Abstract:
A method and apparatus for digital image reduction using an improved “extendible” perspective projection technique which allows for flexible control of the averaging cell or window size separately from the reduction ratio to improve moir{acute over (e)} suppression or sharpness as desired in the resulting reduced-size image. The extendible perspective projection technique can also be implemented together with ordinary perspective projection or together with a combined one-dimensional filter and linear interpolation technique to produce a reduced-size image of a quality comparable to those produced by the prior technique of using a two-dimensional pre-filter prior to interpolation at a much lesser cost due to the reduced number of required scanline buffers.

Description:
BACKGROUND OF THE INVENTION 
     This application relates to the digital image processing arts. More particularly, the application relates to a method and apparatus for digital image reduction in an efficient and cost-effective manner, with good suppression of moir{acute over (e)} and other undesirable artifacts as often become more pronounced in a downsampled image such as a reduced-size digital image. Such undesirable moir{acute over (e)} has been found to be especially severe upon reduction of a scanned halftone image. 
     Digital image reduction is essentially a down-sampling process whereby image pixel data for a bitmap of n rows×m columns is used to construct a smaller bitmap of k rows×l columns, where k≦n and/or l≦m. Of course, while the location of each pixel in the new, reduced-size bitmap is known, its “gray” value is unknown and must be determined with reference to the original image. 
     Many methods are known for determining the gray value of each pixel in the reduced image. A relatively simple method is commonly referred to as “nearest neighbor” interpolation. In such case, if the reduced-size bitmap is viewed as being superimposed over the original image bitmap, the gray value for each new pixel is simply the value of the spatially closest pixel in the original bitmap. Although fast, nearest neighbor interpolation is often not satisfactory in terms of the quality of the resulting reduced-size image. 
     Another common interpolation technique used in digital image downsampling is bilinear interpolation. Using bilinear interpolation, the newly generated pixel gray value is set to be the weighted sum of the four nearest original pixels. The weights are determined linearly—i.e., each weight is inversely proportional to the distance from each original pixel. Bilinear interpolation has been found to yield higher quality reduced-size images relative to nearest neighbor interpolation. Of course, bilinear interpolation also requires significantly more computational effort compared to nearest neighbor interpolation. Additionally, bilinear interpolation still often results in severe moir{acute over (e)} and other undesirable artifacts in the new image. 
     Techniques have been proposed and implemented for reducing moir{acute over (e)} which becomes apparent due to downsampling. One prior method involves the application of a two-dimensional low-pass filter to the pixel data of the original image prior to the downsampling operation. The low-pass filter has the effect of reducing high-frequency content in the original image—i.e., the filter has the effect of somewhat “blurring” the original image. This filtered image data is then used in the scaling operation and results in a reduced-size image with less severe moir{acute over (e)}. Unfortunately, the circuitry required to apply a useful two-dimensional filter to the original image data is expensive to implement. In particular, a relatively large number of scanline buffers are needed to store pixel data from multiple scanlines of the original image. For example, in order to apply a 5×5 filter, at least four scanline buffers would typically be needed for the incoming original image data. These scanline buffers add significant expense to the reduction apparatus. Furthermore, reduction of color digital images requires this circuitry to buffer the original image data for each color separation of the original image. 
     Another prior technique used to reduce moir{acute over (e)} resulting from downsampling is sometimes referred to as “perspective projection.” Perspective projection creates a new pixel from the original image data by averaging a correspondingly located area of the original image. While perspective projection has also been found to be generally effective in reducing moir{acute over (e)}, in certain cases, such as in the downsampling of halftone image data, moir{acute over (e)} is still apparent in the resulting image. 
     Moir{acute over (e)} apparent after downsampling using perspective projection reduction has resulted from the fact that, heretofore, perspective projection has been implemented so that the size of the area of the original image that is averaged is a linear function of the image reduction ratio. The reduction ratio is defined as 1/scale, where scale=a scaling factor such as 0.5 (a reduction to 50% original size), 0.8 (a reduction to 80% original size), etc. For example, in reducing an image to 50% of original size, a reduction ratio of 2 results (i.e., 1/0.5=2), and a 2×2 pixel area in the original image is used for averaging. In another example, in reducing an image to 80% of original size, a reduction ratio of 1.25 results (i.e., 1/0.8=1.25), and a 1.25×1.25 pixel area in the original image is averaged. 
     It should be apparent from the foregoing that prior perspective projection techniques have not provided any means by which the area averaged in the original image can be controlled separately from the reduction ratio. Accordingly, prior perspective projection methods have not allowed for any control of moir{acute over (e)} suppression v. sharpness, with enhanced moir{acute over (e)} suppression provided by a larger averaging area and enhanced sharpness provided by a smaller averaging area. 
     Accordingly, in light of the foregoing and other deficiencies associated with prior digital image downsampling methods and apparatus, it has been deemed desirable to develop a method and apparatus for digital image reduction using an improved “extendible” perspective projection technique which allows for flexible control of the averaging cell or window size separately from the reduction ratio to improve moir{acute over (e)} suppression or sharpness as desired in the resulting reduced-size image. 
     Furthermore, it has been deemed desirable to provide a method and apparatus wherein the extendible perspective projection technique is implemented together with ordinary perspective projection or together with a combined one-dimensional filter and linear interpolation technique to produce a reduced-size image of a quality comparable to those produced by the prior technique of using a two-dimensional pre-filter prior to interpolation at a much lesser cost due to the reduced number of required scanline buffers. 
     SUMMARY OF THE INVENTION 
     In accordance with the present invention, a hybrid image reduction method and apparatus are provided for cost-effective scale reduction of digital images with flexible control of moir{acute over (e)} suppression v. image sharpness. 
     In accordance with a first aspect of the invention, a method of downsampling an input digital image defined by plural image pixel gray values arranged in n rows extending in a fast scan direction and m columns extending in a slow scan direction to a reduced-size output image defined by plural image pixel gray values arranged in k rows and l columns, wherein k≦n and/or l≦m includes determining a plurality of averaging areas in said input image, each averaging area corresponding to an image pixel gray value location in said output image and defined by dimensions efs in the fast scan direction and ess in the slow scan direction, wherein efs and ess are determined according to 
     efs=fs_factor/fs_scale 
     ess=ss_factor/ss_scale 
     and wherein fs_scale and ss scale are scaling factors for the input image in the fast scan and slow scan directions, respectively. The parameters fs_factor and ss_factor are selected independently of each other according to: 
     fs_factor&gt;0 
     ss_factor&gt;0 
     wherein at least one of fs_factor and ss_factor≠1. For each of said plurality of averaging areas of said input image, an average of the input image pixel gray values at least partially encompassed thereby is obtained and the correspondingly located image pixel gray value location in the output image is assigned the average of the input image pixel gray values at least partially encompassed by the averaging area. 
     In accordance with another aspect of the present invention, a hybrid method for downsampling image pixel data of an input digital image by fs_scale in a fast scan direction and by ss_scale in a slow scan direction includes applying a onedimensional low-pass filter to image pixel gray values of the input image in only the fast scan direction to obtain intermediate, filtered grey value pixel data. Thereafter, the intermediate, filtered pixel gray values are downsampled in the fast scan direction using perspective projection reduction and, in said slow scan direction, using extendible perspective projection reduction. The downsampling operations include determining a plurality of averaging areas for the intermediate pixel data, each of the averaging areas associated with a correspondingly located output image pixel grey value area in an output image and defined by a dimension ef s in the fast scan direction and a dimension ess in the slow scan direction. The dimensions efs and ess are selected according to: 
     efs=1/fs_scale 
     ess=ss_factor/ss_scale 
     wherein ss_factor&gt;1. For each of the plurality of averaging areas, an average gray value of the filtered gray value pixel data at least partially within the averaging area is obtained and assigned to the correspondingly located output image pixel gray value area. 
     In accordance with another aspect of the present invention, a hybrid method of image scale reduction includes applying a one-dimensional low-pass filter to image pixel data of an input image in only a fast scan direction. Thereafter, the input image is downsampled in the slow scan direction using an extendible perspective reduction and downsampling in the fast scan direction using one of linear interpolation and perspective projection. The extendible perspective projection reduction includes determining input image gray value averages in each of a plurality of averaging areas defined by a fast scan dimension efs and a slow scan dimension ess, wherein efs and ess are selected according to: 
     ess=ss_factor/ss_scale 
     wherein ss_scale is a scaling factor for the input image in the slow scan direction and wherein ss factor&gt;1. The dimension efs=1 when linear interpolation is used to downsample the input image in the fast scan direction and efs&gt;1 when perspective projection is used to downsample the input image in the fast scan direction. 
     In accordance with yet another aspect of the invention, an image reduction apparatus for reducing an input image having n rows and m columns to a reduced size image having ss_scale*n rows and fs_scale*m columns includes means for calculating an average gray value for each of a plurality of averaging areas in the input image according to input image gray value pixel data located in each of the areas. Each of the averaging areas defined by dimensions efs and ess wherein: 
     efs=fs_factor/fs_scale; 1&lt;fs_factor≦2 
     ess=ss_factor/ss_scale; 1&lt;ss_factor≦2; 
     The apparatus further includes means for outputting the reduced-size image defined by a plurality of gray values, wherein each of the gray values of the reduced-size image is set equal to the average gray value calculated for the correspondingly located averaging area in the input image. 
     One advantage of the present invention resides in the provision of a new and improved method and apparatus for cost-effective size reduction of digital images with moir{acute over (e)} suppression. 
     Another advantage of the present invention is found in the provision of a method and apparatus for digital image reduction allowing for flexible control of moir{acute over (e)} suppression and image sharpness. 
     A further advantage of the present invention is that the flexible control of moir{acute over (e)} suppression v. sharpness can be controlled by user input and/or by embedded image segmentation tags which identify characteristics of the original image data that is to be downsampled. 
     Still another advantage of the present invention is the provision of a hybrid image reduction method and apparatus which utilizes more than one image downsampling method to enhance the quality of the resulting image at a reduced cost. 
     A still further advantage of the present invention is found in the use of a one-dimensional filter together with subsampling within each scanline of the original image, together with an extendible perspective projection downsampling technique among different scanlines of the original image to produce high-quality reduced-size images in a cost-effective manner. 
     Still other benefits and advantages of the present invention will become apparent to those of ordinary skill in the art upon reading and understanding the present specification together with the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention may take form in various steps and arrangements of steps, and in various components and arrangements of components. The drawings are only for purposes of illustrating preferred embodiments of the invention, and are not intended to limit the invention in any way. 
     FIG. 1 is a simplified block diagram illustrating a digital image processing system in accordance with the present invention; 
     FIG. 2 diagrammatically illustrates conventional perspective projection image reduction; 
     FIG. 3 diagrammatically illustrates extendible perspective projection image reduction in accordance with the present invention; 
     FIG. 4A illustrates a hybrid image reduction method in accordance with the present invention using perspective projection in the fast scan direction (i.e., within a scanline) and using extendible perspective projection in the slow scan direction (i.e., between successive scanlines); 
     FIG. 4B is a flow chart illustrating a hybrid digital image reduction method in accordance with one embodiment of the present invention; 
     FIG. 4C is a simplified block diagram illustrating a hybrid digital image reduction apparatus in accordance with the present invention; and, 
     FIG. 5 is a flow chart illustrating a hybrid digital image reduction method in accordance with another embodiment of the present invention. 
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     Referring now to the drawings where the showings are for purposes of describing preferred embodiments of the invention only and not for purposes of limiting same, a digital image processing system  10  in accordance with the present invention is shown in FIG.  1 . An image input terminal  12 , comprising a scanner, computer image generator, an image storage device, or the like, derives or delivers digital image data in the form of one or more monochromatic separations, wherein the picture elements or “pixels” of each separation are defined at a depth of “d” bits per pixel where “d” is an integer. Accordingly, each pixel of each separation is defined in terms of “d” bits per pixel(bit depth=d), and each pixel has some “gray” value between full “off” and full “on.” When the digital image data is provided in terms of a single monochromatic separation, the image is monochromatic, for example, so called “black-and-white” image data. On the other hand, when the digital image data is provided in terms of two or more monochromatic separations, a color image results when the data from the separations is combined, for example, red-green-blue (RGB) separations or cyan-magenta-yellow (CMY) separations. 
     The image signals are input to an image processing unit  14  wherein digital image processing, such as image scaling in accordance with the present invention, is performed. The image processing unit  14  may be provided by any suitable electronic computing apparatus such as an electronic computer, a dedicated electronic circuit, or any other suitable electronic circuit means. The image processing unit  14  outputs data in a suitable format to an image output terminal  16  such as a digital printer. Suitable apparatus for digital image input and/or output include the XEROX Document Center 265DC digital imaging system, Pixelcraft 7650 Pro Imager Scanner, XEROX DocuTech Production Printing System scanners, the XEROX 5775 digital color copier, the XEROX 5760 and 5765 Majestik digital color copiers, or any other suitable digital scanner and/or copier. Regardless of the depth d at which each pixel is defined, the location of each pixel in each separation bitmap is also defined, typically in terms of a row n and a column m. 
     With reference now also to FIG. 2, conventional perspective projection image reduction or downsampling as is generally known is illustrated for purposes of understanding the present invention and its advantages relative to perspective projection as illustrated in FIG.  2 . For convenience of illustration, each image processing operation described herein, including that illustrated in FIG. 2, is explained with reference to digital image data comprising only a single, monochromatic bitmap or separation. However, those of ordinary skill in the art will recognize that the invention has equal application to color digital images comprised of multiple separations of image data by performing the operations described herein on each separation of the image. Furthermore, the image processing operations described herein have application to digital images of any size, and the illustrated examples were chosen for facilitating understanding of the invention. 
     The conventional perspective projection image reduction or scaling operation illustrated in FIG. 2 is carried out in the image processing unit  14  as are all other image processing operations described herein. An original image bitmap  20  is input to the image processing unit  14  and comprises a plurality of scanlines or rows r and columns c of image pixels or pixel data P (i.e., gray values) which vary to control the appearance of the image  20 . Each row r of image pixel data P is said to extend in a “fast scan” direction and each column c of image pixel data is said to extend in a “slow scan” direction i.e., fast scan processing occurs within a scanline r while slow scan processing occurs between scanlines r. 
     In the example illustrated in FIG. 2, the original image  20  comprises 5 rows r and 5 columns c of image pixel data P. Based upon user input to the image processing unit  14 , it is desired to scale the original image 20 to 80% of its original size—i.e., to reduce the image to a new output image  20 ′ comprising 4 rows r′ and 4 columns c′ of image pixel data P′. The pixel data P′ in the output image  20 ′ must be chosen so that the features of the original image  20  are still satisfactorily apparent in the image  20 ′ even though less image pixel data P′ is available to represent the features. Accordingly, the illustrated perspective projection operation is used to downsample the image  20  to the image  20 ′ in a manner that accurately reproduces the image  20  in the smaller image  20 ′. 
     Using conventional perspective projection reduction, the output pixel data P′ is obtained from the original image  20  by averaging pixel data P in an area of the original image  20  that corresponds to the location of the desired output pixel data P′ in the output image  20 ′. This averaging of corresponding areas can be visualized as dividing the original image  20  into a 4×4 matrix of equal size averaging cells AP 1 ,AP 2  (only two cells shown for clarity) as required for the output image  20 ′ and so that each averaging cell AP 1 ,AP 2  corresponds to a single like location AP 1 ′,AP 2 ′ in the output image  20 ′. This, then, allows the weighted average of the pixel data P encompassed or partially encompassed by each averaging cell AP 1 ,AP 2  to be calculated according to the relative spatial contribution of the encompassed or partially encompassed pixel data P to the cell AP 1 ,AP 2 . Use of a weighted average accounts for the fact that each relevant item of pixel data P in the original image  20  does not contribute equally to the area of the averaging cell AP 1 ,AP 2 . 
     Each averaging cell AP 1 ,AP 2  has a size defined by fast scan dimension fs and a slow scan dimension ss. The dimensions fs,ss can be determined mathematically according to the following: 
     fs=1/fs_scale 
     ss=1/ss_scale; 
     wherein fs_scale and ss_scale are the factors by which the original image  20  is scaled in the fast scan and slow scan directions, respectively. For example, if an image is to be scaled to 50% of its original size in both the fast scan and slow scan directions, fs_scale=ss_scale=0.5. In the present example, the original image  20  is to be scaled to 80% of its original size. Accordingly, fs_scale=ss_scale 0.8. Therefore, fs and ss are determined as follows: 
     fs=1/0.8=1.25 
     ss=1/0.8=1.25 
     Each averaging cell AP 1 ,AP 2  encompasses 1.25 items of image pixel data P in the fast scan direction and 1.25 items of pixel data P in the slow scan direction. 
     As is described in detail above, conventional perspective projection reduction as illustrated in FIG. 2 often results in an output image  20 ′ that exhibits severe or unacceptable moir{acute over (e)}. The moir{acute over (e)} is often especially apparent in reducing a halftone original image  20 . The moir{acute over (e)} results from the fact that the area encompassed by each averaging cell AP 1 ,AP 2  is insufficient. However, as is illustrated in the above formulas, the area of each averaging cell AP 1 ,AP 2  is inseparably tied to the fs_scale and ss_scale factors. Thus, further moir{acute over (e)} suppression is not possible using conventional perspective projection methods. 
     Turning now to FIG. 3, extendible perspective projection in accordance with the present invention is illustrated. Extendible perspective projection as described herein has many advantages over prior art perspective projection, including the ability to adjust the size of the averaging cells to enhance moir{acute over (e)} suppression. For ease of understanding extendible perspective projection in accordance with the invention, like features illustrated in FIG. 3 relative to those illustrated in FIG. 2 are identified with like reference characters and numerals. 
     Extendible perspective projection reduction in accordance with the present invention comprises obtaining the output pixel data P′ from the original image  20  by averaging pixel data P in a rectangular (including a square) area of the original image  20  that corresponds to the location of the desired output pixel data P′ in the output image  20 ′. As shown in FIG. 3, the weighted average of the pixel data P encompassed by an averaging cell EP 1  in the original image  20  is calculated to obtain the gray value data for a correspondingly located area EP 1 ′ of the output image  20 ′. Likewise, the weighted average of the pixel data P encompassed by an averaging cell EP 2  in the original image  20  is calculated to obtain the gray value data for a correspondingly located area EP 2 ′ of the output image  20 ′. By repeating this operation for each of the unknown items of output pixel data P′ in the output image  20 ′, the reduced size image  20 ′ is obtained. 
     Determining the location and size of each extendible perspective projection averaging cell EP 1 ,EP 2  can be thought of initially as described in relation to conventional perspective projection as discussed in relation to FIG.  2 —i.e, the original image  20  is divided into a matrix of equal size averaging cells, with each of the cells corresponding in location to an item of output pixel data P′ required for the output image  20 ′. However, unlike conventional perspective projection described above, each averaging cell EP 1 ,EP 2  (only two shown for clarity) is expanded or extended in the fast scan and slow scan directions—to the right and downward as illustrated in FIG.  3 —so that each extendible perspective projection averaging cell EP 1 ,EP 2  has a larger size, relative to the ordinary perspective projection averaging cell AP 1 ,AP 2 , defined by an extended fast scan dimension efs and an extended slow scan dimension ess. Those of ordinary skill in the art will recognize that the averaging cells EP 1 ,EP 2  may be extended bi-directionally in both the fast scan direction and the slow scan direction, e.g., so that the pixel P of interest in the original image  20  is centrally located in the averaging area EP 1 ,EP 2 . The dimensions efs,ess can be determined mathematically according to the following: 
     efs=fs_factor/fs_scale 
     ess=ss_factor/ss_scale; 
     wherein fs_scale and ss_scale are the scaling factors for the original image  20  in the fast scan and slow scan directions, respectively, as described above, and wherein fs_factor and ss_factor are programmable parameters which vary, preferably according to 1≦fs_factor≦2; 1≦ss_factor≦2, wherein at least one of fs_factor and ss_factor is not equal to 1; fs_factor and/or ss_factor may also be less than 1 when increased image sharpness is desired. 
     The parameters fs_factor and ss_factor are preferably chosen according to user input to the image processing unit  14  through use of a sharpness and/or moir{acute over (e)} suppression input selector switches to the unit  14 . Those skilled in the art will recognize that, as fs_factor and ss_factor increase toward 2, the dimensions efs and ess increase, respectively. Conversely, as fs_factor and ss_factor approach 1, the dimensions efs and ess approach the dimensions fs and ss as would be obtained through conventional perspective projection. When fs_factor and ss_factor are less than  1 , image sharpness increases even further with less moir{acute over (e)} suppression. Those skilled in the art will also recognize that, as the dimensions efs and ess increase, more image pixel data P will be averaged to obtain each item of output pixel data P′ in the output image  20 ′ leading to reduced sharpness but increased moir{acute over (e)} suppression. On the other hand, as efs and ess decrease and approach fs and ss, respectively, sharpness increases with less effective moir{acute over (e)} suppression in the output image  20 ′. This, then, allows a user to select enhanced moir{acute over (e)} suppression or enhanced sharpness, as desired, with the described trade-off therebetween. It is noted that the parameters fs_factor and ss_factor may also be varied automatically by the image processing unit  14  in accordance with segmentation tags associated with each pixel P of the original image  20  for identifying the type of image data represented by that pixel—e.g., text, halftone, continuous tone, or the like. For example, if the original image  20  was comprised of halftone pixel data as indicated by segmentation tags, the image processing unit would increase fs_factor and ss_factor to suppress moir{acute over (e)}, while if the original image  20  was comprised of continuous tone data as indicated by segmentation tags, the image processing unit would decrease fs_factor and ss_factor to increase sharpness. 
     In the example illustrated in FIG. 3, the image  20  is to be reduced to 80% of its size in an image  20 ′. Therefore, fs_scale ss_scale=0.8. A user has selected enhanced moir{acute over (e)} suppression and the image processing unit has set fs_factor=1.4 and ss_factor=2.0. This leads to the calculation of efs and ess as follows: 
     efs=1.4/0.8=1.75 
     ess=2/0.8=2.5 
     so that each extendible perspective averaging cell EP 1 ,EP 2  encompasses 1.75 pixels P in the fast scan direction and 2.5 pixels P in the slow scan direction. In doing extendible perspective projection reduction in accordance with the present invention, the original image  20  can be viewed as a continuous two-dimensional function with each pixel being a unit square filled with its gray value P. The pixel value P′ in the scaledown image is calculated as the integral of the two-dimensional function over the area efs×ess, divided by that area. 
     FIGS. 4A-4C illustrate hybrid image reduction or downsampling employing extendible perspective projection reduction in accordance with the present invention. For ease of understanding FIG. 4A, like features therein relative to those illustrated in FIG. 3 are identified with like reference characters and numerals, and new features are illustrated with new reference characters and numerals. 
     With particular reference to FIG. 4B a step or means S 1  applies a one-dimensional fast scan direction low-pass filter to the image pixel data of the original image (not shown). Since a one-dimensional filter in the fast scan direction comes at almost no additional cost, a relatively large filter size, e.g., 11, 13, 15, or any other suitable number of elements, is preferably used. The filtering operation results in an intermediate image  120  (FIG. 4A) of the same size as the original image but including filtered image pixel data FP. The intermediate image  120  is then reduced using a hybrid method according to the present invention by a step or means S 2  to yield the downsampled pixel data FP′ for the reduced-size output image  120 ′. 
     In a first embodiment of hybrid image reduction in accordance with the invention, the intermediate image is reduced by extendible perspective projection in the slow scan direction and conventional perspective projection in the fast scan direction. Accordingly, the fast scan and slow scan dimensions efs,ess of each hybrid averaging cell HP 1 ,HP 2 (only two shown for clarity) applied to the intermediate image  120  are determined as follows: 
     efs=1/fs_scale 
     ess=ss_factor/ss_scale 
     wherein fs_scale and ss_scale are the factors by which the intermediate image  120  is scaled in the fast scan and slow scan directions, respectively, as described above, and wherein ss_factor is a programmable parameter which varies, preferably according to 1≦ss_factor≦2. The weighted average of filtered pixel data FP encompassed by each cell HP 1 ,HP 2  is used as the gray value in a correspondingly located area HP 1 ′,HP 2 ′ of the output image  120 ′. 
     FIG. 4C is a simplified block diagram of an image processing unit  14  suitable for carrying out hybrid image reduction as illustrated in FIGS. 4A and 4B. A central processing unit  200  performs all required calculations. The original image is input at  202  to the image processing unit  14  and fed to a fast scan one-dimensional filter  204 , which is preferably a one-dimensional fast scan direction low-pass filter, for purposes removing high-frequency components from the original image data in the fast scan direction. The fast scan filtered, intermediate image data is fed to a slow scan control unit  210  which, through first and second switches  212   a , 212   b , controls the flow of fast scan filtered image data FP to first and/or second fast scan position control units  220   a , 220   b . The fast scan position control units control the flow of filtered data FP into first and second scanline buffers  230   a , 230   b , respectively, as is required to perform the combined perspective projection and extendible perspective projection reduction operations described above. An output selector control  240  controls the flow of output image pixel data FP′ from the first and second scanline buffers  230   a , 230   b  to a reduced image data output  250 . 
     FIG. 5 illustrates another hybrid image reduction method in accordance with the present invention wherein a step or means S 10  applies a one-dimensional fast scan filter to the original image data as described above. The resulting intermediate image is then reduced by a step or means S 20  in the slow scan direction to form an intermediate image  120 . The step or means S 20  preferably performs an extendible perspective reduction operation wherein: 
     efs=1/1=1 
     ess=ss_factor/ss_scale 
     so that the intermediate image is reduced only in the slow scan direction. A step or means S 30  downsamples the image resulting from the step or means S 20  in the fast scan direction, preferably using conventional linear interpolation, although any other suitable fast scan direction subsampling method may be used. Those of ordinary skill in the art will recognize that the steps S 20  and S 30  may be carried out in reverse order (i.e., fast scan linear interpolation S 30  before slow scan extendible perspective projection S 20 ) without departing from the overall scope and intent of the present invention. 
     The invention has been described with reference to preferred embodiments. Modifications and alterations will occur to others upon reading and understanding the preceding specification. It is intended that the invention be construed as including all such modifications and alterations insofar as they fall within the scope of the appended claims or equivalents thereof.