DE19741359A1 - Multiple image scanner - Google Patents

Description

The present invention relates generally to the Ge offers optical scanning devices or optical scanning ner and in particular to a method and a system for Obtain multiple images from a single scan. Ins In particular, the present invention provides a device for obtaining color image data and black and white image data from a single scan.

Optical scanners are used to take pictures capture and digitize. The digital image can then electronically stored and / or with a character recognition processing software to generate ASCII text who the. Use most optical scanners lighting and optical systems to move the object glow, and around a small area of the illuminated ob object, commonly referred to as a "scan line", to focus on the optical photosensor array. The Ge velvet object is then moved by moving the illuminated scan line across the entire object, either by Moving the object in terms of lighting and opti arrangements or by moving the lighting and the optical arrangements relative to the object.

A typical optical scanner system becomes one Lens assembly include to image the illuminated Ab scanning line on the surface of the optical photosensor array to focus. Depending on the specific design, this can optical scanner system further a plurality of Include mirrors to "fold" the path of the light beam, which enables the optical system to take advantage is attached within a relatively small envelope.

Although different types of photosensor devices in  optical scanning devices can be used a commonly used sensor is the charge-coupled construction element or CCD (= Charge Coupled Device) How it works well is known, a CCD can handle a large number of individual Have cells or "pixels", each of which has an elec accumulates charge in response to light exposure or builds up. Because the size of the enriched electrical Charge in any given cell or pixel on the Intensity or duration of the light exposure can be related A CCD can be used to spot light and dark spots an image that is focused on the CCD. At a typical scanner application, the charge, that has built up in each of the CCD cells or pixels at regular intervals, called exposure times or Sampling intervals are known, and that is about 5 milliseconds or similar for a typical scanner NEN, measured and unloaded. Since the charges (i.e. image da ten) simultaneously in the CCD cells during the exposure time, the CCD also includes an analog one Shift registers to the simultaneous or parallel data from the CCD cells to a sequential or serial Convert data stream.

A typical analog shift register has a plurality of "charge transfer buckets", each with a single cell is connected. At the end of the exposure time are the charges that are collected by each CCD cell which, simultaneously transferred to the charge transfer buckets, with which the CCD cells for the next exposure sequence be prepared. The load in each bucket is then from Bucket to bucket out of the shift register in one se quantitative or "bucket chain" type transferred while At this time, the CCD cells are scanned with the next line exposed. The sequentially arranged charges of The CCD cells can then be inserted one by one into a di gital signal by a suitable Analog-to-digital converter can be converted.  

For most optical scanner applications arrange each of the individual pixels end-to-end in the CCD net, which creates a linear array. Every pixel in the CCD array therefore corresponds to an associated pixel ab cut the illuminated scan line. The individual pixels in the linear photosensor array are commonly used in the "Lateral" direction aligned, i.e. H. perpendicular to the rich movement of the illuminated scan line and across the object (also known as the "scan direction"). Each The pixel of the linear photosensor array therefore has one Length, measured in the transverse direction, and a width, measured sen in the scanning direction. With most CCD arrays the length and width of the pixels are the same, more typical about 8 µm or similar in every dimension.

The cross direction scan rate is a function of the number of the individual cells in the CCD. For example, contains a commonly used CCD photosensor array is sufficient Number of individual cells or pixels at a sampling rate in the transverse direction of about 600 pixels or dots per Inches (600 ppi = 236.22 dots per cm (ppcm); ppi = points per inch) to enable the sampling here as native rate in the cross direction.

The scan rate in the scan direction is reversed to that Product of scan line scan rate and CCD exposure time (i.e. the sampling interval). Therefore the sampling rate in the scanning direction by decreasing the Scan line scan rate, CCD exposure time or at to be increased. Conversely, the sampling rate in the Ab scanning direction by increasing the scan line scan rate, the CCD exposure time or both. The "minimum scan rate in the scan direction" for a counter The exposure time is the sampling rate that is achieved if at the maximum scan line scan rate at this Exposure time is scanned. For example, one maximum scanning line scan rate of about 8.4582 cm (= 3.33 inches) per second and a maximum exposure time of  about 5 milliseconds to a minimum sampling rate in the Scanning direction of approximately 60 ppi (= 23.62 ppcm).

Optical character recognition (OCR; OCR = Optical Character Recognition) 300 ppi (= 118.11 ppcm) From key rates for exact results. So a 300 ppi is 4 Bit gray scanning (8.5 x 11 inches = 21.59 x 27.94 cm) what a high resolution and a shallow bit depth is about 4.2 Megabyte. Color fastness requires 24 bit color groping. Hence, a 150 ppi is 24 bit color sampling (21.59 × 27.94 cm), which is a low resolution and a is high bit depth, about 6.3 megabytes. To scan one egg to deliver a document that contains both color images or drawings which contains an OCR, and what is written, the sampling would have to be about 300 ppi at 24 bits (21.59 × 27.94 cm), which corresponds to approximately 25.24 megabytes of memory. The accordingly, scanning a document requires that includes both text and images, quite a memory amount. So far, the software on a computer is that Scan the color image down to about 6.3 megabytes, and that Throw away color image to get text. This process is extremely slow to do it with software, and it consumes a large amount of memory unnecessarily. Another alternative is either the text or to sample the graphics first, and then a sample performance of the other. Then the document could be reproduced by software. However, this is alongside it also takes a very long time to use as much memory complex process of scanning the document.

The object of the present invention is a Scanner and a method to create it he possible, a document that contains both text and graphics has to be sampled, significantly the total amount of Data read from the scan direction to the host computer det is reduced (which is currently a speed restriction) and the total amount of data ge stores and processed by the host computer software  is reduced.

This task is accomplished by a method for generating Multiple reproductions of an image of a scanner according to claim 1, by a scanning device according to An saying 5 and by a method for generating multiple reproduced a bit solved according to claim 9.

The above and other aspects of the present invention are achieved by a multi-image scanner, which performs a single scan of a document that multiple types of images (e.g. text and graphics) holds, and the multiple reproductions of the same document by the scanner to the host computer (e.g. a gray High resolution step image and low color image resolution and high bit depth), which is consequently strong the total amount of data reduced to the host computer is sent and processed by the same, e.g. B. from et wa 25.24 megabytes to about 10.5 megabytes (a 300 ppi 4 bit Gray image [21.59 × 27.94 cm], that is 4.2 megabytes, and one 150 ppi 24 bit color image [21.59 × 27.94 cm], that's 6.3 Megabytes), which is a 2.4 to 1 reduction.

The scanner of the present invention sends the Multiple images are nested on a line basis to that Host computer, e.g. B. with two lines of high gray data Resolution and then a line of lower color data Resolution if the resolution ratio between the bil who is two. The advantage of the present invention be is that the host software spends less information must work and store, and that less information must be sent from the scanner to the host sen, which is a current limitation of the scanning device speed is.

The present invention also features host computer software on that the data stream of nested images in one can dissolve individual images, which are then used for manipulation  and further processing by the host computer are.

The present invention can provide a method of making multiple reproductions of an image with one scan have direction, the method the following Steps comprises: performing a single scan of the Image with the scanner; and generated by the Scanner of more than one reproduction of the image, obtained by scanning the image individually. Of the Step of generating more than one rendering of the Image obtained from a single scan of the image , the step of generating at least a grayscale image and at least one color image sen, which further includes the step of generating at least a grayscale image with high resolution and at least a color image with low resolution and high bit depth having. Once the scanner more than one again the single scan image is generated, the scan can direction more than a reproduction of the image from the Single scan of the image was obtained to the hostcom Send computer for further processing.

The present invention also includes a scanner with the following features: an image processor Unit for generating more than one reproduction of a Image of a single scan, the image processing unit can have a prescaler or prescaler, whereby the prescaler a single scan image in more than one how dividing the output of the single-scan image. The advantage can further convert the single-scan image into at least one mo reproduction of the single-scan image and at least split a color reproduction of the single-scan image. Furthermore, the prescaler can use the single scan image in mind least a high-resolution grayscale image and a color Split image with low resolution and high bit depth.

Preferred embodiments of the present invention are described below with reference to the accompanying Drawings explained in more detail. Show it:

Fig. 1 is a block diagram of the data path for a multi-state image sensing device according to the present invention;

Fig. 2 is a more detailed block diagram of the data path of the image preprocessor for a multiple image scanner in accordance with the present invention;

Fig. 3 is a more detailed block diagram of the data path of the Bildnachprozessors for Mehrfachbildabtastvor device according to the present invention;

Fig. 4 is a more detailed block diagram of the data path from the multi-image scanner to the host computer according to the present invention; and

Fig. 5 is a flowchart of a method of dissolving egg nes data stream that more than one record ent of the present invention maintains invention.

The present invention provides a scanning device two sets of sample data simultaneously from a single ab can get groping. Although the region of the scan is the same, the data types and resolutions of the two Views vary. For example, if an Abta an image is processed, an image processing unit in the scanning device with a grayscale image high resolution and a 24-bit color image with low resolution solution of the document being scanned, and then both renditions of the scanned document to a host send computers nested in a data stream that the The host computer then resolves to the two views of the remote to reproduce the keyed document.  

Fig. 1 shows a block diagram of the data path for a double image scanner, the area of the dashed line 102 being the host computer functions. It should be noted that although the embodiment described herein is a double image scanner having a black and white and a color image, the concepts are expandable to multiple images. An image processing unit 100 is implemented in an ASIC (Application Specific Circuit) with functional details, which are described below with reference to FIGS. 2 and 3. When a document is scanned, a CCD array 104 or other known photosensor device outputs a red data signal 106 , a blue data signal 108 and a green data signal 110 . These three data signals are then converted into a color image data signal 128 and a monochrome image data signal 130 by an image preprocessor 112 . The image pre-processor 112 places the color image data signal 128 in a Farbpuf ferabschnitt 118 of a buffer 114 and the Monochrombildda tensignal 130 in a monochrome buffer section 116 of the Puf fers 114th

Next, an image postprocessor 120 uses the image data in color buffer 118 and monochrome buffer 116 to produce either one or two views of the window that was scanned by the scanner as specified by the host computer. If two views are created, the image postprocessor will send the two views to the host computer in a nested data stream 136 .

When the host computer receives the two views of the scan window, a data resolver 122 will resolve the data stream 136 into a color image 124 and a monochrome image 126 . The two views are then ready to be manipulated by the host computer. The advantages are that less information has to be processed and stored by the host software and that less information has to be sent from the scanning device to the host, which is a current limitation of the speed of scanning devices.

I. Multi-image scanner

The double image scanner reduces the required Data from the scanner to the host computer for full page (text and graphics / image) information are to be sent with one scan. Currently the Optical character recognition 300 ppi sampling rates for exact re results. For a color fastness is a 24-bit color sample required. To do this, the typical Abta 300 ppi at 24 bits (21.59 × 27.94 cm), which is 25.24 mega byte is. The scanner is left two reproductions send the same pages, a high-definition grayscale image and a low resolution 24-bit color image, so the Ge total amount of data sent to the host software, and processed by it, greatly reduced. A 300 ppi 4-bit grayscale image (21.59 × 27.94 cm) is approximately 4.2 Megabytes and a 150 ppi 24-bit color image (21.59 × 27.94 cm) is about 6.3 megabytes, which is a total of 10.5 me gabyte, and about a 2.4 to 1 reduction in terms of Data is.

The multi-image scanning of the present invention has an image processing unit that performs the above-mentioned operations very quickly. The image processing unit can be implemented in a conventional field programmable gate arrangement or a gate array, an ASIC or the like using Verilog, e.g. B. with the functional description provided herein. The image processing unit of the multi-image scanning device comprises the image preprocessor 112 , the buffer 116 and the image postprocessor 120 , which are described in more detail below.

A. Image preprocessor

Referring to Fig. 2 takes the image pre-processor 112, the RGB (red 106, green 108 and blue 110) image data from the CCD 104, and the same placing either one or two under schiedliche representations of this image into the buffer 114. One of the possible representations is a color image and the other is a monochrome image that is created by selecting only one of the three color channels (red, green or blue). The two different buffer images have the same Y resolution, but they can have different X resolutions and bit depths. The bit depth of each image can be either 12 bit or 8 bit, and the X resolution can be the CCD resolution divided by any integer factor from 1 to 63. The CCD resolution is the same for both images, and the same can be either 300 ppi or 150 ppi. For example, the image preprocessor 112 can be programmed to hold the 300 ppi (×) by 300 ppi (y) 8-bit monochrome (green channel) data and the 100 ppi (×) by 300 ppi (y) 12-bit - Put color data in the buffer. It should be noted that both images need not be created. The preprocessor can be programmed to produce only the color representation or only the monochrome representation or both.

The four main functions performed by the image preprocessor of the present invention are described in more detail below and with reference to FIGS. 1 and 2.

1. A / D converter

The A / D converter takes the 300 ppi or 150 ppi analog RGB image data from the CCD array and either converts one of the three or all three color values for each pixel in 10-bit digital numbers around. These digital values are set to 12 bits  padded and sent to a dark bracket.

2. Dark bracket

The dark bracket draws the average dark current for the line from each pixel value. Pixels within the desired scan window then become a compensator cleverly.

3. Compensator

The compensator removes pixel variations caused by a inconsistent lighting and inconsistent CCD reaction can be effected. Be compensated for pixel values then sent to the prescaler.

4. Advantage

The prescaler divides the compensated pixel values into one mo nochrombild and a color image, the same reduces the X-Auf each picture is solved by a different integer factor, and it represents one or both of the results tive images in the buffer. The prescaler shares that Image data from the compensator into a monochrome stream and a color stream, the same reduces the X resolution of each Current by a different integer factor, and it stores one or both of the resulting ones Currents in the buffer. This is done to the amount minimize the buffer space created by each line of Image data is consumed, especially if two views be requested by the host. For example, if no prescaler is provided and the host one 300 ppi monochrome view and a 100 ppi color view of one 21.59 cm (= 8.5 inch) wide scan window requests, each Line of the picture consume 11.475 Kbytes of buffer space  (21.59 cm 300 ppi 3 colors / pixel, 1.5 bytes / color). With the Each line only consumes 6.375 Kbytes (21.59 cm 300 ppi 1 color / pixel + 21.59 cm 100 ppi 3 color ben / pixel 1.5 bytes / color).

It should be noted that the prescaler is either full 12-bit or can put truncated 8-bit data in the buffer. The data width can speci independently for each data stream be infected. The prescaler reduces the x-resolution of the two data streams by averaging adjacent pixels and not just dropping pixels. This effectively low-pass filters the image data before it the lower resolution, and this helps To reduce image imperfections or aliasing. The before The x-resolution can be divided by any integer factor reduce between 1 and 63.

B. Image postprocessor

The image postprocessor uses the images in the buffer to either one or two views of the scan window that is specified by the host. Any view is either from the color image or the monochrome image testifies. The two views can be the same or un different images are generated. For example could be a view from the color image and the other view generated from the monochrome image, OR both views could be generated from the color image, OR both on views could be generated from the monochrome image. The two views can have different y-resolution sen, the y-resolution of each view must be the Buffer y resolution divided by an integer factor of 1 be to 16. The two views can also differ Liche x-resolutions that each resolution of 1/4 can be up to 2 × the x resolution of the buffer image from which the view is generated. Each view can also be viewed under different matrixes, sound images, data types, etc. (with  some restrictions, which are detailed below be covered).

When two views are released, the views are broadcast interleaved on a row basis depending on the ratio of their y resolutions. For example, if the y-resolution of the first view is 300 and the y-resolution of the second view is 150, then the data alternates with two lines of the image data of the first view and then one line of the image data of the second view (except at the beginning) from. Other examples of nested data as a ratio of y resolution are:
(2 to 1 ratio) → output 300 to 150 ratio:
300, 150, 300, 300, 150, 300, 300, 150,. . .
(1 to 2 ratio) → Issue 150 to 300 ratio:
150, 300, 300, 150, 300, 300, 150, 300,. . .
(3 to 1 ratio) → output 300 to 100 ratio:
300, 300, 100, 300, 300, 300, 100, 300, 300, 300,. . .
(1 to 3 ratio) → output 100 to 300 ratio:
300, 100, 300, 300, 300, 100, 300, 300, 300, 100,. . .
(4 to 1 ratio) → output 300 to 75 ratio:
300, 300, 75, 300, 300, 300, 300, 75, 300, 300,. . .
(1 to 4 ratio) → Edition 75 to 300 ratio:
300, 75, 300, 300, 300, 300, 75, 300, 300, 300,. . .
(5 to 1 ratio) → output 300 to 60 ratio:
300, 300, 300, 60, 300, 300, 300, 300, 300, 60,. . .
(1 to 5 ratio) → Edition 60 to 300 ratio:
300, 300, 60, 300, 300, 300, 300, 300, 60, 300,. . .

It should be noted that the previous examples are only are exemplary; other possible conditions of the current All implementations go from 1 to 9.

The six main operations performed by the image postprocessor of the present invention are detailed below and described with reference to FIGS. 1 and 3.

1. Line mixer

The line mixer reads 1 to 9 lines from the appropriate one Image (color or black and white), with the same optional a few lines together before the resulting Rows are sent to a matrixer. The line mixer essentially nests the two or more how editions of the scanned image into a single ver nested data stream that is sent to the host computer shall be. By nesting the two or more Renderings of the scanned image on a line-by-line basis the scanner does not have to do everything everyone Save playback, as well as all playback generated, ver nest and sent to the host computer in real time become - d. H. on a line-by-line basis.

The line mixer reads 1 to 9 lines of data from either that of the color image or the black and white image and averages some lines together to reduce the number of calculations adorn, which must be carried out by the matrixer. In addition, the line mixer can be a simple form of y resolution advantage by averaging additional be Provide adjacent lines. For example, the lines mixer read nine lines from the buffer, three each Average the adjacent lines by the effective y-resolution reduce a factor of 3, the two remaining Average outer lines for core symmetry and then the send the resulting two lines to the matrixer. Therefore  the line mixer the number of lines that are measured by the Ma trixer must be processed, reduced from 9 to 2.

Any integer number of adjacent rows from 1 to N (where N is the number of rows coming from the buffer be read - up to 9 lines) can be averaged together the. However, after averaging adjacent lines, the resulting number of rows 1, 3, 5, 7 or 9, such that symmetrical lines can be averaged further before they are passed on to the matrixer. This means that if no adjacent rows are averaged , you can use either 1, 3, 5, 7 or 9 row cores can. However, if two or three adjacent lines with can only be one or three line cores use. If four to nine adjacent rows are averaged you can only use one line core.

The lines are created by adding the appropriate pixels each line and divide by a division factor of 1, 2, 4 or 8 averaged. Therefore, an exact averaging only received when 1, 2, 4 or 8 rows are averaged the. The line mixer will overflow if the number of Lines that have been put together divided by the part is greater than 2. Therefore, if a 3, 5, 6, 7 or 9 row averages is desired, the next lower gere division factor are used, and the Matrixerkoef efficiencies should be reduced to include the additional "Ver strengthening "introduced by the line mixer compensate. The only exception to this rule is therein when 9 lines are read from the buffer, and each because three adjacent lines are averaged, and then one Three-line handle is used. In this case, the Line mixer finally 9 lines by 2. One of these two Rows (the one that corresponds to the center of the core) by adding the three center lines from the buffer hold. The other line is added by adding the outer 6 Received rows from the buffer. However, it can only be a Divisor must be selected, and it must be the same  be chosen that no line coming from the line mixer comes out multiplied by more than 2. Therefore in this example a divisor of 4 can be selected. There the gain of the line mixer is now 3/4, the Matrix coefficients may be increased to compensate.

The buffer image to be used (colored or mono chrome), the number of lines read from this image the number of adjacent averaged rows and the division factor can be independent for each view that to be generated.

2. Matrixer

The matrixer "mixes" the three colors of each pixel by one generate single color or three new colors before the Lines are forwarded to a sound image.

3. Sound images

The sound mapper or tone mapper uses lookup tables and an interpolation to the image contrast and intensity before sending the data to a formatter. The output pixels are further trans through the sound images that sends them through a reference table, which contains a transfer curve called tone mapping becomes. Sound mappings are used to correct a gamma to perform contrast and intensity to increase shadows, etc.

4. Formatter

The formatter optionally creates a threshold value or rasterizing the data before packing it into one  specified data width by. This level can also Data, if desired, before sending it to one Invert compression device.

5. Compression device

The compression device optionally uses the pack bits algorithm to line the image data before sending compress it to the host.

11. Multiple views from one scan window

The multiple image scanner of the present invention has the ability to take two pictures from a single Ab to get groping. The scanner command languages (SCL-; SCL = Scanner Command Language) Implementation of Multiple images separate the concept of the scan window from the special view of this window. The SCL is the Be false language used for scanning devices and is well known. It should be noted that every command language can be used. With the preferred off The SCL is used to provide multiple views to generate a scan window. The scan window is the physical area of the page being scanned (de defined by the x and y position and the dimensions). The view of this scan window is the data that is inside half of the physical area (defined by the resolution, the data type, the mirror, the inverse, etc.) are. There are scanner settings, the window and view independent (i.e., ADF is attached, serial number mer etc.) are. The advantage of separating the view and the Window is that the same is the definition of Multiple views on multiple windows with multiple views expandable. No other scanning device points Multiple image skills or an implementation of more technical views on. It should be noted that, although at the front  lying invention of multiple views a single scan stung is used to view multiple views of the same To get document, it is irrelevant whether one or Multiple scans can be used to create multiple views to get the same document. It does not matter, how to get the data (from one or more samples) The important point is that the SCL implement mentation of more than one view of different data allows to represent the same space.

In a preferred embodiment, the Hewlett-Packard ScanJet 5p is used to enable two views of data to be captured simultaneously. It should be noted, however, that any color scanner could be modified by any manufacturer to implement the present invention. While the region of the scan is the same, the data types and resolutions of the two views can vary. The limits of the two variable sets of the two views are described with the SetViewType macro in SCL as follows:
INT16 DualScan (INT16 phase,
PUINT8 PBufferView0,
INT32 LengthView0,
PINT32 pReceivedView0,
PUINT8 PBufferView1,
INT32 LengthView1,
PINT32 PReceivedView1).

The parameters are set as shown below:
Phase flag that indicates whether this is the first transfer in a sequence. Must be one of the following:
SL_FTRST or SL_SCAN, the first buffer in the transfer,
SL_ADF_SCAN, the first buffer in an ADF transfer (currently only supported by HP1750A and HP5110A),
SL_NEXT, each additional buffer transfer;
PbufferView0 - pointer to the view 0 data buffer to receive the data;
LengthView0 - size of the view 0 data buffer in bytes;
pReceivedView0 - pointer to the actual number of bytes received from the scan direction for view 0;
PBufferView1 - pointer to view 1 data buffer to receive the data;
LengthView1 - size of the view 1 buffer in bytes;
pReceivedView1 - Pointer to the actual number of bytes received by the view 1 scanner.

This function is almost identical to the Scan () function, that is well known to those who are familiar with SCL, except that it is the dual view mode of the Scanner supported.

Some of the default settings for the two views of one Scans are shown in Table 1 below.

Table 1

In the table above, "*" shows that the parameter is not is set independently for the two views. This could, however, be modified to allow some or all of these parameters are independent for these two Views can be set. Furthermore, these reflect Implementation of parameter settings and SCL commands which is used by the inventors and the same are not meant to be the only possible combination of parameters Settings or SCL commands are multiple views of a single scanning concept of the present invention enable.

The following commands have been added to select the number of views to be sent to the host computer by the scanner:
Command: Select number of views
Escape sequence: Esc * f # A
Query ID: 10466
Range: 1-2
Default: 1
Macro: SetNumberofViews (x)
Send command SendCommand (SL_NUM_OF_VIEWS, x)
x can be either 1 or 2.

This command will choose how many views of the fen sters are sent by the scanner. The before gift will be 1. The through the present implementation supported values are 1 = one view, 2 = two views If two views are released, the data for the two views, depending on the quantum of the y-up solutions of the same, nested on a row basis sent. For example, if the y resolution of the first An view 300, and the y resolution of the second view 150 then the data alternate with two lines of view of the first picture and then a line of the picture of the second line view (except at the beginning; see the examples above in the Image post-processor section).

The select view command is used to set the scanner settings for the view or views to work with as follows:
Command: Select view
Escape sequence: Esc * f # B
Query ID: 10467
Range: 0-1
Default: 0
Macro: SetViewType (x)
Send command SendCommand (SL_VIEW_TYPE, x)
x can be 0 for view one or 1 for view two.

The view must be before selecting the scanner positions can be selected. This command selects on which view the following SCL commands or queries refer to to take. Supported values are: 0 (view one) and 1 (on view two). The default is view one.

III. Method for resolving multiple image scan data

A host computer software solves the nested more shed images sent by the scanner will. In the present implementation this is possible Software program Dual Scan (= double scanning) and its supporting modules that a user who the details of the multi-image data format, without further ado Multiple image data from the scanner in known Resolves Tiff files, which can then be used with programs such as B. PhotoShop can be used. DualScan is a soft product range sold by Hewlett-Packard Co. becomes. It is possible that one or both of the images come together contain primed data, which further the resolution problem complicated. The DualScan software enables use Form a scanner with a multi-image capability their hardware by resolving the nested Data stream received by the scanner. Professionals can easily expand the DualScan program to resolve multiple views of data and not the two views as it is in the present imple mentation is described to include.

Fig. 4 is a block diagram of a dual image data stream 136 (not shown) from the scanning device is sent, and (not shown) through a Datenstromauflöser 122 to the host computer in view-one data (monochrome image) 126 and the view-two Data (color image) 124 is resolved. The operation of the data stream resolver is further explained with reference to FIG. 5, which is a flow diagram of the data stream resolver function.

At the initial entry point, the resolution, compression state, bytes per line for each of the images are queried by the data resolver at 200 . Next, the image ratios for each view are calculated by the data resolver at 202 . Then interlaced image data is received by the data resolver from the scanner at 204 . The data resolver then copies a line of scan data to the appropriate output buffer, decompressing the data at 206 if necessary. The data resolver then ( 210 ) changes views based on the image ratios calculated at 202 . If no errors are detected and the data stream is not resolved ( 212 ), the resolver returns to 204 and receives more interleaved data from the scanner to be resolved. If an error is detected or the resolving of the data stream is completed at 212 , the resolver returns this status to the calling function that takes appropriate action. Error conditions may include the following conditions: ( 1 ) output buffer full, ( 2 ) poor response from the scanner, ( 3 ) decompressor has no data, and the scanner has no data, or ( 4 ) scan completed. The steps in FIG. 5 are also shown in the source code in Appendix A.

It should be noted that although the implementation outlined herein is a double scan, double views and resolving two nested data streams writes these concepts down to the multiple buttons, on multiple views and on the resolution of more multiply nested data streams is expandable.

The foregoing description of the present invention  was only for purposes of illustration and description spelled out. It is not intended to be exhausted fend, or that the invention to the precise disclosed form limited, and further modifications and Variations may be possible in light of the above teachings. For example, the data stream resolver can chess everyone Telten stream containing more than one record dissolve. The data stream does not have to be a data stream one keyed image. It is also for the SCL implementa tion of multiple views of the same window is irrelevant how the multiple views were obtained; the im plementation is the same whether the views of egg one or more samples of the same area are obtained were.  

APPENDIX A

Claims (10)

1. A method for generating multiple reproductions of an image with a scanning device, the method comprising the following steps:

• (a) performing a single scan of the image with the scanner; and
• (b) by the scanner, generating more than one rendering ( 132 , 134 ) of the image obtained from the single scan of the image.

2. A method of generating multiple reproductions of an image with a scanner according to claim 1, wherein step (b) further comprises the step of:
Generating at least one grayscale image ( 134 ) and at least one color image ( 132 ). 3. A method of generating multiple reproductions of an image with a scanner according to claim 1 or 2, wherein step (b) further comprises the step of:
Generating at least one grayscale image with high resolution ( 134 ) and at least one color image with low resolution and high bit depth ( 132 ). 4. A method for generating multiple reproductions of an image with a scanning device according to any one of the preceding claims, further comprising the step of:

• (c) by the scanner, sending the more than one rendering of the image obtained from a single scan of the image to a host computer ( 102 ) for further processing.

5. Scanning device with the following features:
an image processing unit ( 100 ) for generating more than one reproduction of an image from a single scan. 6. scanning device comprising according to claim 5, wherein the image processing unit (100) further includes a prescaler (144), wherein the prescaler (144) a Einzelabta in more divides stungsbild as a reproduction (128, 130) of the single scan image. 7. A scanning device according to claim 6, wherein the divider ( 144 ) divides the single-scan image into at least one monochrome reproduction ( 130 ) of the single-scan image and into at least one color reproduction ( 128 ) of the single-scan image. 8. A scanner according to claim 6 or 7, wherein the prescaler ( 144 ) divides the single-scan image into at least one gray-scale image with high resolution ( 130 ) and into a color image with low resolution and high bit depth ( 128 ). 9. A method for generating multiple reproductions of an image, the method comprising the following steps:

• (a) performing a single scan of the image with a scanner;
• (b) by the scanner, generating more than one data signal representing more than one rendering ( 132 , 134 ) of the single scan image; and
• (c) by the scanner, interleaving the more than one data signal representing more than one rendering ( 132 , 134 ) of the single scan image into a single interleaved data stream.

10. A method for generating multiple reproductions of an image according to claim 9, further comprising the step of the scanner of sending the single interlaced data stream ( 136 ) to a computer ( 102 ) for further processing the more than one reproduction ( 132 , 134 ) of the single-scan image.