KR920006101B1 - Thermal printer head - Google Patents

Abstract

The apparatus includes a line memory (100) for storing the data for each line up to the time when one line is printed. A comparator (400) compares the output of a gradation counter (300) with the output of the line memory (100), and a temperature detector (500) detects the temperature of a thermal printer head. A pulse generating section (700) generates reference pulses, and a PWM generating section (800) generates strobes signals by the output of the pulse generating section (700), while a decoder (900) decodes the output of the PWM generating section (800). With the apparatus, the temperature detectors are installed to compensate the temperature, and therefore, the picture quality is improved.

Description

Thermal recording device of video printer

1 is a block diagram of a video printer.

2 is a block diagram of a conventional thermal printer head.

3 is a thermal recording apparatus of a printer in a conventional video.

4 is a block diagram of a thermal printer head according to the present invention.

5 is a thermal recording apparatus of a video printer according to the present invention.

* Explanation of symbols for main parts of the drawings

100: line memory 200: controller

300: gradation counter 400: comparator

500: temperature detector 600: gradation rom

700: pulse generator 800: PWM pulse generator

900 decoder 1000 heating element driving unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video printer apparatus for printing and outputting an input of an image signal. More particularly, the present invention relates to a thermal recording apparatus of a video printer capable of improving image quality by detecting and correcting a temperature of a surface of a thermal print head.

In general, a video printer apparatus has been proposed in response to the necessity of printing an image by momentary capturing of an image signal or printing an image recording content to be reproduced on a monitor through a recording apparatus such as a still camera.

In the conventional case, as shown in FIG. 1, when an image signal is input, the decoder 1 separates the R, G, and B analog signals and outputs vertical and horizontal synchronous signals. In addition, when the memory command signal is applied to the memory input terminal I1, the memory controller 8 generates a sampling pulse to the analog / digital converter 2 in accordance with the vertical and horizontal synchronization signals.

In the analog digital conversion section 2, analog R, G, and B signals are recorded in the image memory 3 in accordance with the recording address specified by the memory control section 8 in accordance with the sampling pulse. At this time, the reason why the digital R.G, B signals are written to the image memory 3 once is due to the difference between the speed of the video signal and the printing speed.

When the command input signal is applied to the print command input terminal I2 after the memory function is completed, the print control unit 10 applies a read address to the image memory 3 and designates a write address in the line memory 5. Select the memory selection switch. On the other hand, in order to print R, G, and B three-color signals on recording paper, it is necessary to change to three colors of yellow (Y), cyan (C), and magenta (M), so that the R, G, and B digital data recorded in the image memory 3 are recorded. In order to convert the color into three colors Y, M, and C, the line memory 5 is sequentially memorized by a memory selection switch and then stored in the line memory 5 under the control of the print control unit 10 again. The transferred data to the control means (G).

The control means 6 sequentially converts the R, G, and B signals into Y, M, and C signals, and at the same time reduces the effect of density conversion due to the correlation between the characteristics of the recording paper and the amount of heat generated by the head. After the resistance correction is performed to reduce the resistance deviation of the heating elements of the recording heads, heating data is applied to the recording heads of the recording unit 7 in the order of three colors of Y, M, and C to perform one-line seam printing to perform one-screen printing. To complete.

2 is a configuration diagram of a conventional thermal print head, and FIG. 3 is a thermal recording apparatus of a conventional video printer. The line memory 11 which receives data of vertical one-line components from digital image data stored in a digital memory is shown in FIG. By control of the control part 13, it keeps until 1 line printing completion.

The data stored in the line memory 11 is applied to the comparator 14 by the control of the controller 13. The comparator 14 receiving the data from the line memory 11 compares the counter value of the gradation counter 22 to output. In addition, when the temperature is detected by the temperature detector 16 and applied to the gradation ROM 15 and given an address by the counter value of the gradation counter 12, the gradation ROM 15 outputs concentration time data for controlling the intermediate concentration. Done. The PWM pulse generator 18 for inputting the data output from the grayscale 15 may generate and output a strobe pulse according to the pulse of the pulse generator 7.

The decoder 19 for inputting the signal output from the PWM pulse generator 18 decodes and selects and outputs the strobe signal. The shift register 10 for inputting data output from the comparator 14 outputs the shifted data by the control clock of the controller 13. The latch unit 21 for inputting data output from the shift register 20 is latched out in accordance with the clock signal of the latch pulse generator 24 driven by the control of the control unit 13.

The strobe driver 22 for inputting the data latched by the latch unit 21 outputs data according to the decoded strobe signal of the decoder 19.

The output signal of the strobe driver 22 drives the heating element array 23. At this time, the thermistor detects the temperature of the central portion of the heating element array 23 by the thermistor according to the configuration of FIG.

As described above, the conventional thermal print head thermal recording apparatus detects a temperature by placing the thermistor at the center of the head substrate, so that the temperature correction is actually performed for the highest temperature. There is a problem of image quality deterioration because it is printed in a small concentration.

Accordingly, an object of the present invention is to provide a thermal recording apparatus of a thermal print head capable of compensating a temperature according to print density by generating a strobe signal according to the number of thermistors by configuring a plurality of thermistors in a head substrate in a thermal print head. .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

4 is a configuration diagram of a thermal print head according to the present invention, and FIG. 5 is a circuit diagram according to the present invention, where 500 is a temperature detector 600, a gradation ROM 700 is a pulse generator 800 is a PWM generator 900 is a decoder 1000 is a heating element driver A line memory 100 that receives data of vertical one-line components from the digital image data stored in the digital memory and stores them until the completion of one-line printing; a controller 200 for controlling the system; and the controller 200 Detecting the temperature of the thermal print head and the comparator 400 for inputting and comparing the output of the gray counter 300 with the output of the gray counter 300 and the output of the line memory 100 under the control of The first temperature detector 501, the first grayscale 601 for receiving the output of the gradation counter 300 and the output of the temperature detector 506, and outputting concentration and time data for intermediate concentration control, and a reference.PWM generator for generating a strobe pulse by inputting the first pulse generator 701 and the output signal of the first gradation 701 to generate a pulse; 801, a first decoder 901 for selectively outputting a first strobe pulse by decoding the output signal of the PWM pulse generator 801, and a second temperature detector 602 for detecting a temperature of the thermal print head. And a second gradation rom 502 for receiving the output of the gradation counter 300 and the output of the second temperature detector 602 and outputting concentration and time data for intermediate concentration control, and for generating a reference pulse. A PWM generator 802 for inputting a second pulse generator 302 and an output signal of the second gradation 502 to generate a strobe signal by the pulse of the second pulse generator 702; A second decoder 902 for decoding the output signal of the PWM pulse generator 802 to selectively output a second strobe pulse; The latch pulse generator 1000 generates a latch clock pulse according to the control signal of the controller 22 and the comparison output data of the comparator 400 is inputted by the control clock of the controller 200. A shift register 1101 for outputting the shifted data, a latch unit 1102 for inputting the shifted data in the shift register 1101 and latching and outputting the latched signal by the clock signal of the latch pulse generator 1000; The strobe driver 1103 for inputting the latch data of the latch unit 1102 and outputting the data by the decoded strobe signal of the decoders 901 to 902 and the output signal of the strobe driver 1103 are generated. It is composed of a heating element array 1104 is provided so that a plurality of temperature detection unit is configured to generate a plurality of strobe pulses.

Based on the above configuration, an embodiment of the present invention will be described with reference to 4-5.

First, the gradation counter 300 which receives the control signal of the controller 200 outputs to the counting first and second gradation ROMs 601-602 and the comparator 400, and the line memory 100 is controlled by the controller 200. ) Are sequentially input to the comparator 400.

In the comparator 400 for inputting the output signal of the line memory 100 and the output signal of the gradation counter 300, the sequential output data from the line memory 100 and the output "1" of the gradation counter 300 and Are compared and sequentially applied to the shift register 1101 of the thermal print head, and at the same time, a clock pulse for driving the shift register 1101 of the thermal print head is applied to the clock terminal of the thermal print head. do.

When data comparison of one line component embedded in the line memory 100 is completed in the comparator 400, the control unit 200 operates the latch pulse generator 1000 to latch the latch pulse of the thermal print head. The output data of the sequential comparator 400 included in the shift register 1101 is applied to the clock stage of the unit 1103 to the latch unit 1103.

After the latch pulse is generated in the latch unit 1103, the control unit 200 operates the first and second PWM generators 801. At this time, the first and second gradation ROMs 601 and 602 have density time data embedded therein, so that the output “1” of the gradation counter 300 operates as an address in the first gradation ROM 601 and is configured as an address as shown in FIG. 4. Data contained in the address of the temperature detection card is inputted to the first and second PWM generators 801 and 802 according to the outputs of the 501 and 502, and the input data is the first and second pulses. By the control of the generators 701 and 702, the signal is converted into a PWM signal having a temporal concept.

The first decoder 901 for inputting the output signals of the first and second PWM generators 701 and 702 decodes and selectively outputs the first and second strobe pulses. After the above process, the first gray scale (concentration) expression is completed. At this time, the gray scale counter 300 increases the output to "2" and transmits data of the thermal print head to the second method in the same manner as described above. Generates a strobe signal to complete the second gray scale expression, and if the number of gray scales to be expressed is configured to repeat the number of gray scales to be expressed, a plurality of strobe pulses are generated and the temperature for each part of the heating element of the thermal printer head is increased. Will be corrected.

As described above, since a plurality of thermistors are installed in the thermal printer head to detect the temperature for each part of the heating element and correct the temperature, there is an advantage of improving the image quality.

Claims (1)

A thermal recording apparatus of a video printer, comprising: a line memory (100) that receives digital image data output from a digital memory, receives line component data, and stores one line of printing at the end of printing, a controller (200) for controlling the system; And a gradation counter 300 counting and outputting the control by the control unit 200, a comparator 400 comparing and outputting the output data of the gradation counter 300 and the output data of the line memory 100, and a thermal printer. The temperature detector 500 detects temperature by installing a plurality of thermistors in a predetermined position on the substrate of the head, and receives the output signal of the gradation counter 300 and the output signal of the temperature detector 500 to adjust the concentration for intermediate concentration control. And a gradation ROM 600 for outputting time data, a pulse generator 700 for generating a reference pulse, and an output signal of the gradation ROM 600 to be input by the pulse of the pulse generator 700. PWM generator 800 for generating strobe signal by pulse width modulation, decoder 900 for selecting strobe pulse by decoding output signal of PWM generator 800, and output signal of comparator 400 To generate a strobe signal corresponding to the temperature detection according to the number of thermistors in the temperature detector 500, and having a heating element driver 1000 for driving the heating element array by the strobe signal of the decoder 900. Thermal recording apparatus of a video printer, characterized in that the enhancement.

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