monochrome screen is displayed on the screen, the emission frequency becomes the field frequency of the signal. However, in this case, since the color is monochromatic and the brightness is not high, the flicker is not very noticeable and does not cause much of a problem.

By the way, the relationship between the primary color signals R, G, B and the luminance signal Y is as follows: Y = 0.3 OR + 0.59 G + 0.11
Since the brightness is given by B, the brightness of green and the brightness of (red+blue) are approximately equal. From this, it is conceivable to configure as shown in Fig. 6 instead of the example in Fig. 4.In Fig. 6,
Portions corresponding to those in FIG. 4 are designated by the same reference numerals.

In the same figure, red and blue primary color signals R from the processing circuit o0
, B are supplied to the projection tubes (IR) and (IB) via amplifiers (5R) and (5B), respectively. Further, the green primary color signal G from the processing circuit (transfer) is supplied to the delay line (13G).

This delay line (13G) has a delay time of 1/2 ■, and the green primary color signal G is delayed by 1/2 V on the output side, and this is the amplifier (5G)? It is supplied to the projection tube (IG) via.

Further, the synchronization signal Psync from the separation circuit (6) is supplied to the deflection circuits (7R) and (7B), and these deflection circuits (7R) and (7B) transmit the projection tube (IR) and (I
Deflection signals are supplied to the deflection coils (8R) and (8B) of B), respectively. Furthermore, the synchronization signal P from the separation circuit (6) is transmitted through a delay line (14G) having a delay time of 1/2 V! A deflection signal is supplied to a deflection circuit (7G) via the deflection circuit (7G), and a deflection signal is supplied from this deflection circuit (7G) to a deflection coil (8G) of the projection tube (IG).

The rest of the structure is the same as the example shown in FIG.

In this example in FIG. 6, the projection tube (IG) includes the projection tube (
IR), (IB) 1 compared to the primary color signal supplied by vc
At the same time that the primary color signal shifted by /2V is supplied, the projection tube (
IG) deflection is 1/! with respect to projection tube (IR), (IB) Ic! ■Since it is shifted, the projection tube (IR), (I
B) and the projection tube (IG) are separated by 1/2v to form a raster. In other words, in the projection tube (IG), the projection tube (IR).

A raster is formed at the same position with a delay of 1/2v from (IB). Therefore, the emission frequency of the screen is twice the field frequency. In this case, as shown in FIG. 7B, the red back screen (r+b) and the green screen g appear to be displayed in an intersecting XJK manner at an interval of 1/2v. Therefore, in this case as well, the same effects as in the example shown in FIG. 1 can be obtained.

Note that FIG. 7A shows the same thing as FIG. 5A.

〔Effect of the invention〕

According to the present invention described above, each of the n sets of projection tubes is 1/
Since rasters are formed separated by n vertical periods (17nV) and the emission frequency of the screen is n times the field frequency, surface flicker is suppressed and interline flicker is reduced even at high brightness.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment 7 of the present invention, FIG. 2 is a diagram for explaining the same, and FIGS. 3, 4, and 6 are block diagrams showing other embodiments of the present invention, respectively. , FIG. 5, and FIG. 7 are diagrams for explaining the example in FIG. 4 and the example in FIG. 6, respectively. (IP) and (IQ) are projection tubes, (2) is a screen, (6P) and (6Q) are synchronous separation circuits, (7P
) and (7Q) are deflection circuits, respectively, and (9Q) is a delay line. Figure 1 Figure 2, A B Figure 4

Claims (1)

[Claims] The projection light from each is overlapped and projected onto the same screen.
The video signal is sequentially supplied to the n sets of projection picture tubes by shifting 1/n vertical period, and at the same time the deflection of the n sets of projection picture tubes is sequentially shifted by 1/n vertical period. A video projector characterized by: