JPS61229574A - Simple energy-controlling system for thermal head - Google Patents

Abstract

PURPOSE:To eliminate effects of accumulation of heat due to the quantity of black information in the preceding line and achieve printing with uniform density in each line, by correcting the printing energy for the next line in accordance with the quantity of information in the preceding line. CONSTITUTION:When period signal (c, d) is inputted, set points (h) held by a set point holding means 4 are preset on preset counters 1, 2, 3, and the number of bits of black signals in image data is counted. When the count exceeds the set point in one period of the period signal, a CO signal (g) is outputted from the counter 3 to a shift register 6, and image data will not be inputted to the counters 1-3. The period signal is inputted to the shift register 6 as a shift clock. At the end (corresponding to one line) of the fourth period, an EOL signal is outputted, the data in the shift register 6 are latched in parallel (l) by a latch circuit 7, and are inputted to a ROM 8 as an address. Correction data of pulse width corresponding to this are outputted from the ROM 8.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a simple energy control method for a thermal head, and in particular to a thermal head that can easily correct heat accumulation. This paper relates to a simple energy control method.

(Conventional Techniques and Techniques> Conventional) Thermal control of a thermal transfer recording device uses a thermal head of about 1.5-1 seconds/line. The temperature of the board is detected by the thermistor attached to the thermal head, and depending on the detected temperature, the voltage is applied to the heating resistor and the resistance element. [It was 11,311 times per day.

For example, 1:2 before the recording of 1. Su-
Detects the temperature of the board of the multihead, and if the temperature is 1, for example.
At 0°C, the heating resistor element is heated with a pulse width of 0.5 seconds, and its concentration is, for example, 15"Ct'$.
5h, the heating resistor element was controlled with a pulse width smaller than 0.5 seconds.Contrary to the above, if the i degree of one plate of the thermal head is smaller than 1o:c,li, then 0. The heating resistive element was controlled with a pulse width longer than 5 seconds.

This control is performed only once for each page recorded, and even if the temperature of the Dogmal head board changes after one page has been recorded, no correction is made for this change. .

(Problems to be Solved by the Invention) The above-mentioned conventional technology has the following 1211 II points.

If a thermal transfer recording device using a thermal head that uses low energy and low power efficiency, that is, a thermal head that has heat storage but poor thermal response, is controlled using the conventional thermal control method described above, the black color in one line will be reduced. , the amount of information X is the shadow of heat accumulation due to the amount of black information on the previous line.

There was a problem in that the sound became obvious and the density of the print varied from line to line.

□ □□For example, at the start of 1st recording, the applied energy to the heating resistor element of the i thermal head is □
There was a problem that if the settings were set so that even lines with a small amount of information would appear clearly, if lines with a large amount of information continued, the print would be blurred or trailing. On the other hand, contrary to the above, if the line with a large amount of information is set up so that it is clearly visible, the line with a small amount of information will be
There was a problem: it became thinner or blurred.

The present invention has been made to solve the above-mentioned problems.

(Means and operations for solving the problems) In order to solve the above-mentioned problems, the present invention provides a low-cost □, P8 dot, "'5[sec// In a thermal transfer recording device such as a run, the printing energy of the next line is corrected according to the amount of information on the previous line.There is a characteristic at the point. .

(Example) □ ・： ・
The present invention will be described in detail below with reference to the drawings.

'1...:' :Figure 1 is a Brong diagram of one embodiment of the present invention.
□Ru.

Also, Figure 2 shows the signal yard for the main signal in Figure 1.
□゛ 1 In the figure, 1, 2 and 3 are the “PuzzleB!Set counters”, and the periodic signals are inputted to the counters 1, 2 and 3.
The set value held in the set value holding means 4 is set in the preset counter.・
゛・・：゛.

The image data passes through the OR gate 5 and is input to the preset counter set gate □. The preset counter set color 1 counts the number of bits of the black signal in the image data described above in synchronization with the data clock (data CLK). When the number of black signals exceeds the set value within one period of the periodic signal, the preset counter 3 will change the shift register 6 [
A carrier signal (Co signal) is output.
□ In the fourth example shown in Part 4, the period T
It is shown that Δ'□ is outputted at Cσ times 1', T-, and T4.
□Once c 'o 儂' is output, the sled circumference□
During the period, the preset counter
The Co signal is maintained at 1, and the OR gate 5 is opened by the Co signal.

However, after the J'c 'o signal is output, the image data does not pass through the OR gate 5 and is sent to the preset counter 1.
There is no input 1 in ~3□”.
The periodic signal is input to the shift register as a shift clock. For example, as shown in the second knee, the traces of
T.I.

At Tt and T4, the shift register 6 is loaded with a ``1''.
If there is an input/signal of "1n" in the period T3, then the storage element of the shift register 6 (
The data stored in (11* a2 h a39.aa) becomes (1, 1, 0, 1).

Next, at the end of the fourth cycle, an EOL signal (End O
r Line ) is output and input to the latch circuit 7 , the data in the shift register 6 is latched in parallel to the latch circuit 7 .

Next, the signal latched by the latch circuit 7 is input to RO・M゛,8, and becomes the address of ROM8! Ru.

Since the ROM 8 stores correction data for the pulse width applied to the heating resistor element of the thermal head, the correction data for the pulse width corresponding to the data latched by the latch circuit 7 is output from the ROM 8. .

For example, if one line of image data contains a lot of black information on average, the count value of black bits exceeds the set value in each of the periods T1 to T4, and the shift register 6 and latch Circuit 7 has (1, 1, 1, 1
> data is input. At this time, the corresponding (1
, 1, 1, 1), the energy applied to the heating resistor element during thermal transfer of the next line is reduced.

Conversely, if one line of data contains only a small amount of black information, the latch circuit 7 will have (0°0, O, O).
data is latched. At this time, ROM8 has (0
, O, Mound, 0), if correction data for adjusting the buff width is inputted, the t energy applied to the heating resistor element during thermal transfer of the next line increases.

As described above, in this embodiment, it is possible to correct the energy applied to the heating resistor element of the thermal head during thermal transfer of the thorny pine based on the image information of the previous line.
Therefore, high-quality thermal transfer recording can be performed.

Note that in this embodiment, one line of image data consists of four
Although this is an example in which the information is transferred in batches, it goes without saying that the present invention is not limited to this.

Roughly speaking, in the above embodiment, one set of preset counters was used and the black information of the previous line was used for pulse width correction, but two or three sets of preset counters were used instead of the one set of preset counters.
By providing sets of preset counters in parallel and using the sets of preset counters by switching between them,
Of course, the black information of the line or the previous three lines may be counted, and the pulse width correction may be performed using the black information of the previous two lines or the previous three lines.

Furthermore, when the energy control method of the present invention is used together with the conventional page-based heat control method, the effect will be even greater.

(Effects of the Invention) As is clear from the above description, according to the present invention, the following effects are achieved.

(1) The printing energy for each line can be controlled to be averaged by simple means.

(2) Since the recorded image has less unevenness in shading and is free from blurred or blurred print, it is possible to obtain a recorded image of good quality.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of one embodiment of the present invention, and FIG. 2 is a block diagram of an embodiment of the present invention.
3 is a time chart of signals in the main part of the figure. 1.2.3... Preset counter, 4... Setting value holding means, 6... Shift register, 7... Latch circuit, 8... ROM

Claims (2)

[Claims] (1) A preset counter that counts the number of bits of black information from image data for a predetermined period (hereinafter referred to as one cycle) and outputs a carry-out signal when the number becomes equal to a preset value; means for holding the signal held in the means for each period; means for latching the signal held in the means at each scheduled period; and means for converting the signal latched in the latch into energy correction information for applying the signal to the heating resistor element of the thermal head. A simple energy control method for a thermal head characterized by comprising a means for converting the energy. (2) The thermal head according to claim 1, wherein the latch means latches the input signal using an EOL signal that is output when one line of image data transfer is completed. Simple energy control method.