DE19545625C1 - Method and device for recording images using electronic image signals - Google Patents

Description

The invention relates to a method and an apparatus for recording Pictures according to the preamble of claims 1 and 9. A corresponding Auf Drawing system is known for example from US 5,028,939-A.

Today, images are increasingly processed using electronic means. Here the pictures can either be generated fully electronically or picture templates optoelectronically scanned and digitized and further processed electronically will. The images are also often electronically ver via networks sends.

The main advantage of these electronically processed images over conventional ones Images on mechanical image carriers are that they can be manipulated practically at will are cash. The digital image signals can in terms of color, density and also be retouched from errors in the underlying images. In all but it is generally desirable to remove the images processed in this way from image processing computers worked on one for the human eye at some point output legible, durable image carrier. The pictures are z. B. on Output on paper or on film. Various technologies are available for this Available, e.g. B. color dot matrix printer, color inkjet printer, thermosublima tion and diffusion printers, laser printers, etc. Among all these technologies the output on photographic material offers very high quality in terms of The extent and saturation of the colors, sharpness, homogeneity of large areas, Drawing in highlights, shadows and with continuous transitions.  

For the output of images on photographic material is e.g. B. the DE 42 11 128 A1 known. In the process described there, the Images with a point, controllable with regard to the transmission of light exposed medium. As a medium there is a liquid crystal arrangement or indicated a light valve tube. Although with the methods described there the output speed of electronic image signals compared to the others, o. g. Procedures as well as versus procedures in which images about a Katho can be exposed on photosensitive material, clearly one higher output speed with comparable technical effort leaves, there is still the task of digitizing images even more quickly on light to be able to expose sensitive material.

From US 5,028,939-A an image recording system is known in which light a light source via mirror surfaces arranged in rows and columns is pointed at a light-sensitive material. The disadvantage of this system is that different gray levels can be achieved is relatively expensive. The individual mirrors can in terms of their exposure time can be set, but this can only be done within one by the mechanical data of the mirror given relatively narrow exposure interval. The fine gray gradation required for exposure in photographic quality is hardly possible.

From US 5,455,602-A is known a mirror arrangement of the above ten type according to the well-known TDI (Time Delay Integration) principle operate. The light required for a given exposure amount becomes thereby by adding up several partial exposures on the recording carrier reached. The above restrictions on the number of However, gray gradations per individual mirror surface apply to such a surface Arrangement also.

US 5,049,901-A also shows a recording system with a micro mirror arrangement that in terms of number of grayscale and so  is narrowly limited in terms of the achievable image quality.

It is therefore an object of the invention to provide a method and a device ben with which images that are in the form of electronic image signals, if possible quickly and in the highest possible quality on light-sensitive material can be spent.

This object is achieved by the method according to claim 1 and by the Vorrich tion solved according to claim 9. Advantageous embodiments of the invention are the subject of the subclaims.

According to the invention, the image signals are used in several rows and columns arranged mirror surfaces alternately from each other a rest position and moved back into this. The mirror surfaces can e.g. B. be independently controllable individual mirrors or independently of each other controllable areas of a larger mirror surface. That from a light source Originating light is alternately on the light-sensitive material for its exposure directed. To achieve the most homogeneous density possible gears is provided, the light originating from the light source between this and the photosensitive material inhomogeneous in a predetermined direction to modify, in particular to weaken. The photosensitive material is preferably of a photographic type, in particular color negative photo paper. The one Cell mirrors are in particular arranged in a row, with the weakening the light is perpendicular to the line direction of the mirror and the light sensitive material is moved perpendicular to the line direction. Every pixel on the light-sensitive material is then successively over the corresponding individual mirror of the respective mirror rows exposed. The in homogeneous attenuation of the light perpendicular to the line direction of the Mirror arrangement allows a very precise adjustment of the total amount of light, that meets the respective pixel on the photographic material. Thereby can produce a lot more grayscale on the light-sensitive material than with homogeneous lighting.  

Either a multicolor light source can be provided, which is Color filters successively differently colored exposures on the photosensitive material or different colored light sources be seen, each with a mirror group with one of the light sources interacts for a multi-colored exposure of the photosensitive material.

The number of mirrors is preferably in a ratio not equal to 1: 1 Number of pixels of the image signals. If the number of mirrors is larger than that Number of pixels, several can be used with the signals of one pixel Mirror can be controlled. If the number of mirrors is smaller than the pixel number, a fil can be activated by suitable control of the individual mirrors Interaction can be achieved on the recorded image.

For the output of colored pictures it proves to be useful for one of each three basic colors each a mirror arrangement and / or a gradation provision of funds.  

Details of the invention emerge from the following description, which is supplemented by figures.

Show it:

Fig. 1, an image output device,

Fig. 2 shows a second embodiment of an image output device,

Fig. 3 shows a third embodiment of an image output device and

Fig. 4 shows a controllable mirror arrangement.

In Fig. 1 an electronic printer 1 is shown, in which directed the light from a white light source 2 through a color filter array 3, a mirror assembly 4, and a lens 7 on photosensitive material 8. The exposure takes place serially in the three basic colors red, yellow and green. For this purpose, the filter arrangement 3 consists of three color segments R, G, B, which are assigned to these three primary colors. For this purpose, the filter arrangement 3 is designed as a filter wheel which can be rotated in a direction C. A filter drive 19 , which is connected to control electronics 5 , ensures the rotation.

The electronic printer 1 receives image signals from a data interface 6 . These are temporarily stored in the control electronics 5 and used to control the drive 19 on the one hand and on the other hand to control the Spiegelan arrangement 4 .

The mirror arrangement 4 consists of a plurality of individually controllable mirrors. Each mirror can be moved back and forth between at least two stable states. The image signals of a pixel are used to move at least one mirror 4, preferably several. This allows the amount of light to be controlled which falls point by point from the light source 2 onto the photographic material 8 . Depending on how long an individual mirror directs the light from the light source 2 onto the photographic material 8 , this is more or less blackened.

For example, a so-called digital is suitable for the mirror arrangement Mirror device (DMD). By controlling many individual mirrors at the same time the DMD's, a parallel exposure of many pixels is possible. The separation the light control in the DMD and in the light source, the light source can Exposure requirements, d. H. the exposure corresponding to the image signals amount optimally, specially adapted for high performance. Such a total DMD is e.g. For example, described in U.S. Patent 5,206,629. Instead of individual mirrors it is also possible to move so-called elastomer-spatial-light Modulators (SLM) or membrane SLM’s to use. With such modules gates will not toggle individual mirrors between rest and activation positions switched, but individual areas of a larger mirror top individually controlled and deformed surface. Details of such modulators are for example in the article "Deformable-Mirror Spatial Light Modulators" by Larry J. Hornbeck, Proc. of SPIE, Vol. 1150-06, pages 1-17, 6-11. August 1989.

The electronic, digital image signals are converted in the control electronics 5 into control signals for the individual mirrors of the DMD 4 . The exposure time of the individual pixels on the photographic material 8 is controlled by the individual signals of the DMD 4 by the image signals.

The photographic material 8 can e.g. B. film or photo paper positive or negative type. Depending on the type of image signals - positive or negative - the control electronics 5 can invert the image signals in such a way that the image recorded on the photographic material 8 is positive after having undergone a photographic development process. Details of the electronic image in version are e.g. B. described in DE 35 25 807 C1.

Fig. 2 shows an electronic printer similar to Fig. 1. Behind the light source 2 , a condenser 9 is connected in the beam path of this printer, which homogenizes the light coming from the light source 2 . In the further course of the beam path, a gradient filter 10 is further arranged after the color filter 3 . It ensures that the mirror arrangement 4 , which contains a surface 15 with individual mirrors 11 arranged in a matrix, is illuminated inhomogeneously along the direction B of the columns.

The light-sensitive material 8 is transported here in the direction B with drive means, which comprise a transport roller 16 and a motor 17 . As a result, each point on the light-sensitive material 8 can be exposed several times by different individual mirrors 11 , which are arranged on the DMD 4 along a column. The control of the individual mirrors 11 is in each case so that the electronic image information is moved to a pixel during said relative movement between the DMD 4 and the light-sensitive material 8 along the column direction B such that the image information of the individual mirrors 11 of a column one after the other on the same Point of the photosensitive material 8 is exposed. This exposure takes place one after the other in the individual color separations. When a desired exposure on the light-sensitive material 8 is reached, the mirrors 11 of the DMD 4 are no longer activated for this pixel. The contribution of the individual lines of the DMD to the exposure of the photographic material 8 can be controlled by controlling the line activation time. In the present embodiment, exposure is also influenced by the inhomogeneous lighting perpendicular to the line direction. However, the lighting is homogeneous within one line, ie in direction A. With such an arrangement, an exposure characteristic can be achieved which is linear to the density of the photographic material 8 .

FIG. 3 shows an electronic printer of essentially the same type as in FIG. 1, in which the light from the light source 2 is transmitted via light guides 12 . The exposure time for each pixel is controlled here by line-shaped DMDs 14 . A gray filter 10 is provided for each DMD line 14 , which in conjunction with a homogenizer 13 within line 14 ensures uniformly intense light. A pair of gray filters 10 and a homogenizer 13 are provided for each image line. This causes a gradual filtering in the direction B perpendicular to the line direction A. By appropriate selection of the appropriate gray filter, practically any total exposure amounts can be generated for each pixel when the recording material is moved. The gray filters can each be interchangeable or visually controllable with regard to their gray gradation. For example, the gray filter can be designed as a controllable liquid crystal (LCD). The individual mirrors of the DMD lines 14 are controlled via the control line 18 of the corresponding DMD line using a multiplex method. The light-sensitive material 8 can be photographic material or any other light-sensitive material, such as. B. be a selenium drum of an electrophotographic process.

In Fig. 4, a controllable mirror arrangement is shown, which has a large mirror surface 4 . Within the mirror surface 4 , individual mirror surface regions 20 (eg 1000 × 2000 dots) can each be controlled independently of one another in such a way that the mirror surface 4 deforms in the respective region. The deformation is possible because behind the very thin mirror surface 4 there is a soft material 21 , e.g. B. silicone gel, against which the Spiegelflä surface 4 can deform in certain areas. The deformation is caused by a semiconductor solid body 22 , which can be controlled at certain points in such a way that an electrical field is formed in some areas, through which the metallic mirror surface is deformed. Details on the functioning of such an element can be found, for. B. in the article "Amplitude-controlled diffraction grating for large-screen projection". The control of the mirror surface areas 20 accordingly the image signals via a data line 23 , preferably in a multiplexing process. Such a mirror arrangement can be used in place of or in conjunction with the DMD mirror arrangement 4 shown in FIGS . 1 to 3.

Exemplary embodiments of the invention have been described. It is clear that within the scope of the professional ability without further modifications of the Invention or additions to the invention can be specified. For example, NEN details on electronic signal processing, especially the elec tronic image signal reversal can be carried out according to known methods. On such a method is e.g. B. in DE 35 25 807.

Claims (13)

1. A method for the point-by-point output of images by means of electronic image signals on a light-sensitive material ( 8 ), wherein

• a) the material ( 8 ) by means of a light source ( 2 ) and rows and columns arranged mirrors ( 11 ) is exposed, which are moved in accordance with the image signals such that a number of mirrors corresponding to the signal size ( 11 ) in the exposure position is brought
• b) the movement of a plurality of mirrors ( 11 ) which follow one another in the column direction (B) is controlled with the information of an image signal point,
• c) the material ( 8 ) is moved during the exposure relative to the mirrors ( 11 ) perpendicular to the row direction (A) along the column direction (B) and
• d) the proportion of the individual mirrors ( 11 ) in the total exposure along the column direction (B) is varied depending on the total exposure amount, characterized in that
• e) the light between the light source ( 2 ) and the light-sensitive material ( 8 ) with grading means ( 10, 13 ) perpendicular to the line direction (A) modified inhomogeneously according to a predetermined characteristic, in particular is weakened.

2. The method according to claim 1, characterized in that photographic or electrophotographic material ( 8 ) is used as the light-sensitive material. 3. The method according to claim 1 or 2, characterized in that the mirror surfaces ( 11 , 20 ) are each grouped together to form a mirror row ( 14 ) or a mirror surface ( 15 ). 4. The method according to claim 1, 2 or 3, characterized in that a plurality of differently colored light sources ( 2 ) are provided and in that a mirror group ( 14 ) each with a light source ( 2 ) interacts for a colored exposure of the photographic material. 5. The method according to any one of claims 1 to 4, characterized in that a multicolored light source ( 2 ) is provided for recording colored images, that the light source ( 2 ) or an arranged between this and the photographic material filter arrangement ( 3 ) one after the other between the different colors are switched and that the mirror surfaces ( 11 , 20 ) are each controlled in accordance with the color information of the image signals. 6. The method according to any one of the preceding claims, characterized in that the number of mirror surfaces ( 11 , 20 ) is in a ratio not equal to 1: 1 to the number of pixels. 7. The method according to claim 6, characterized in that the mirror number is smaller than the number of pixels. 8. The method according to claim 6, characterized in that the mirror number is greater than the number of pixels.   9. Device for recording images by means of electronic image signals on a light-sensitive material ( 8 ), wherein

• a) the material ( 8 ) by means of a light source ( 2 ) and rows and columns arranged mirrors ( 11 ) is exposed, which are movable in accordance with the image signals and which are moved in accordance with the image signals such that a number of mirrors corresponding to the signal size ( 11 ) is brought into the exposure position,
• b) the movement of a plurality of mirrors ( 11 ) which follow one another in the column direction (B) is controlled with the information of an image signal point,
• c) the light-sensitive material ( 8 ) is moved during the exposure relative to the mirrors ( 11 ) perpendicular to the row direction (A) along the column direction (B),
• d) the proportion of the individual mirrors ( 11 ) in the total exposure along a column direction (B) to one another is varied depending on the total exposure amount, characterized in that
• e) grading means ( 10 , 13 ) are provided which inhomogeneously modify, in particular weaken, the light between the light source ( 2 ) and the light-sensitive material ( 8 , 18 ) perpendicular to the line direction (A) of the mirrors ( 11 ).

10. The device according to claim 9, characterized in that the grading means ( 10 , 13 ) between the light source ( 2 ) and the mirrors ( 11 ) are arranged. 11. The device according to claim 9 or 10, characterized in that the grading means ( 10 , 13 ) comprise a graduated or step filter. 12. Device according to one of claims 9 to 11, characterized in that a mirror arrangement ( 4 ) and a grading means ( 10 , 13 ) is provided for the output of colored images for three primary colors (R, G, B). 13. Device according to one of claims 9 to 12, characterized in that the light-sensitive material ( 8 ) is color negative photo paper.