KR960010408B1 - Cvp using in photo film - Google Patents

Abstract

a signal convertor which converts the signal passed through the film into the electrical image signal having original color signal; a brightness/color signal dividing unit which divides a brightness signal and a color signal by receiving the mixed image signal having electrical brightness and color element; a decoder which makes horizontal-vertical synchronous signals and the original color signal from the output signal of the brightness/color signal dividing unit; a switching unit which transforms the output selected from the signal convertor or the decoder according to a control signal of the system control unit into a analog/digital convertor; a memory which stores the image data converted by the analog/digital convertor; the printing unit which prints the stored image data with a thermal transforming head.

Description

Color video printer

1 is a circuit diagram of a conventional color video printer.

2 is a circuit diagram of a color video printer of the present invention.

3 is a detailed circuit diagram of the signal conversion section in FIG.

* Explanation of symbols for main parts of the drawings

21: luminance / color signal separator 22: decoder

23: analog / digital converter 24: memory

25: digital / analog converter 26: encoder

27: mixing unit 28: system control unit

29: memory control unit 30: tone control unit

31: Thermal print head 32: line memory

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to photographic printing of color video printers, and more particularly, to a color video printer in which signal inputs other than electrical signals can be converted into signals.

The conventional color video printer circuit configuration includes a luminance / color signal separator 1 for separating the input video signal Vi into a luminance signal Y and a color signal C, as shown in FIG. A decoder (2) for converting the color (C) and luminance (Y) separated by the luminance / color signal separation unit (1) into red signal (R), green signal (G), and blue signal (B); The analog / digital converter 3 converts the red (R), green (G), and blue (B) analog signals into digital signals, and stores the digital signals of the image converted by the converter (3). Memory 4, a digital / analog converter 5 for converting a digital signal stored in the memory 4 into an analog signal, and red (R), green (G), and blue (blue) of the converter (5). An encoder 6 for converting and outputting the digital signal of (B) into a luminance and a color signal, a mixing unit 7 for converting the luminance and color signals outputted through the encoder 6 into a composite video signal; Number of decoders 2 A memory controller 8 for controlling the data signals stored in the memory 4 in synchronization with the vertical synchronization signal H-SYNC and V-SYNC, and a line memory for storing line data for line printing; (9), a tone control unit 10 for making memory data printable, a thermal print head 11 for receiving and printing data from the tone control unit 10, and controlling the entire system. It consists of the system control unit 12.

In the conventional circuit configured as described above, when the composite video signal Vi is input to the luminance / color signal separation unit 1, the composite video signal Vi is separated into the luminance signal Y and the color signal C from the composite video signal Vi. Output to the decoder 2, and the decoder 2 receives the luminance signal Y and the color signal C into analog color signals of red (R), green (G), and blue (B), thereby converting the analog / In addition to the digital conversion unit 3, the horizontal (H-SYNC) and the vertical synchronization signal (V-SYNC) are separated and input to the memory control unit (8).

The red (R), green (G), and blue (B) analog signals are converted into digital data by the analog (A) / digital (D) converter (3) and digital (D) / through the memory (4). The luminance signal Y and the color signal which are input to the analog (A) converter 5 and converted into the original red (R), green (G), and blue (B) analog signals, and are modified by the encoder (6). (C) is a mixed video signal mixed through the mixing unit 7 and is output through the output terminal (Vout).

At this time, when a memory command comes into the memory controller 8 through the system controller 12, the memory controller 8 stores the current image information in the memory 4 as the command is transmitted to the memory 4.

In addition, when a print command is received from the system controller 12, the memory controller 8 takes out the data stored in the memory 4, and performs data transfer to the line memory 9 line by line.

When all the one-line data is taken out in this way, the data stored in the line memory 9 is transferred to the tone control unit 10 and printed through the thermal print head 11.

However, such a system uses only a signal in which the signal input source is electrically converted, and thus there is a problem in that an input other than an electrical signal cannot be used in the system.

Therefore, in order to solve the conventional problems, a negative film is used in converting a signal, which is not an electrical signal source, into a signal source in a video color printer, and the light incident by the light source is negative. When the light enters the image pickup device through the film to convert the optical signal into an electrical signal to print to overcome the limitations of the print signal input source was created a color video printer, which will be described in detail with reference to the accompanying drawings. Is as follows.

2 is a circuit diagram of a color video printer according to the present invention. As shown therein, a signal converter 35 converts a signal passing through a film into an electric video signal having primary color signals R, G, and B. And a luminance / color signal separator 21 for receiving a complex video signal having luminance and color components and separating the luminance signal into color signals C and luminance / color signal separators 21. The decoder 22 for generating the primary color signals R, G, and B and the horizontal and vertical synchronization signals H-SYNC and V-SYNC from the output signals, and the decoder according to the control signals of the system controller 28. A switch unit 34 for selecting one of the outputs of the signal conversion unit 35 and the output of the signal conversion unit 35, and transmitting the signal to the analog / digital conversion unit 23; Memory 24 for storing video data and digital video data stored in the memory 24 are read out. Analog (R), green (G), and blue (B) of the analog / digital converter 25 and the digital / analog converter 25 for converting and outputting the analog primary color signals R, G, and B. An encoder 26 for converting the primary color signal into a luminance and color signal and outputting the mixed color signal; a mixing unit 27 for mixing the luminance and color signals output through the encoder 6 into a composite video signal; A memory controller 29 for controlling the data signals stored in the memory 24 in synchronization with the horizontal and vertical synchronization signals H-SYNC (V-SYNC) of (22), and line data for line printing; A line memory 32 for storing the data, a tone control unit 30 for making memory data printable, and a thermal print head 31 for receiving and printing data from the tone control unit 30. do.

As shown in FIG. 3, the signal conversion unit 35 includes an imaging device 52 which receives the amount of transmission of the light 50 transmitted through the negative film 51 and converts it into an electrical amount; The color signal processing unit 53 which receives a signal from the image pickup device 52 and generates a luminance and color difference signal, and the output of the color signal processing unit 53 to compensate for this since the image present in the negative film 51 is an inverted value. An inverted amplifier 54 inverted and amplified by a signal, and a matrix unit 55 for receiving the output signal of the inverted amplifier 54 and generating inverted primary color signals R, G, and B.

Referring to the operation and effect of the present invention configured as described above in detail.

When the signal source is an electrical signal, when the switch unit 34 receives the control signal through the system control unit 28, the line is transferred to the decoder 22 to receive an input.

Then, as in the prior art, the luminance / color signal separator 21 receives the composite video signal and separates it into the luminance signal Y and the color signal C, and divides the separated luminance signal Y and the color signal C. When transmitted to the decoder 22, the decoder 22 converts the primary color signals R, G, and B into the primary color signals R, G, and B with the luminance signal Y and the color signal C, and performs analog / digital conversion through the switch unit 34. In addition to the input to the unit 23, the horizontal synchronous signal H-SYNC and the vertical synchronous signal V-SYNC are separated and input to the memory controller 29.

The primary color signals R, G, and B are converted into digital signals through the analog / digital conversion unit 23. When a memory command comes from the system control unit 28 to the memory control unit 29, the memory control unit 29 As the command is transmitted from the memory 24 to the memory 24, the current image information is stored in the memory 24.

Thereafter, when a print command is received from the system controller 28, the memory controller 29 takes out the data stored in the memory 24 and transfers data to the line memory 32 one by one. When the data is removed, the data stored in the line memory 32 is transferred to the tone control unit 30 and printed through the thermal print head (TPH) 31.

When the analog primary color signals R, G, and B are input to the digital / analog converter 25 through the memory 24, the analog signals are inverted into digital signals and input to the encoder 26. The primary color signal is converted into a luminance and a color signal by the encoder 26, and the signal is input to the mixing unit 27 to produce a composite video signal and then output through the video output terminal Vout.

When the signal source is a non-electrical signal, the system control unit 28 commands the switch unit 34 to transfer the signal line to the signal line of the signal conversion unit 35.

Then, when the signal conversion unit 35 converts the non-electrical signal into an electrical signal and sends it to the switch unit 34, the signal is transmitted to the analog / digital conversion unit 23, converted into a digital value, and converted into a memory 24. The image information is stored in the memory. Hereinafter, the memory and printing operation are the same as when the electric signal described above is received.

Referring to FIG. 3, a signal conversion for converting a non-electrical signal into an electrical signal is as follows.

When light from the light source 50 passes through the negative film 51 and the amount of light emitted is incident on the image pickup device 52, the image pickup device 52 converts the amount of light into an electric amount by the amount of light emitted and sends it to the color signal processor 53. .

The luminance signal Y is generated through the CD 531 and the low pass filter 532 of the color signal processor 53, and the color difference signal RY is performed through the CD 531 and the color separator 533. Since the image present in the negative film 51 is the inverted value after the production of BY, to compensate for this, the inverted luminance signal (-Y) and the inverted color difference signal (-(RY) ),-(BY)) to send the matrix unit 55 to generate the inverted primary color signals (-R, -G, -B) through the matrix unit 55.

As a general concept, -R, -G, and -B are represented by R, G, and B in FIGS. 2 and 3.

In FIG. 3, the light source 50 is used as a single light source, but the single light source is projected onto the negative film in order by dividing the color of the three elements of light, and the data formed according to the light source at that time are stored at different addresses or the data are combined and memoryd. Can also be stored in

As described in detail above, the present invention has the effect of overcoming the limitation of the signal source by allowing the light incident by the light source to be transmitted to the image pickup device through the negative film to convert the optical signal into an electrical signal for printing. There is.

Claims (2)

A signal converter 35 for converting a signal passing through the film into an electric video signal having primary color signals R, G, and B, and a composite video signal having electrical luminance and color components, and receiving a luminance signal and a color signal. Luminance / color signal separation section 21 to be separated into; and primary color signals R, G, B and horizontal / vertical synchronization signals H-SYNC, V- from the output signal in the luminance / color signal separation section 21; The decoder 22 generating the SYNC and the output of the decoder 22 or the signal converter 35 are selected and transmitted to the analog / digital converter 23 according to the control signal of the system controller 28. It comprises a switch unit 34, a memory 24 for storing the image data converted by the analog / digital conversion unit 23, and a printing unit for printing the image data stored in the memory to the thermal transfer head Color video printer characterized in that. The image pickup device 52 of claim 1, wherein the signal conversion unit 35 receives an amount of light transmitted from the light source 50 through the negative film 51, and converts the light into an electrical amount. With respect to the output of the color signal processor 53 for compensating for the inverted value of the image present in the negative film 51 and the color signal processor 53 for generating the luminance signal and the color difference signal from the signal received from the element 52. And a matrix unit (55) configured to receive an inverted amplifier (54) for inverting and amplifying the inverted primary color signal by receiving the output signal of the inverted amplifier (54).