JPH0666957B2 - Video printer - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video printer which inputs an output signal from a video camera, an electronic still camera or the like and prints it out.

(Prior Art) Conventionally, a video camera or the like is provided with an RGB output terminal for outputting an RGB signal and a genlock output terminal for outputting a genlock signal composed of a composite video signal. These terminals and the video printer are provided. A video printer is provided that prints out a video screen by connecting the input terminal etc. In addition, this type of video printer is also capable of inputting a video signal alone, and these two types of signals are switched and input.

(Problems to be Solved by the Invention) However, in this type of video printer, there has been no means for correcting the gain of an input signal in the printer main body, and therefore, a video camera for this purpose does not exist. , The output signal level was corrected with an electronic still camera, etc., and then input into the main body of the video printer. However,
In such a video printer system, input
When the RGB signal level was low, there was a problem that the print was very dark.

(Means for Solving Problems) A video printer of the present invention includes a first system to which a genlock signal including a composite video signal output from a video camera and an RGB signal output from the video camera are input. A changeover switch for inputting two systems, a second system for inputting a video signal, for switching and outputting either the input genlock signal or the video signal, and this changeover switch A Y / C separation circuit for separating the color signal and the luminance signal with the output of
An AGC circuit that creates and outputs an AGC voltage proportional to the level of the luminance signal separated by the Y / C separation circuit and a color signal separated by the Y / C separation circuit
A color signal selector switch for switching and outputting the RGB signal and each RGB signal input from the first system, and a gain of the RGB signal output from the color signal selector switch is output from the AGC circuit. The R, G, and B amplifiers that control and output according to the AGC voltage are set.

(Function) A genlock signal or a video signal composed of a composite video signal is input by a change-over switch, and a luminance signal whose luminance is separated from this input signal by a Y / C separation circuit is AGC.
Input to the circuit. In the AGC circuit, an AGC voltage that is proportional to the level of this luminance signal is created and given to each of the R, G, and B amplifiers as a control signal.

In addition, the R, G, and B amplifiers are supplied to the R, G, and B signals generated from the color signals separated by the Y / C separation circuit, and the R and G signals input from the first system. , B signals are input after being appropriately switched by the color signal changeover switch. Therefore, each of the R, G, and B amplifiers amplifies each of the R, G, and B color signals by the amplification degree controlled by the AGC voltage, and outputs them to the next stage.

That is, the video printer of the present invention is an AGC created from the luminance signal included in the genlock signal or the video signal.
The voltage is used to correct the gain of the input signal (RGB signal from the first system or RGB signal from the second system). When the input signal level is low, the AGC is activated and R It is possible to print brightly by increasing each gain of G, B. Further, since the AGC is a feedforward type control, the gain adjustment of RGB signals is transmitted in real time.

Embodiments Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows a video printer according to the present invention. This video printer is capable of inputting two systems, a system for inputting an RGB signal and a genlock signal and a system for inputting a video signal. Input switching of these two systems,
This is done by operating the analog switch 1. In this example,
When the output level of this analog switch 1 is "H" level, the input of RGB signal and genlock signal is selected,
The input of the video signal is selected at the "L" level.

When a video signal is selected by the analog switch 1, the selector switch 2 for selectively inputting the genlock signal and the video signal is switched to the terminal b side. The input video signal is separated into a chroma signal (C) and a luminance signal (Y) via the Y / C separation circuit 3. The chroma signal is input to the chroma demodulation circuit 4, where the color difference signals (RY, GY, B-
After being demodulated into Y), it is mixed with the luminance signal (Y) separated by the Y / C separation circuit 3 in the matrix circuit 5 and converted into R signal, G signal and B signal respectively, and corresponding color signal switching is performed. It is input to the terminal b side of the switches 6a, 6b, 6c. The RGB signal is directly input to the a terminal side which is the other input terminal of the changeover switches 6a, 6b, 6c. Further, these changeover switches 6a, 6b, 6c can be switched between the input terminal a and the terminal b by operating the analog switch 1.

The luminance signal (Y) is DC-regenerated by the clamp circuit 7, integrated by the integration circuit 8, converted into a value of (DC reproduction voltage + average value of luminance signal), and input to the comparator 9. A reference voltage is set to the comparator 9 by the volume VR ₁ , and when the luminance signal level after the integration is lower than the reference voltage, the comparator output (AG
C voltage) becomes "H" level. This AGC voltage corresponds to each of the RGB signals connected to the output terminal side of the changeover switches 6a, 6b, 6c, and the R amplification section 10a, G amplification section 10b, B amplification section
The control voltage controls the amplification factor of 10c. That is, AGC
Is a feedforward type control.

Then, the RGB signals after the automatic gain adjustment by the amplifiers 10a, 10b, 10c are respectively clamp circuits 11a, 1c.
It is digitally converted via 1b, 11c and A / D converters 12a, 12b, 12c and sent to a subsequent processing circuit (not shown).

FIG. 2 shows a specific circuit of the amplifiers 10a, 10b, 10c.

Although the following description will be limited to the R amplifier section 10a, the configuration and operation of the other amplifier sections 10b and 10c are the same as those of the R amplifier section 10a.
It is the same as the amplification unit 10a.

In Figure 2, R signals are DC cut by capacitor C, is biased set by the resistor R _1, R ₂ is input to the transistor Q _1, the transistor Q ₁ is the collector side of transistors Q ₂ and the transistor Q ₃ difference It is provided on the common emitter side of the dynamic amplifier and constitutes a constant current circuit adapted to supply a constant current value determined by a resistor R ₃ connected to the emitter side of the transistor Q ₁ .

The AGC voltage is input to the base of one transistor Q ₂ that constitutes this differential amplifier in a manner superimposed on the voltage defined by the volume VR ₂ , while the other transistor Q ₃ has a resistor R ₄ , Fixed biased by R ₅ . Then, is output through the inverting amplifier circuit formed by transistors Q ₄ and the bias resistor R _6, R ₇ from the collector of the transistor Q _3.

In the R amplifier 10a, if the input signal level is high, the AGC voltage is high because the luminance signal (Y) level is also high, while if the input signal level is low, the AGC voltage is low. Therefore, the base bias of the transistor Q ₂ is set high when the input signal level is high, and is set low when the input signal level is low. Now, let the emitter currents of the transistors Q ₂ and Q _{3 be} i _E2 ,
When i _E3 and the collector current of the transistor Q ₃ are i _C3 , the following equations (1) and (2) are established.

i _E2 + i _E3 = constant (1) i _E3 ≈ i _C3 (2) Therefore, when the AGC voltage is high, a large amount of the emitter current i _E2 of the transistor Q ₂ flows, so the emitter current i _{E3 of the} transistor Q ₃ Is reduced and the gain output from the transistor Q ₃ is reduced. On the other hand, when the AGC voltage is low, the emitter current i _E2 of transistor Q ₂ decreases and
_Since the emitter current i _E3 of ₃ increases, the gain output from transistor Q ₃ increases.

(Effect of the invention) Since the video printer of the present invention is configured to control the gain of the RGB signal by using the AGC voltage created from the luminance signal included in the genlock signal or the video signal, it is bright even when the input level is low. Can be printed. Further, since the AGC control is a feed-forward type control, it has an effect that the gain adjustment of the RGB signal can be performed in real time.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a video printer according to the present invention, and FIG. 2 is a circuit diagram illustrating an RGB amplification section in FIG. 2 ... Changeover switch, 3 ... Y / C separation circuit 6a, 6b, 6c ... Color signal changeover switch 7 ... Clamp circuit, 8 ... Integration circuit 9 ... Comparator, 10a ... R amplification section 10b. G amplifier, 10c ... B amplifier

Claims (1)

[Claims] 1. A first system to which a genlock signal composed of a composite video signal output from a video camera and an RGB signal output from this video camera are input, and a second system to which a video signal is input. A video printer capable of inputting two systems, a changeover switch for changing over and outputting either the input genlock signal or the video signal, and a color signal and a luminance signal using the output of the changeover switch as input. Y / C separation circuit for separating the A / C separation circuit, an AGC circuit for creating and outputting an AGC voltage proportional to the level of the luminance signal separated by the Y / C separation circuit, and a Y / C separation circuit for separating the AGC voltage. A color signal changeover switch for switching and outputting an RGB signal created from a color signal and an RGB signal input from the first system, and this color signal changeover switch. Video printer being characterized in that a respective amplifier unit of R, G, B control and output by the AGC voltage output gain of the RGB signal outputted from the AGC circuit.