DE3843645A1 - Optical printer with a half-tone printing system - Google Patents

Abstract

In a printer which prints a half-tone image on a mobile, photosensitive component by means of image exposure, light is used which is emitted by a series of LEDs. The locked image data of a line quantity are transmitted to the respective LED elements within a time period determined for an exposure of an image line, a number of times which corresponds to a desired image density. The respective LED elements emit light in response to each emission of image data and together produce a corresponding electrostatic charge image on the photosensitive component. As a result, a brightness gradation of an image determined by the number of LED light emissions is obtained. <IMAGE>

Description

The present invention relates to an optical Printer with a halftone printing system and in particular on an LED printer in which an LED printer head by binary Image signals is controlled.

In a conventional halftone dot printer, the halftone image that prints from binary signals become the tremor system (dither system) and the density pattern system system) applied. However, these systems do, too if an improvement in the brightness gradation of the Printer by expanding the matrix size is possible in substantially deterioration of the screen raster, so that the printed image for practical use too is out of focus.

An effective method to improve the brightness gradation without the good screen raster  waive is the degree of blackening (density) of an individual to change a point.

For example, JP-OS 59-1 27 465 discloses a brightness Voting procedure in which to produce a halftone picture the degree of brightness of the LEDs is changed.

However, such a gradation of brightness of the LEDs leads to the fact that the structure and consequently the control scheme of a Drive circuit for controlling the power supply to the jewei LED elements becomes complicated.

Another alternative is from JP-OS 60-5 387 (corresponds US-PS 45 96 959) is known in which a drive period for each one of a variety of on an LED printer head attached LED grid point elements is controlled.

This alternative system suffers from the same problems as already mentioned above, namely on a complicated Structure and control difficulties with regard to the Control the drive duration of the LED elements provided Drive circuit.

The object of the present invention is an LED printer ker to create with a halftone printing system, which a has simple circuit construction.  

According to the present invention, an optical printer comprises ker with a photosensitive part that in a vorbe certain direction is movable, and with a variety of punctiform, light-emitting elements that cross to the direction of movement of the photosensitive member are directed, a method by the invention for Solution to the above problem is improved and Exposing an image on the moving part with is designed for light-emitting elements, and the following steps:

• 1. Repeatedly output a line of image data, where the number of repetitions of the image density information corresponds within the for a picture line exposure intended period of time; and
• 2. Controlling the light emission of each individual light emitting elements, depending on the output image data.

According to the above procedure, each the point-shaped, light-emitting elements the light emissions-i.e., duty cycle within the for an image line exposure controlled specific time interval. The means that, in accordance with the number of caused Light emissions, the density of the light excited by the emitting element of exposed pixels, i.e. Pixel  changed and as a result created a halftone image becomes.

An optical printer for the above method of the present invention comprises a shift register for receiving print data; a hold signal generator for generating a hold (latch) signal when the number of dot-shaped light-emitting element units corresponding to the print data have been loaded into the shift register; a latch register for receiving the print data from the shift register in response to the latch signal; scanning signal generating means for generating a scanning signal in accordance with the image density information; wherein the holding register transmits the print data locked therein to the light emitting elements when it is driven by the scanning signal; wherein the scanning signal is transmitted to the respective light emitting elements as many times as it corresponds to the image density information within a period of time n : n is expressed by the following equation:

n = 1 / f ,

where f is the product of the speed of the photosensitive element and the image density to be printed.

According to the above features of the present Er a halftone image can be printed without with such a simple circuit design, on the good one To avoid screen rasterization. Furthermore, the halftone print is system using an ordinary binary (two-stage) LED printer possible.

An embodiment of the present invention is disclosed in following described with reference to the drawings. It shows:

Figure 1 is a schematic side view of the surroundings of an LED printer head and a photosensitive part in an optical printer.

FIG. 2 shows a front view of an LED printer head from FIG. 1; FIG.

Fig. 3 is a block diagram of an electrical circuit that applies ver in the LED printer head of Figures 1 and 2; FIG.

Fig. 4 is a flowchart showing the relationship between various signals and LED light emission conditions in accordance with a three-stage LED control scheme.

Fig. 1 shows schematically the structure of an optical printer with an LED printer head 10th This printer head 10 lies opposite the surface of a drum-like, photosensitive part 11 . In operation, as soon as the light emitted by the LED strikes the drum surface evenly charged by a corona charger 12 , an electrostatic charge image is generated on the surface of the photosensitive member. Then, a toner image corresponding to the electrostatic charge image is formed on the drum surface by a developing device 13 , and this toner image is then transferred to a recording sheet by means of a transfer charger 14 . After this image transfer, the toner material remaining on the surface of the photosensitive member 11 is completely removed by a cleaner 16 . Then the residual charge on the drum surface is deleted by a Löschvor direction.

Fig. 2 is a schematic front view of an LED printer head 10 , the LED row 1 with a plurality of punctiform LED elements 1 a , 1 b ,. . . 1 n shows. These LED elements 1 a , 1 b,. . . 1 n of the LED row 1 are oriented transversely to a direction of movement (indicated by an arrow) of the photosensitive part 11 .

Fig. 3 is a block diagram showing the electrical structure of the LED printer head 10 . As shown, the respective elements 1 a , 1 b,. . . 1 n of the LED series 1 with switching elements 2 a . . . 2 n and NAND gates 3 a ... 3 n connected, so that the respective LED elements 1 a , 1 b ,. . . 1 n can be excited in accordance with the output contents of a holding or blocking register 4 when it is clocked or driven by three types of scanning signals. A signal generator 6 generates a sampling signal STR, a hold or lock signal LA, and an alternating clock signal SCLK (shift clock signal). A data processor creates print information DATA.

A line amount of print information DATA generated by the data processor is loaded into a shift register 5 in synchronism with the change-over signal SCLK. Then, in response to the lock signal LA, the DATA is locked in the latch register 4 .

Fig. 4 is a flowchart showing the relationship between the respective signals and the light emission states of the LED elements operated in accordance with a three-stage image control scheme.

The line clock signal LCLK (line clock signal) is used as a reference variable for a scanning direction printing speed of the optical printer, for example a rotational speed of the photosensitive drum, the revolution (1 / f ) of which is equal to a scanning cycle (ie a scanning cycle).

Generally, the LED printer head includes on its control base a line clock LCLK, based on which the time controls of various signals can be controlled.

A frequency f of the line clock LCLK is represented by the following equation (1):

f = Vp × Pi (1)

With
Vp : processing speed (inch / sec) (rotation speed of the drum)
Pi : print density (dot / inch)

Then the transfer of the print data to the LED printer head through any frequency within the through the following equation (2) reproduced range causes will:

f × n fs (fs) max (2)

With
fs : frequency of the alternating cycle SCLK,
(fs) max : Maximum response frequency of fs of the LED printer head.

With reference to FIGS. 3 and 4, the print data DATA with positive and negative edges of the line clock signal LCLK and in synchronism with the alternating clock signal SCLK are loaded into the shift register 5 . If the shift register 5 a line size of the print data DATA, corresponding to the total number of units of the LED elements 1 a , 1 b,. . . 1 n , the loaded data, in response to a lock signal LA, is passed to the lock register 4 to be locked therein. Subsequently, when activated by entering a next scanning signal STR, the blocked contents of the blocking register 4 become the LEDs 1 a , 1 b ,. . . 1 n transmitted. With these, the respective LED elements 1 a . . . 1 n switched ON either 0 times or 1 times or 2 times during a line scan: 1 / f depends on the type of the input scanning signal.

With the controlled light emission of the individual LED elements 1 a . . . 1 n , an electrostatic charge image is formed on the photosensitive member 11 , and then a toner image corresponding to the charge image is imaged on a sheet by the electrophotographic process described above.

In repetition, according to this particular embodiment of the present invention, the same print data DATA is transmitted twice within one cycle (1 / f ) of the line clock LCLK and the LED elements 1 a , 1 b . . . 1 n are switched ON either 0 times, 1 times or 2 times. A full dot image density is obtained with the double exposure. With the single exposure, half a dot image density is obtained. As a result, a three-level halftone image can be printed.

If now the number of points corresponding to a line size of the print data is less than the total number of units of LEDs 1 a . . . 1 n is, for example because the sheet is too small, phantom data 0 should be added according to the incorrect amount of the points in order to preserve a sufficiently complete imaging area.

In the optical printer described above, the total exposure time of the LED elements is 1 a . . . 1 n (ie the switching rate of the scanning signal STR) is set to 50%. In contrast, this rate can be appropriately changed within the range of 100%.

Furthermore, instead of the three-step described above Image control schemes, another tax scheme based on ir based on a number of levels, within the permissible gene, represented by the above equation (2) Response area of the LED printer head possible. Even in the In these cases, a high-quality halftone print image can be obtained without sacrificing screen rasterization.  

As can be seen from the above, the shift is construction of this optical printer very simple. Also in the event of a change, e.g. through different tactics nale, printing a halftone image is straightforward using the ordinary two-stage (binary) Type, i.e. of an ON-OFF-like LED printer head possible.

Furthermore, in the above description, the halftone image is determined solely by the frequency of light emission from the LED elements 1 a . . . 1 n printed within one line pass (ie one scan cycle). Yet another control scheme is possible by creating a variety of output circuit types to create different one-time light emission times and to effectively correlate light emission times with light emission times.

The present invention has been described so far as it executed in an optical printer with a row of LEDs becomes. However, the invention is also in other optical Printer types, such as one that uses a ferroelectric (PLZT) Shutter and a polarizer used in combination applicable.

Claims (3)

1. A method of operating an optical printer having a photosensitive member movable in a predetermined direction and a plurality of punctiform light-emitting elements oriented transversely to the direction of movement of the photosensitive member, the light-emitting elements forming an image by an exposure process generate on the movable, photosensitive part, characterized in that a line of image data is repeatedly output within the time period provided for an image line exposure, the number of repetitions corresponding to the image density information; and that the light emitting elements emit light depending on the output of the image data. 2. Optical printer using the method of claim 1, with a shift register for receiving print data; with stop signal generating means for generating a stop signal when the print data corresponding to the number of units of the punctiform light-emitting elements has been loaded into the shift register; a holding register for receiving the print data from the shift register in response to the lock signal; and scan signal generating means for generating a scan signal in accordance with the image density information; wherein the holding register transmits the print data locked therein to the light emitting elements when it is driven by the scanning signal; characterized in that the scanning signal can be transmitted to the respective light-emitting elements ( 1 a , 1 b ,... 1 n ) as many times within a period of time n as corresponds to the image density information, where n = 1 / f and f the product from the speed of the photosensitive part and the printing density. 3. Optical printer according to claim 2, characterized ge indicates that the punctiform, light emitting elements are LEDs.