DE4124038A1 - Print head used with photosensitive drum - has fluorescent tube with matrix of light emitting points served by corrected values held in ROM - Google Patents

Abstract

A print head (1) for use with a photo sensitive drum contains a fluorescent tue (2) that has an array of strip formed anodes and a number of control electrodes that form a matrix of 8 x 304 points. The anode connect with drive stages (3) and the control electrodes with a drive circuit (4). The drive circuit operates together with a ROM memory that contains correction values such that each point of emission generates uniform value. The correction values define the pulse widths of the signals to be emitted. ADVANTAGE - Constant light emission from end point.

Description

The invention relates to a write head for an optical Printing device according to the preamble of the claim.

Fig. 6 schematically shows the general construction of an optical printer having a photosensitive drum A. The photosensitive drum A rotates clockwise and is subjected to charging by the charger B. The surface of the charged drum A is irradiated with punctual light from the printhead C, which contains a plurality of luminous dots, with the result that the desired latent image consisting of characters, figures and the like, which is then moved through a development device D is developed, is trained. A Abzugspa pier F, which is contained in a cassette E, is passed between the surface of the drum A and a transfer heating device G, so that the developed image on the surface of the drum A is successively transferred to the print paper F. Fig. 6 shows an erase lamp H for deleting the image on the drum A, which was the subject of the image transfer, and a cleaning blade J for cleaning the surface of the drum A.

In such a write head, which contains a plurality of luminous dots, an arrangement of light-emitting diodes (LED), which has a plurality of linearly arranged LEDs, or a fluorescent vacuum tube according to Japanese Patent Application No. 1 74 997/1985 be used. This fluorescent vacuum tube is constructed as shown in FIG. 7. In particular, the tube contains a plurality of strip-shaped anodes 100 , over which a plurality of control electrodes 101 , each formed with a gap, are arranged in such a way that they cross the anodes 100 at an angle. The column of control electrodes 101 divides the electrodes 100 , which results in a plurality of luminous points 102 , which are determined in such a way that they are arranged obliquely along the column. A lighting timing of the luminous dots 102 is set with respect to the operation of the drum A so that the surface of the drum A is irradiated in succession with the light from the dots 102 which form a straight line parallel to the axis of rotation of the drum is emitted.

In a writing head constructed in this way, it is desirable worth the amount of light emitted by the luminous dots reproduce as uniformly as possible to create an optical Get printers that have improved print quality points. Conventional printheads use for this purpose System in which a driver voltage for each driver switch circle for the operation of the illuminated dots is controlled to the Amount of light for each red dot group, which is a variety of  Contains luminous dots and each by one of the switching circles is controlled to vote.

In addition, in the conventional tube, the driving voltage is controlled as shown in FIG. 7. In particular, the driver voltage is controlled by means of a zener diode 103 , which is arranged for two or more strip-shaped anodes 100 each, or by means of a resistor arrangement, which is arranged for each control electrode 101 . An alternative embodiment is the simultaneous regulation of the driver overvoltage for the anodes 100 and the driver voltage for the control electrodes 101 .

According to the previous illustration, convention Lichen printhead the correction of the amount of light of the luminous points by dividing the luminous dots into groups leads. Such constructions allow the lighting points of each group emit equal amounts of light. Each but the amount of light emitted by the groups is basically non-uniform, so that the amount of light is clear fluctuates between the red dot groups. So that's an ago conventional print head unfavorable for an optical printer.

The object of the present invention is accordingly in creating a printer printhead that made it possible light, the amount of light emitted by each point of light is the same moderate and in particular fluctuations in the Exclude the amount of light between the illuminated dots. These Task is by the features according to claim 1 solved.

The write head according to the invention contains a large number of Illuminated dots to form a latent image on a Recording medium, a driver device for operating the Illuminated dots through driver signals of different pulse widths and a ROM with correction values D for each light point that were previously stored in it, making it possible  is to supply the correction values D to the driver device. The correction values D are formed on the basis of the Values P, which indicate the amount of light of each luminous point ben whose light emission is on the same Im pulse width establishes. In particular, the correction values for each red dot by creating a frame area of the Correction factor S = Pmin / P of the pulse width, that of the Relationship between the maximum value Pmax of the values P and ih rem depends on the minimum value Pmin, is determined, and the correction D values of the pulse width corresponding to the correction factor S is set within the set range, the Correction factor S is calculated for each luminous point.

Examples from the prior art and execution examples games of the invention will now be described with reference to the accompanying Drawing described. Show it:

Fig. 1 is a block diagram of an embodiment of the writing printer head;

FIG. 2 is a flowchart showing the process of calculating the correction values stored in a ROM in the print head shown in FIG. 1;

Fig. 3 is a graphical representation of the results of a measurement of the light quantity distribution of red dot th before the correction in the printer head;

Fig. 4 is a graph showing the results of measurement of the light amount distribution of light punk th after the correction in the printer head;

Fig. 5 is a timing diagram illustrating the operation of the write head;

Fig. 6 is a schematic illustration of the general structure of an optical printer; and

Fig. 7 is a schematic representation of a conventional printer printhead that contains a plurality of light dots.

An embodiment of the write head 1 ( Fig. 1) contains a fluorescent tube. The fluorescent tube 2 contains a plurality of strip-shaped anodes and a plurality of control electrodes, which are each designed with a gap in such a way that they cross the anodes at an angle, so that the gaps divide the anodes and thus form a large number of luminous dots. In particular, eight anodes and three hundred and four control electrodes are arranged, from which it follows that each gap determines eight luminous points in a direction which crosses at an angle the longitudinal direction of the anodes, resulting in a total number of 2432 (= 8 × 304) luminous points.

Each of the anodes of the fluorescent tube 2 ( FIG. 1) is connected to an on driver 3 , and the control electrodes are connected to a driver device 4 . The driver device 4 receives correction values, which will be described below, in order to generate a driver signal and then to vary the pulse width of the driver signal in sixteen steps, in order to allow the lighting time of the illuminated dots or a time range during which each of the illuminated dots emits light to correct so that the amount of light emitted by each light spot is made uniform. For this purpose, the driver device 4 contains a grid driver 5 , an AND gate switch 6 , a comparator 7 , a holding circuit 8 and a shift register 9 . A ROM memory 10 is connected to the shift register of the driver device. Correction values D of the pulse widths previously stored for each individual illuminated point are set in the ROM. The correction values stored in the ROM are selected in response to a signal supplied from an address counter 11 , and then transferred to the shift register 9 . A step counter 13 is connected to the comparator. The write head 1 further includes a timing circuit 12 , the function of which is to supply the anode driver 3 , the address counter 11 and the driver device 4 with various types of clock signals or control signals.

In the following the correction values D of the pulse width, previously stored in the ROM.

First of all, the driver device 4 is actuated in order to operate the luminous points of the fluorescent tube 2 under similar driver conditions, so that the luminous points emit light. In particular, each anode is supplied with the same drive voltage and each control electrode with a driver signal with the same pulse width, as a result of which the luminous dots emit light for the same time range. The amount of light emitted by each light point operated in this way is measured by means of a suitable measuring device for determining the light quantity distribution, which results in the values P which indicate the amount of light emitted by each light point under consideration ( FIG. 3). In Fig. 3, the axis of abscissa represents numbers assigned to each of the control electrodes, and the values P show an average value between a maximum value of the amount of light emitted from each of the eight luminous dots for each control electrode and its minimum value. The values P are then input into a data processing device 100 ( FIG. 2).

A lower limit value for the light quantity of the luminous dots is then entered into the data processing device, as indicated by step 101 in FIG. 2. The lower limit value varies depending on the operating stress of the write head, for example depending on the printing speed and represents a minimum value of the amount of light that allows the write head to be used as a light source.

The values P are then compared in the data processing device (step 102 ), so that a maximum value Pmax is determined from the values together with a minimum value Pmin.

The minimum value Pmin determined in this way is then compared with the lower limit value described above, as indicated in step 103 in FIG. 2. If the minimum value Pmin is less than the lower limit value, the light tube 2 is considered defective in accordance with the lack of light quantity. On the other hand, when the minimum value Pmin is larger than the lower limit value, the correction values D for determining the pulse widths of the drive signal which is sent to each red dot are gradually reduced, so that the amount of light of each red dot decreases to a height corresponding to the minimum value Pmin in order to make the amount of light of each luminous point uniform.

In particular ( FIG. 2, step 104 ), the ratio between the maximum value Pmax of the values P and their minimum value Pmin is calculated in order to determine a frame area of the correction factor S of the pulse width of the driver signal which is generated by the grid driver 5 for operating the luminous dots . In the event that the ratio of the maximum value Pmax to the minimum value Pmin z. B. 1: 0.7 (Pmax: Pmin = 1: 0.7), the luminosity of a luminous point that emits light with the maximum value Pmax is reduced to the minimum value Pmin, in which the luminous point with the maximum value Pmax has a pulse width of z . B. 1, this pulse width is reduced to 0.7 ver. Thus, in this example, the correction factor S is set in the range from 1.0 to 0.7.

Thereafter, the above-mentioned frame area of the correction factor S is ordered into a predetermined number of levels so that each of the levels in the series is represented by a correction factor S of its upper limit. Then a pulse width corresponding to the pulse width is determined from each of the stages in the row, which is averaged with a correction factor S = 1. And then it is caused that the pulse width thus determined corresponds to the correction values D, each of which corresponds to the steps of the sequence. In the exemplary embodiment listed in table 1, the frame range of the correction factor S is between 1.0 and 0.702. It is divided into fifteen stages, which corresponds to the number of variable stages of the output pulse of the grid driver 5 , the correction values being divided into the sizes 1 to F.

Table 1

The frame area is in Table 2 below of the correction factor S between 1.0 and 0.6.

Table 2

Then, in accordance with step 105 ( FIG. 2), the correction factor S of each of the luminous points is calculated in accordance with the following formula:

S = minimum value Pmin / measured value P.

Then, in accordance with step 105 ( FIG. 2), the correction factor S of each of the illuminated points is calculated in accordance with the following formula.

S = minimum value Pmin / measured value P.

The correction values D for each luminous point are then determined (step 106 ) as a function of the correction factor S calculated in this way.

Thereafter, the correction values D for each luminous point are stored in the ROM memory 10 (step 107 ) by means of a ROM writer.

The operation of the write head 1 will now be described with reference to FIGS. 1 and 5.

A data clock signal, which is generated by the timing control circuit 12 , is supplied to the address counter 11 , whereby the correction values D are sequentially supplied from the ROM 10 to the shift register 9 . Thereafter, a hold signal in ge appropriate timing synchronized with the Datentaktsi signal to the hold circuit 8 , so that the correction values D from the shift register 9 are held in the hold circuit 8 .

The stage counter 13 counts a stage clock signal that is generated by the timing circuit 12 every time it is reset by an erase signal. The correction values held in the holding circuit and a value counted with the pedometer are compared with each other in the comparator 7 .

When the comparison shows that the correction values, which are stage data, are greater than or equal to the counted value, the correction values are given to the AND gate switch 6 to turn on the grid driver 5 , so that in a time range, during which Grid driver 5 is turned on, which corresponds to the pulse width of the driver signal, which is fed to the control electrodes of the fluorescent tube 2 . Thereafter, in a time range in which the correction value D is caused to fall below the counted value, the output signal of the grid driver 5 is switched off. In particular, the pulse width of the grid output signal for each control electrode is corrected at sixteen stages depending on the correction values D.

When the anode driver 3 drives the anodes of the fluorescent tube 2 in synchronism with the above-described operation of the control electrodes, a plurality of illuminated dots are actuated by a drive signal, the pulse width of which is determined as a function of the correction values D which are stored in the ROM- 10 . Consequently, the light emission from the luminous dots must be uniform. Fig. 4 shows results of a measurement solution of the amount of light of each luminous point according to the embodiment. The results clearly show that in the embodiment, a fluctuation in the amount of light from each light spot is suppressed, so that the write head according to the embodiment significantly improves the printing quality of a printer.

According to the invention, it is possible for each of the lights to correct points emitted light quantity separately, whereby a fluctuation in the amount of light is significantly reduced. Also if the distribution of the amount of light during use fluctuates, the correction values can be changed according to the invention set by resetting the amount of light of the luminous dots be so that the amount of light of the luminous dots is uniform becomes.

Claims (1)

Print head for a printing device with a large number of illuminated dots to form a latent image on a recording medium and with a driver device for operating the illuminated dots, characterized by a ROM memory ( 10 ) with correction values (D) previously stored therein for each illuminated dot are supplied to the driver device, the correction values (D) being set by a frame area of a correction factor (S = Pmin / P) of the pulse width, which is determined by a ratio between a maximum value Pmax of the values (P) which is given by each illuminated dot due to the Specify the same pulse width emitted light quantity, and a minimum value Pmin depends on these values, and the correction values (D) of the pulse width with respect to the correction factor (S) within the specific frame range be determined, thereby the correction factor S for each Calculate red dot, the signal output by the driver circuit a variable I pulse width.