DE4220280A1 - Line-by-line optical beam deflection by rotating mirror - randomly selecting polygon faces for adjacent line scans in conjunction with modulation control memory read=out. - Google Patents

Abstract

The method involves scanning (13) a surface (11) of a document by a beam (2) generated, e.g. by laser (1), and brightness-modulated (3), e.g. acousto-optically, prior to reflection from faces (7) of a polygonal mirror (6) rotated (9) about its axis (8) at uniform speed. Whenever the top line (14) is scanned, a pulse generator (16) triggers a random number generator (20) addressing input and output selection memories (25,22) associated with the modulator control memory (4). A tiltable lens or mirror (18) is operated to suppress the scan while unselected faces of the polygonal mirror are in transit across the optical path (2'). USE/ADVANTAGE - In electronic copier. Interference due to mirror surface residual defects is avoided at comparatively low cost.

Description

The invention relates to the field of electro African reproduction technology and relates to a process and a device for line-by-line deflection of an optical Radiation over a surface by means of a rotating Mirror, in particular a multi-surface mirror (Polygon mirror).

A line-by-line deflection of optical radiation via an area is found, for example, in master scanners and held in recorders.

In a document scanner, also called an input scanner, a light beam generated in a scanning element is and line by line over a template, and that of the Original reflected or transmitted scanning light in an optoelectronic converter into an image signal changes.

In a recording device, also recorder, imagesetter or Output scanner called, one in a record organ-derived light beam from an image signal intensi modulated as a result, point by point and line by line using a light sensitive recording material led to rasterized or make non-rasterized recordings.  

For the line-by-line deflection of a light beam over a Area in the form of a template or a record materials are mainly rotating polygon mirrors used. The individual mirror surfaces of a polygon mirrors usually have reflection differences and Angular errors on, called mirror errors for short, too incorrect positioning of the deflected light beam on the original or the recording material.

DE-A-30 46 584 describes a method for correcting the Known mirror error of a polygon mirror, in which the Mirror errors of the individual mirror surfaces recorded in advance correction values are determined based on the detected mirror errors and saved and the mirror during operation errors due to appropriate correction deflections of the light be reduced.

Despite such a correction, the mirror surfaces have however, residual errors caused by the cyclical alignment sequence of the individual mirror surfaces of the rotating Polygon mirror z. B. in line-by-line recording a recurring recording material Line structures regarding position, point quality or Cause intensity. These line structures can be used with the periodic image and raster structures Beatings and interference effects in the recording to lead.

To compensate for interference effects in a line-by-line image recording using a writing beam it is known from DE-A-23 15 594, the writing beam statistically across the row direction to deflect amounts, the maximum of which corresponds to half the line spacing, which avoids a comparatively strong distraction. Such a statistical deflection of the write beam within the lines, causing a wobble of the lines corresponds, but requires a very fast distraction  direction ahead of the writing speed. The known method is thus for example in facsimile Devices can still be carried out comparatively well, with devices the reproductive technology used for processing very high Amounts of data are designed, however, would be considerable electronic effort required.

The ent by rendering a picture line by line standing faults can theoretically also by a suitable selection of the line period can be suppressed. This However, the procedure fails in practice with the Residual defects in the mirror surfaces caused Moir's because the Line period with the period of one revolution of a polygon is not the same.

The object of the present invention is therefore a Line deflection method and device to improve optical radiation in such a way that by Residual errors of the mirror surfaces with interferences comparatively little effort can be avoided.

This task is carried out with regard to the procedure by the Claim 1 and with regard to the device in the Claim 9 specified features solved.

Advantageous further developments are in the subclaims specified.

The invention is explained in more detail using the example of a recording device with reference to FIGS. 1 and 2.

Show it:

Fig. 1 is a block diagram of a recording device and

Fig. 2 is a further development of the recording device.

Fig. 1 shows a block diagram of a recording device with a light beam deflection device for dot and line recording of information on a recording material.

A light source ( 1 ), e.g. B. a laser generator, generates a light beam ( 2 ) which is modulated in intensity in a light modulator ( 3 ) in dependence on line data provided line by line. The light modulator ( 3 ) is, for example, an acousto-optical modulator (AOM). The image data are fed to the light modulator ( 3 ) from a line storage device ( 4 ) via a line ( 5 ). The intensity-modulated light beam ( 2 ') falls on a mirror, for example on a polygon mirror ( 6 ) with a number M mirror surfaces ( 7 ), in the exemplary embodiment with M = 8 mirror surfaces. The axis of rotation ( 8 ) of the polygon mirror ( 6 ) is oriented perpendicular to the plane of the drawing. The polygon mirror ( 6 ) rotates with the help of a motor not shown Darge in the direction of an arrow ( 9 ) at a constant angular velocity about the axis of rotation ( 8 ). A photosensitive recording material ( 11 ), for example a film, is arranged on a recording medium ( 10 ), in the exemplary embodiment a flatbed recording medium. The rotation of the polygon mirror ( 6 ) is reflected by the individual mirror surfaces ( 7 ) and through a lens ( 12 ) on the recording material ( 11 ) focused light beam ( 2 ') continuously in the recording direction, which is indicated by an arrow ( 13 ) is deflected over the recording material ( 11 ). By a gradual or continuous relative movement between the polygon mirror ( 6 ) and the recording medium ( 10 ) perpendicular to the deflection plane of the light beam ( 2 ') in the recording direction ( 13 ) running, adjacent lines are each from a line start ( 14 ) to a line end ( 15 ) on the recording material ( 11 ) be exposed, wherein each mirror surface ( 7 ) of the polygon mirror ( 6 ) is assigned a line and the associated image information of the line.

A in the deflection plane of the light beam ( 2 ') lying pulse generator ( 16 ) generates with each mirror surface ( 7 ) or with each incident light beam ( 2 ') a line start pulse signaling the respective line start ( 14 ) on a line ( 17 ).

Between the light modulator ( 3 ) and the polygon mirror ( 6 ) a controllable optical deflection device ( 18 ) for the light beam ( 2 ') is arranged in the illustrated embodiment, with which the light beam ( 2 ') perpendicular to the deflection plane of the polygon mirror ( 6 ) or perpendicular to the recording direction ( 13 ) or line direction. The deflection device ( 18 ) can, for example, be designed as a pivotable or tiltable lens or as a tilting or deflecting mirror. The deflection device ( 18 ) is controlled via a line ( 19 ) by a random generator ( 20 ) which is triggered by the line start pulses on the line ( 17 ) and generates a random sequence.

The pending random number of the random sequence pending before the recording of a line at the output of the random generator ( 20 ) determines the respective deflection amount for the light beam ( 2 ') transverse to the line direction as a multiple of a line spacing, whereby according to the invention a line is chosen by chance the currently active mirror surface ( 7 ) of the polygon mirror ( 6 ) is recorded. In this way it is prevented that adjacent mirror surfaces ( 7 ) draw adjacent lines. Since the deflection device ( 18 ) is only activated outside of the time intervals in which the light beam ( 2 ') records the line, lower demands are placed on the quality of the deflection means.

The line storage device ( 4 ) provides the image data required for light modulation for the lines selected at random. The line memory device ( 4 ) consists of individual line memories ( 4 a) for line-by-line storage of the image data, a controllable image data input selection ( 4 b) for controlling the sequence when writing the image data and a controllable image data output selection ( 4 c) Control of the sequence when reading the image data.

The line memory device ( 4 ) can, as in the embodiment for example, be designed as a buffer, to which image data is continuously fed line by line via an interface ( 21 ). The line storage device ( 4 ) can also be an entire memory in which the image data for the entire recording are stored line by line and from which they are read in the desired order.

It has proven to be expedient to design the line memory device ( 4 ) in such a way that one of M lines can optionally be drawn with each of the M mirror surfaces ( 7 ) of the polygon mirror ( 6 ). Therefore, the number of lines memory ( 4 a) is selected equal to the number M mirror surfaces ( 7 ).

The line-by-line reading of the image data belonging to the lines currently to be recorded from the buffer device ( 4 ) is also controlled according to the invention by the random generator ( 20 ) in synchronism with the deflection of the light beam ( 2 ') by the deflection device ( 18 ). The random numbers output by the random number generator ( 20 ), each of which selects one of the lines 1 to M for recording, are stored in an output selection memory ( 22 ) and are called via a line ( 23 ) with the aid of the image data output selection ( 4 c) image data belonging to the current lines in the line memories ( 4 a). The image data read out are sent to the light modulator ( 3 ) via the line ( 5 ). The random number of the last selected line is stored in an input selection memory ( 25 ) and controls the line-by-line writing of new image data into the lines read out ( 4 a) via a line ( 26 ) using the image data input selection ( 4 b). This ensures that the image data of a line that has already been processed is replaced by new image data.

It proves to be expedient to use a pseudo random sequence as a random sequence, ie a sequence with a long repetition period of the numerical values. Such pseudo random sequences have the advantage that they can be implemented comparatively easily with the aid of digital computer algorithms. In order to keep the required deflection amounts small and because the image data of one line can only be exposed once, it proves to be expedient to restrict the random sequence with the condition that each of the lines 1 to M is only once during one revolution of the polygon mirror ( 6 ) occurs. In addition, double exposure on the recording material can be avoided using suitable control parameters. This is particularly important if you are not working with a buffer and are being read directly from a main memory.

FIG. 2 shows a development of the recording device according to FIG. 1 with an additional correction device for compensating for pyramidal errors of the mirror surfaces ( 7 ) of the polygon mirror ( 6 ).

To carry out the correction, a correction stage ( 27 ) is provided between the random generator ( 20 ) and the deflection device ( 18 ), in the previously determined pyramidal error correction values for the individual mirror surfaces ( 7 ) of the polygon mirror ( 6 ) in tabular form are filed. The correction stage ( 27 ) is fed via line ( 19 ) the random numbers generated in the random generator ( 20 ), which are a measure of the respective deflection amounts. There is also a mirror surface counter ( 28 ) which assigns a code number to each mirror surface ( 7 ) of the polygon mirror ( 6 ). The mirror area counter ( 28 ) is clocked by the line start pulses of the pulse generator ( 16 ) via the line ( 17 ) and reset by reset pulses on a line ( 29 ) after each revolution of the polygon mirror ( 6 ). To generate the reset pulses, a pulse detector ( 30 ) is present in the area of the polygon mirror ( 6 ), which detects a reference mark ( 31 ) attached to the polygon mirror ( 6 ). The key figures generated in the mirror surface counter ( 28 ) are fed to the correction stage ( 27 ) via a line ( 32 ). With the help of the mirror surface counter ( 28 ), an assignment of the correction values for the error compensation and the respective positioning of the mirror surfaces ( 7 ) is thus established. The corrected deflection amounts obtained in the correction stage ( 27 ) are fed to the deflection device ( 18 ) via a line ( 33 ).

It is within the scope of the invention to arrange the deflection device ( 18 ) between the polygon mirror ( 6 ) and the recording medium ( 10 ), in a departure from the illustration. In addition, it is possible to use the relative displacement between the light beam ( 2 ') and the recording medium ( 18 ) transversely to the recording direction ( 13 ) with the deflection device ( 18 ) shown, but with a mechanical adjusting device for the polygon mirror ( 6 ) or to realize for the record carrier ( 10 ).

The invention has been described using the example of a recording device. However, the invention can also advantageously be used in a scanning device. In this case, the record carrier ( 10 ) is formed as a template carrier, on which a template to be scanned is stretched, and the light source ( 1 ) with light modulator ( 3 ) is replaced by an optoelectronic converter, with which the information recorded in the template is converted into an image signal is implemented.

Claims (18)

1. A method for line-by-line deflection of an optical radiation ( 2 ) over a surface ( 11 ) by means of a rotating mirror ( 6 ) with at least two mirror surfaces ( 7 ), characterized in that the assignment of successive mirror surfaces ( 7 ) of the mirror ( 6 ) and is randomly selected from lines swept by the deflected optical radiation ( 2 ) on the surface ( 11 ). 2. The method according to claim 1, characterized in that that the assignment by means of a pseudo random sequence is selected. 3. The method according to claim 1 or 2, characterized in that the random assignment of mirror surfaces ( 7 ) and lines on the surface ( 11 ) is carried out by a corresponding deflection of the optical radiation ( 2 ) transverse to the line direction. 4. The method according to any one of claims 1 to 3, characterized in that the random assignment of mirror surfaces ( 7 ) and lines on the surface ( 11 ) by a corresponding relative displacement between the mirror ( 6 ) and surface ( 11 ) made transversely to the line direction becomes. 5. The method according to any one of claims 1 to 4, characterized in that each line is swept once during a rotation of the mirror ( 6 ). 6. The method according to any one of claims 1 to 5, characterized in that in the random assignment of mirror surfaces ( 7 ) and lines on the surface ( 11 ) at the same time compensation of the pyramidal errors of the mirror surfaces ( 7 ) by an additional correction deflection of the optical radiation ( 2 ) is carried out. 7. Method for line-by-line deflection of an optical signal ( 2 ) which is brightness-modulated by an image signal via a recording material ( 11 ) by means of a rotating mirror ( 6 ) with at least two mirror surfaces ( 7 ), characterized in that

• - The lines that are recorded by the successive mirror surfaces ( 7 ) deflected optical radiation ( 2 ) on the recording material ( 11 ) are randomly determined and
• - The image signal belonging to the respective line to be recorded is selected from the image signals stored in a line memory device ( 4 ).

8. The method according to claim 7, characterized in that the number of line image signals stored in the line memory device ( 4 ) corresponds to the number of mirror surfaces ( 7 ) of the mirror ( 6 ). 9. Device for line-by-line deflection of an optical radiation ( 2 ) over a surface ( 11 ) by means of a rotating mirror ( 6 ) with at least two mirror surfaces ( 7 ), characterized in that for a random assignment of successive mirror surfaces ( 7 ) of the mirror ( 6 ) and from the lines swept by the deflected optical radiation ( 2 ) on the surface ( 11 ) a random generator ( 20 ) is provided. 10. The device according to claim 9, characterized in that for the random assignment of mirror surfaces ( 7 ) and lines on the surface ( 11 ) arranged in the beam path, controllable deflection device ( 18 ) for corresponding deflection of the optical radiation ( 2 ) is present across the line direction. 11. The device according to claim 10, characterized in that the controllable deflection device ( 18 ) is designed as a pivotable or tiltable lens. 12. The device according to claim 10, characterized in that the controllable deflection device ( 18 ) is designed as a tilting or deflecting mirror. 13. Device according to one of claims 9 to 12, characterized in that for the random assignment of mirror surfaces ( 7 ) and lines on the surface ( 11 ) a controllable, mechanical Stellvor direction for the corresponding relative displacement between the mirror ( 6 ) and surface ( 11 ) is present across the line direction. 14. Device according to one of claims 9 to 13, characterized in that the mirror ( 6 ) is designed as a polygon mirror. 15. Device according to one of claims 9 to 14, characterized in that in the region of the deflection plane of the optical radiation ( 2 ) over the surface ( 11 ) a pulse generator ( 16 ) is provided for generating line start pulses, which with the random generator ( 20 ) is connected. 16. Device according to one of claims 9 to 15, characterized by

• - A correction stage ( 27 ) connected to the deflection device ( 18 ) for correcting the deflection amounts in order to compensate for the pyramidal errors of the mirror surfaces ( 7 ) of the mirror ( 6 ),
• - One with the correction stage ( 27 ) and the pulse generator ( 16 ) connected mirror surface counter ( 28 ) for identifying the mirror surfaces ( 7 ) of the mirror ( 6 ) and
• - A pulse detector ( 30 ) arranged in the region of the mirror ( 6 ) and connected to the mirror surface counter ( 28 ) for generating a pulse per revolution of the mirror ( 6 ).

17. Device for line-by-line deflection of an optical signal ( 2 ) which is brightness-modulated by an image signal via a recording material ( 11 ) by means of a rotating mirror ( 6 ) with at least two mirror surfaces ( 7 ), characterized by

• - A random generator ( 20 ), which determines the lines which are recorded on the recording material ( 11 ) by the lines which are deflected by the successive mirrors ( 7 ) deflected optical radiation ( 2 ) and
• - A line memory device ( 4 ) for line-by-line storage of image signals and for selecting the image signal belonging to the line to be recorded in each case from the stored image signals.

18. The device according to claim 17, characterized in that the line memory device ( 4 ) from lines store ( 4 a) for line-by-line storage of the image signals, a controllable image data input selection ( 4 b) for controlling the sequence when writing the image signals and from a controllable image data output selection ( 4 c) for controlling the sequence when reading the image signals.