DE3116223A1 - Method for image reproduction with variable magnification - Google Patents

Abstract

This method, in which an image information signal for recording an image on an image carrier is converted into an electrical signal by means of a scanning system, is characterised by the fact that a magnification or reduction in image size is carried out at least in the main scanning direction and/or in the secondary scanning direction in accordance with one of the method steps A) or B) below for main scanning direction and, respectively, one of the method steps A) or C) below for secondary scanning direction A) Scanning of an image form or imaging signal with a frequency or a scanning start signal; B) Selective use of a number of image reproduction devices, which are provided in accordance with predetermined variable magnification ratios, by means of a selection device for changing the ratio of change of the recording size; and C) Change of the main scanning period of the image form or imaging signal. In this context, either a change in the relative speed of movement of an optical scanning device with respect to the original image or a change in the speed of movement of a charge carrier element can be selected in addition to the method steps in the secondary scanning direction of the original image.

Description

Procedure for displaying images with

variable magnification Description The invention relates to a method for image reproduction with variable magnification to implement a template or Receipt image information into an electrical signal for the purpose of recording an image on a recording medium and for the purpose of producing an image by means of a scanning system in accordance with the electrical signal.

Various image display devices have been developed including one for electrophotographic processing and recording an imaging signal. This image display device is not just used as an output or output device for either the one (electronic) computer issued information or via a message or connection circuit used transmitted information, rather it can also function as a general electrophotographic copier by they the image of an original using a solid-state image scanner, such as a charge displacement or CCD image scanner, converted into an electrical signal and this signal on processed electrophotographically in a corresponding manner. To enlarge or reduce of the image reproduced from the original image in the previous electrophotographic Copier, a method was used in which a varifocal lens (zoom lens) switched into the beam path or the speed of movement of a mirror or a lens is increased or decreased. However, these measures will the mechanism for moving the optical system is complicated, and these measures are not limited to the aforesaid image reproducing apparatus for processing the original image information applicable in the form of an electrical signal.

The object of the invention is therefore in particular to create a method for image reproduction or reproduction with variable magnification, in which an in an electrical signal converted original image information electrophotographically is processed and recorded.

This object is characterized by what is stated in the attached claims Measures resolved.

In the method of the present invention, the image size becomes in the main scanning direction an original image enlarged or reduced by either an image signal (imaging signal) is sampled according to a clock signal or by means of means for selecting the enlargement ratio selectively a plurality of means for the formation of a latent electronic or charge image, which corresponds to the predetermined possible variable magnification ratios are used while enlarging or reducing the original image in its Subscanning direction either by a scanning method using the clock signal or by a method in which the sampling intervals are changed. In particular when the image signal is generated by means of a solid-state image scanner, such as a CCD image scanner, by photoelectric conversion of the scanning an original generated by means of an optical scanning unit reflected light is, a method can be used in which the relative speed of the optical scanning unit changed for the original in the sub-scanning direction of the original will.

In the following, preferred embodiments of the invention are based on the accompanying drawing explained in more detail. They show: FIG. 1 a schematic representation an image display device for carrying out the method according to the invention, Fig. 2 is a block diagram of a control circuit for a scanning method using a clock signal and to change the intervals (distances) of the clock signal according to an embodiment of the invention, FIGS. 3A to 3D time (control) diagrams to explain an image reproducing method with variable magnification in the main scanning direction using a scan, 4 shows a schematic representation an example of a variable magnification image reproducing method Use of ion modulating electrodes as a means of forming a latent Charge diagram, Fig. 5 is a circuit diagram of a control circuit for the method according to Fig. 4, Fig. 6A to 6E timing diagrams for explaining the image reproduction method with variable magnification in the sub-scanning direction by scanning, Fig. 7 Block diagram of a partially simplified embodiment of the control circuit according to Fig. 2 and Fig. 8A to 8D and Fig. 9A to 9D time (control) diagrams for Explanation of the method according to the invention when carried out with a change in the Clock signal intervals.

In the case of the image reproduction method according to the invention, an optical Fiber tube, an ion modulation electrode, a multi-needle electrode (multi-stylus electrode), a laser beam or the like.

used as a means for image formation, while a photo- resp.

photosensitive material, a dielectric material, or the like.

is used as a medium for the formation of the latent charge image. For example, the following description relates to an image display device, In the case of a charge transfer device (CCD) as a solid-state image scanner (image sensor), an ion modulation electrode as an image forming device, and a dielectric one Material as a medium for forming a latent charge image used will. Fig. 1 schematically illustrates the structure of such a device.

A template M placed on a template carrier 1 made of glass is illuminated by means of an illumination lamp 2, and the reflected light is over transfer a mirror 3 and a lens 4 to a charge transfer device 5, through which the original image is converted into an electrical signal.

This signal is amplified by an amplifier 6 and then one Signal processing circuit 7 fed, which the signal processing for the carries out variable enlargement processes to be described. The one from an electronic Computer output information or from a message or. Connection circuit Information supplied is input to the signal processing circuit 7 directly. That by the signal processing circuit to the variable magnification method subject electrical signal is a driver resp.

Control circuit 8 for an ion modulation electrode 9 is supplied, that consists of a continuous layer of an (electrically) conductive material 9a and a segmented layer of conductive material 9b, between which a Insulating layer is enclosed, consists and arranged in a row through openings 9c is provided. The continuous layer made of the conductive material or Conductor layer 9b is supplied by the driver circuit 8 with an electrical signal charged according to the image information to be recorded, this electrical Signal from multiple control (group control) through the continuous ladder layer 9a is subjected. A control circuit 10 contains a clock signal generator to the Delivery of a clock signal to the charge shifting device 5, to the signal processing circuit 7 and to the driver circuit 8. A corona ion generator 11 is above the ion modulation electrode 9 arranged, under which a rotating drum (cylinder) 12 is provided, the surface of which consists of a dielectric material. Around the drum 12 are a developing device 13, a transfer electrode 14, a separator 15, a charge eliminating electrode 16, a cleaning blade 17 and a fixing device 18, all for normal electrophotographic processing are needed. The flow rate or velocity from the corona ion generator 11 generated ions is set in the openings by the control signal, which the segmented conductor layer 9b of the ion modulation electrode 9 is impressed, so that on the dielectric surface of the drum 12 a latent image of charge is shaped according to the original image information to be recorded. This charge image is developed in the developing device 13 with the aid of a developer and through the transfer electrode 14 onto a sheet of recording or copying paper P transferred. The paper sheet P is then by the separator 15 of the Drum 12 separated, fixed in the fixing device 18 and then out of the Device issued.

To enlarge or reduce the means of the described Image reproduction device generated original image, it is now sufficient to reproduce the image and reproduction both in the main scanning direction (i.e. in the axial direction of the drum 12) of the original image as well as in the sub-scanning direction (i.e. in the direction of rotation of the drum) to control or vary.

The following is the enlargement and reduction of the original image first in the main scanning direction.

The frequency of the imaging signal from the charge transfer device (e.g. CCD 121 H and CCD 142 from Fairchild Co., Ltd.) is denoted by f, while the clock signal to initiate a sampling with XX and the clock signal for the control of a shift register are designated with XT.

Figure 2 illustrates in block diagram form an electrical circuit for image forming or imaging with variable magnification according to the invention. In Fig. 2 is the structure of the signal processing circuit 7 and the control circuit 10 shown in FIG. 1 in detail. The control circuit 10 includes an oscillator 20 for generating clock pulses of frequency f, a frequency divider 21 for dividing the clock pulse frequency to half for the purpose of controlling the shift register of the Solid-state image scanner, a 1 / N counter 22 for generating scan start clock signals and an oscillator 26 for supplying pulses mf (with m = magnification or Reduction ratio), this oscillator being triggerable by the 1 / N counter 22 is. The signal processing circuit 7 is a sampling and Holding circuit with an offset circuit for subtracting the DC voltage level component from the amplified output signal of the charge transfer device, a sampling circuit 24 and an analog / digital converter 25.

1. Scanning method In this method, the imaging signal with frequency f using the sampling pulses of the frequency mf tapped or scanned. The sampling pulses are supplied by the oscillator 26. The imaging signal (e.g. a video signal) of frequency f (see Fig. 3B) is through the offset circuit 23 is supplied and then through the sampling circuit 24 with the Sampling pulses of frequency mf (sampled with m (1) according to FIG. 3C.

After the sample and hold operation, an image form or image signal can be obtained according to Fig. 3D, which is subjected to analog / digital conversion and then passed to the ion modulation electrode 9 via the driver circuit 8 (FIG. 1) will. As a result, the original image is pressed in the main scanning direction.

On the other hand, in the case of in> 1, the original image becomes in the main scanning direction stretched.

In this connection it should be mentioned that the scanning process be synchronized or not synchronized with the sampling start clock signal XX can.

2. Method using multiple ion modulation electrodes In this process, several ion modulation electrodes are used, each correspondingly the relevant enlargement or reduction ratio, provided, wherein a predetermined ion modulation electrode as required for the image formation of a magnification selection signal is selectively used.

For example, referring to Fig. 4, there are three different ion modulation electrodes 9, 9t and 9 ″ provided with different opening or hole spacings. if the hole spacings with 1, 1 'and 1 "(l' <1 <l '') are 1, l '/ l and l' '/ l are chosen so that they correspond to the pitch or hole spacing at Image formation with 1: 1 enlargement, the desired reduction ratio or correspond to the desired enlargement ratio. In this case it is enough it off, the relevant ion modulation electrode 9, 9 '' or 9 'for imaging the Original image, for producing the enlarged image or for producing the reduced one Image to use.

Figure 5 is a block diagram of a control circuit for the three different ion modulation electrodes 9, 9 'and 9 ".

According to Fig. 5, a shift register 30 is provided, which with the image form or image signal is fed. Furthermore are a tangling circuit 31, a switch circuit 32 and a control circuit for a segmented conductor layer intended. A control circuit with a clock signal generator is shown at 10 '. The continuous conductor layers of the ion modulation electrodes 9, 9 'and 9 "are with 9a, 9'a resp.

9''a, while their segmented conductor layers with 9b, 9'b and 9''b, respectively. The control circuit shown is an example for a circuit in which the ion modulation electrodes of a group control subject to or controlled in groups. The segmented conductor layers 9b, 9'b and 9''b, each provided with the same number of through openings are fed with the imaging signal. The original image is represented by a of the ion modulation electrodes 9, 9 'and 9' 'by choosing the continuous conductor layers 9a, 9'a and 9 "a shaped in such a way that the size change ratio by the Eigenvalue of the chosen electrode is determined. That way it can The original image can be enlarged or reduced in the main scanning direction.

In the method described, instead of the ion modulation electrodes template image form elements, e.g. multi-needle electrodes, can also be used, their Recording position is predetermined.

The following is the enlargement and reduction of the original image described in the sub-scanning direction.

1. Scanning Method This method is illustrated in FIG. When the electrical picture information signal (i.e. the video signal) every other Clock signal XX according to FIG. 6A is tapped or tapped with the sampling signal according to FIG. 6B. is scanned, an original image can be generated as shown in FIG. 6B, the size of which is reduced in the sub-scanning direction. Figure 6E illustrates an example of the signal after the scanning process in the event that the scanning method according to the invention with the size reduction in the main scanning direction by means of an optical system is combined. The period of the sampling pulses can be arbitrary by means of the oscillator 26 or changed arbitrarily. In the method according to the invention, however, it is cannot produce an original image enlarged in the sub-scanning direction. The method according to the invention can be carried out by means of the circuit according to FIG the circuit of FIG. 2 is partially modified. In Fig. 7 are parts corresponding to the parts of Fig. 2 with the same reference numerals as previously designated. The scanning start signal for each scanning line is a signal that by tapping or sampling the signal from the 1 / N counter 22 by means of a sampling circuit 27 is obtained. It it should be mentioned that the inventive Procedure performed by combination with a mechanical resizing system can be and can be exemplified by a method in which the Movement speed of an optical scanning system in image reduction accelerated and the clock signal XX is sampled or tapped.

2. Method of changing the intervals of a sampling start clock signal This process is illustrated in FIG. This is an enlarged original image shaped when the pulse interval or the pulse spacing of the clock signal XX (Fig. 8A) is pressed according to FIG. 8C. When the pulse spacing or interval is increased on the other hand, a reduced original image is obtained. The pulse interval of the clock signal XX can be changed at will, e.g. by changing the frequency f of the oscillator 20 is changed in the control circuit according to FIG. Following this procedure can both an enlarged and a reduced original image can be produced.

Another method according to which the interval or the distance of the sampling start clock signal can be changed is shown in FIG. at This method can change the size by changing only the frequency of the Sampling start clock signal XX without changing the frequency f of an original image transmission clock will be realized. In this method, in particular, during a sampling period an original image signal transmission time a and a blanking time b exposed (reserved). When copying with magnification, the interval or distance of the Clock signal XX is shortened according to FIG. 9C. Here, however, the blanking time b is only changed to b 'without changing the transmission time a (see Fig. 9C). These The period of the clock signal XX can be changed by changing the frequency division ratio Reach N of the 1 / N counter 22 according to FIG. The procedure for changing the interval or distance of the sampling start clock signal can incidentally preferably by combination be carried out with the method of mechanical variable magnification.

For example, when copying with the image enlarged, the interval becomes of the start clock signal is decreased, while the speed of the rotatable drum 12 according to Fig. 1 is increased.

3. Method of adjusting the speed of movement of the optical Focusing system When the original image by means of the image reproduction device according to Fig. 1 is to be recorded, a method is used in which the original M is scanned in such a way that either the optical focusing system with the Illumination lamp 2, the mirror 3 and the lens 4 or the original carrier 1 is moved. The speed of movement is used to produce an enlarged original image of the optical scanning system or the document carrier versus the speed slowed down when recording at 1: 1 magnification. As a result, the Number of scanning lines per unit length so enlarged that an image with the desired Magnification can be made. For the delivery of a reduced image on the other hand, the moving speed of the optical Scanning system compared to the speed when recording with a magnification of 1: 1.

4. Procedure for adjusting the speed of movement of an element to generate a charge The combination of the method according to the invention with the method described above under 1. is for the production of an enlarged Image required. In this case, the number of revolutions of the rotatable drum becomes in accordance with Fig. 1 compared to the speed - increased during the copying process with a magnification of 1: 1. To the In contrast, the drum speed is reduced to produce a reduced image.

The enlargement and reduction procedures described above can be summarized as follows. In the following List means A = electrical scanning method; B = method using a number of recording elements such as ion modulation electrodes; C = procedure with a change in the pulse interval or spacing of the clock signal; D = procedure to adjust the speed of movement of the optical scanning system; and E = Procedure for setting the speed of movement of the load carrier.

Main scanning direction sub-scanning direction enlargement reduction Enlargement Reduction A O O X O B O O X X C X X O 0 D X X O 0 E X X o 0 At the Image reproduction methods according to the invention with variable magnification are the above-mentioned enlarging and reducing devices A to E are arbitrary or arbitrarily selectively combined with one another and both in the main and in the subscanning direction used, so that the image produced with vasiabler magnification with any Enlargement or reduction ratio can be shaped. The invention offers the advantages that the enlarged or reduced original image is easy to produce and the memory device can be loaded little because the original image information when combined with the storage device are stored in pressed form can. On the other hand, when the ion modulation electrode is used as an image display device is used, the control of the ion current can be simplified so that can easily produce an original image with variable magnification and high quality.

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Claims (5)

Method for image reproduction with variable magnification Claims A method of reproducing images with variable magnification in which an image information signal for recording an image on an image carrier by means of a scanning system in an electrical signal is converted, characterized in that an enlargement or reducing the image size at least in the main scanning direction and / or in the sub-scanning direction after one of the process steps listed below; A or B for main scanning direction or one of the following process steps A or C for the sub-scanning direction the following is carried out: A) Scanning of an image form or image signal (imaging signal) with a frequency (f) or a sampling start signal; B) selective use of a plurality of image display devices which are correspondingly predetermined variable enlargement ratios are provided by means of a recording size changing ratio selector; and C) changing the main scanning period of the image shape signal. 2. The method according to claim 1, characterized in that in the Generation of the image shape or image signal by photoelectric conversion of the light reflected from an image of an original by means of a solid-state image scanner or the like. in the sub-scanning direction of the original image either (D) a change in the relative Movement speed of an optical scanning unit in relation to the original image or (E) a change in the speed of movement of a charge carrier element is selected in addition to process steps (A) and (C). 3. The method according to claim 1 or 2, characterized in that the Main scanning direction is perpendicular to the direction of movement of the image carrier. 4. The method according to claim 1 or 2, characterized in that the Sub-scanning direction runs in the direction of movement of the image carrier. 5. The method according to any one of the preceding claims, characterized in, that the surface of the image carrier made of a dielectric material is.