Abstract:
A highly efficient method and system for eliminating halftone screens from scanned documents while preserving the quality and sharpness of text and line-art is disclosed. The method and system utilizes a single channel screen frequency estimator module, which generates a screen frequency estimate for image data. The module generates a signal based on the highly filtered image signal at low contrast levels, and based on a reliable estimate to the halftone frequency at higher contrast levels. The single channel screen estimate module has adequate performance in resolution ranges from 300 to 600 dpi.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     The present application is related to the following co-pending U.S. applications: Ser. No. 10/776,514 entitled “Systems and Methods for Generating High Compression Image Data Files Having Multiple Foreground Planes”; Ser. No. 10/776,515 entitled “Systems and Methods for Identifying Regions Within an Image Having Similar Continuity Values”; Ser. No. 10/776,608 entitled “Systems and Methods for Connecting Regions of Image Data having Similar Characteristics”; Ser. No. 10/776,602 entitled “Systems and Methods for Organizing Image Data Into Regions”; Ser. No. 10/776,603 entitled “Systems and Methods for Adjusting Image Data to Form Highly Compressible Imaae Planes”; Ser. No. 10/776,620 entitled “Method and Apparatus for Reduced Size Image”; Ser. No. 10/776,509 entitled “Finite Impulse Response Filter Method and Apparatus”; Ser. No. 10/776,508 entitled “Apparatus and Methods for De-Screening Scanned Documents”; and Ser. No. 10/776,516 entitled “Segmentation Method and System for Scanned Documents”, all of which were filed concurrently with the present application, are currently pending, and are hereby incorporated by reference in their entireties. 
     The present application is related to the following co-pending applications: Ser. No. 10/187,499 entitled “Digital De-Screening of Documents”, Ser. No. 10/188,026 entitled “Control System for Digital De-Screening of Documents”, Ser. No. 10/188,277 entitled “Dynamic Threshold System for Multiple Raster Content (MRC) Representation of Documents”, Ser. No. 10/188,157 entitled “Separation System for Multiple Raster Content (MRC) Representation of Documents”, and Ser. No. 60/393,244 entitled “Segmentation Technique for Multiple Raster Content (MRC) TIFF and PDF all filed on Jul. 01, 2002 and all commonly assigned to the present assignee, the contents of which are herein incorporated by reference. 
     BACKGROUND OF THE INVENTION 
     1. Field of Invention 
     The present invention relates generally to methods and systems for image processing, and more particularly to methods and systems for de-Screening digitally scanned documents. 
     2. Description of Related Art 
     Almost all printed matter, except silver-halide photography, is printed using halftone screens. The need to estimate the halftone frequency and magnitude stems from the fact that almost all printed matter, with the exception of a few devices like dye-sublimation or silver-halide photography, is printed out using halftone screens. These halftones are very specific to the printing device and when scanned and re-halftoned may cause visible artifacts and/or unacceptable Moiré patterns if not properly removed. The suppression of halftones is especially important for color documents, since these are typically printed with four or more color separations containing slightly different screens at different angles and or frequencies, and these may interact with each other to cause undesirable spatial artifacts. 
     The successful removal of the original halftone screens is based on the ability to accurately estimate the local frequency. Therefore there is a need for an improved method and apparatus for estimating the halftone screen frequency and magnitude. 
     SUMMARY OF THE INVENTION 
     A highly efficient method and system for eliminating halftone screens from scanned documents while preserving the quality and sharpness of text and line-art is disclosed. 
     A screen estimate module is disclosed, which uses only a single channel of image data processing to generate a screen frequency estimate for downstream image processing, particularly for de-screening of the halftone signals from the image. 
     Although using only one channel, the screen estimate module can generate a high quality and reliable estimate of the halftone screen frequency. A single channel screen frequency estimate is sufficient, because when the contrast is low or near zero, the frequency estimate is based on a highly filtered image signal, and may not be an accurate frequency measurement. However, when it is low, minimal halftone noise is measured in the input image and knowledge of its precise frequency is not required by downstream processing. A wide range of edge-sharpening effects may be applied to the image data in this situation, without exacerbating undesirable halftone artifacts. When the contrast is higher, the frequency estimate is based on a reliable measurement of the halftone frequencies occurring in the image. Therefore, a single channel screen frequency estimate can be used over the full range of image contrast. 
     Because only a single channel is used, significant savings in terms of cost, power and device package size can accrue from practicing the invention. The regime in which this invention is particularly effective is in the range of resolutions of 300 to 600 dpi. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The features and advantages of the present invention will become apparent from the following detailed description of the present invention in which: 
         FIG. 1  is a block diagram of the system of a single channel screen estimator module. 
         FIG. 2  illustrates one-dimensional filter responses of various filter units. 
         FIGS. 3-5  illustrates two-dimensional filter responses of various units. 
         FIGS. 6A and 6B  illustrates a typical 3×3 max module structure. 
         FIGS. 7A and 7B  illustrates a typical 3×3 contrast module structure. 
         FIG. 8  shows a min-max detection structure within a 3×3 window. 
         FIGS. 9A . and  9 B illustrates a single interpolation unit. 
         FIG. 10  is a block diagram of a structure of a Bilinear Interpolation unit. 
         FIG. 11  illustrates a screen frequency estimation equation. 
     
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     A new method and system are described for de-Screening digitally scanned documents such that potential halftone interference and objectionable Moiré patterns are eliminated or substantially reduced. Referring now to  FIG. 1 , a block diagram of the method and system of the present invention is represented by a single channel screen estimator module SEM  40 . The screen estimator module  40  is responsible for estimating the instantaneous halftone frequency at the current pixel of interest. The screen-estimator module  40  operates on an 8-bit source image Src  28 , and produces an 8-bit halftone frequency estimate Scm  72 . 
     The need to estimate the halftone frequency and magnitude stems from the fact that almost all printed matter, with the exception of a few devices like dye-sublimation or silver-halide photography, is printed out using halftone screens. These halftones are very specific to the printing device and, when scanned and re-halftoned for printing may cause visible artifacts and/or unacceptable Moir6 patterns if not properly removed. A de-screen module (DSC) as described in Applicant&#39;s co-pending application, Ser. No. 10/776,508 relies on the information that is produced by the screen estimator module in order to eliminate (filter out) the original halftone patterns from the original scanned image. The suppression of halftones is especially important for color documents, since these are typically printed with four or more color separations containing slightly different screens at different angles and or frequencies, and these may interact with each other to cause undesirable spatial artifacts. 
     The prior art screen estimator module used up to three frequency channels at different levels of sensitivities. An upper channel was tuned for maximum frequency sensitivity at the full source resolution and therefore is used for deriving the screen frequency estimate signal. However, this channel was very sensitive and would usually report the existence of frequencies even when the screen is very weak. Therefore the screen frequency was additionally qualified by a screen magnitude Scm  72 . 
     The single channel  40  in  FIG. 1  is tuned for moderate frequency sensitivity and operates at the full source resolution. The screen frequency signal Scm  72  is derived from the analysis of the frequency estimate that is produced by the single channel. 
     The single channel  40  is made up of a Min-Max texture detector MM 3   32  to be described below, followed by an averaging filter  42 . The single channel MM 3   32  unit operates on the single channel 8 bit incoming source signal Src  28 . The MM 3  Min-Max module  32  is used for finding peaks and valleys in the 2D input signal. A detailed description of the Min-Max detector unit is given below. The unit is basically examining the content of a 3×3 window centered on the current pixel of interest and analyzing, using adaptive thresholding, if the center pixel is significantly larger or smaller relative to its eight surrounding neighbors. If so, the center pixel is regarded to be a peak (if larger) or valley (if smaller) respectively. By counting the number of peaks and valleys per unit area, a measure of the local frequency is obtained. 
     The MM 3  unit output  32  has only 1 bit of precision, but is scaled by a configuration factor DotGain prior to the first subsequent stage of filtering. The unit operates on one or more color channels of the input signal. However, in this embodiment only one channel, the luminance channel is used. Note the scaling of the filter output can be postponed to the normalization step of the first subsequent filter by adjusting that stage&#39;s normalization factor. 
     The output from the MM 3  Min-Max detector  32  is passed through different averaging and sub-sampling filters. In order to avoid aliasing problems with the sub-sampling, the spatial filter span in each case is twice the sub-sampling ratio minus one. 
     Likewise, the single channel MM 3   32  output is applied to a cascade of two triangular 2D subsampling filters—the F 31 / 16  filter  42  and F 3 / 2  filter  46 . The output from the cascaded filtering units is sub-sampled by a factor of 32× in each direction (16× in the first filter and 2× in the second). 
     In the single channel  40 , a sample of the 1/16 resolution signal is passed to MX 3  unit  44 . This unit performs a 3×3 Max operation (gray dilation). The output is sent to the b input of the Bilinear Interpolation unit BIU  54 , respectively. 
     The single channel contains an additional smoothing/averaging F 5  unit  64  stage to further reduce spatial noise. The F 5  unit  64  is a 5×5 triangular weight (non-subsampling) filter. The filtered output from this unit is sent to the input of the Bilinear Interpolation units BIU  54 . The output is also passed through the C 3  contrast unit  48  which searches for the maximum difference in a 3×3 window centered on the current pixel. The C 3  output becomes the c input to the BIU unit  54 . 
     The three signals produced by the single channel  40  are sent to the BIU unit  54 . This unit performs bilinear interpolation to bring the sub-sampled input resolution back to the original source resolution. The a and c BIU inputs are at 1/32 resolution and the b inputs are at 1/16 resolution. The output bandwidth from the interpolation unit is substantially higher than the input. For example, with the factor of 32× above, the interpolation unit produces 1024 output pixels for each input pixel. 
     The output of the Bilinear Interpolation Unit  54  is the 8-bit estimated screen magnitude signal Scm  72 . The estimated screen frequency signal Scm  72  is exported to the De-Screen Module DSC  58  and to the Segmentation Module SEG  56 . A more detailed description of the various elements of the single channel screen estimator module  40  is provided below. 
       FIG. 2  illustrates one-dimensional filter responses of various filter units and  FIGS. 3-5  illustrates two-dimensional filter responses of various units. These Filtering Units are used for the purpose of smoothing or averaging the input signals to remove high frequencies. Each filter unit implements a square, separable and symmetric 2D FIR (Finite impulse response) filter. The filter response is identical in the horizontal and vertical directions. If the input to the filter is a color signal, the same filter response is independently applied on each one of the color components. The 1D filter  60  response has a symmetric triangular shape with integer coefficients as illustrated in  FIG. 2 . The particular filter shape (but any other filter shapes are covered) was chosen for ease of implementation. 
     The general filter form is referred to as an Fn/k filter, where n is the filter size (overall span in either x or y) and k is the amount of sub-sampling that is applied to the filtered output in each direction. The sub-sampling factor k is omitted when k=1. Note that in this document the filter span n is assumed to be an odd integer (n=1, 3, 5, . . . ) such that the 2D filter response has a definite peak at the valid center pixel location. 
     Examples for the 1D and 2D filter response are illustrated in  FIGS. 1 and 2 .  FIG. 2  shows the non-normalized ID filter  60  response for F 3  and F 11 , and  FIGS. 3 through 5  shows the resulting non-normalized 2-D coefficients for F 3   62 , F 5   64 , and F 7   66 , respectively. 
     Since the filter is separable, the 2D filter response can be implemented by cascading two 1D filters in the horizontal and vertical directions. The filters are all operating at the full input data rate, but the output may be sub-sampled by a factor of k in each direction. In many cases, although not always, the filter size n and the sub-sampling factor k satisfy the following relationship:
 
 n= 2* k− 1
 
     This represents 50% coverage overlap relative to the sub-sampled area. As an example, the overall 2-D response of the smallest 3×3 filter, F 3   62 , is: 
     
       
         
           
             
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     Larger filters are similarly described. Since these filters are separable, it is best to implement them in two 1D steps, orthogonal to each other. Each filter output is normalized by the sum of the coefficients to make it fit back into the 8-bit range. Some filters, such as an F 3  filter  62 , have a total sum of weights that is a power of 2 numbers. These filters will require no division in the normalization step as it can simply be implemented as a rounding right shift of 2. For example, the F 3  filter  62  has a total 1D weight of 1+2+1=4. A rounded division by this weight could be accomplished with an add of 2 followed by a shift right by 2.
 
normalizedResult=(sum+2)&gt;&gt;2
 
     In general, when rounding is called for, it is typically applied by adding in half the divisor prior to performing the shift. Since right shift, performed on 2&#39;s complement coded binary numbers is the equivalent of floor (numerator/2^shift), adding half the divisor causes nearest integer rounding for both signed and unsigned numerators. 
     When the total weight of a filter does not add up to a power of 2, the compute-intensive division operation is avoided by approximating it using a multiplication by ratio of two numbers, where the denominator is a chosen power-of-2 number. 
     The subsampling filters F 3 / 2  F 15 / 8  F 31 / 16  and F 63 / 32  all have power of 2 1D weights: 4,64,256 and 1024 respectively. So normalization is just a rounding right shift. The F 5  filter  64  has a 1D weight of 9 and can be approximated by multiplication by 57 prior to a rounding right shift by 9 positions. Note that multiplication of x by 57 can be done without using a variable multiply by using shift/add/sub operations such as:
 
 x* 57 =x&lt;&lt; 6 −x&lt;&lt; 3 +x 
 
     Referring to  FIGS. 6A and 6B , the MX 3  Max unit  32  used in the single channel searches for the maximum value in a 3×3 window centered on the current pixel  74  of interest. The input is an 8-bit signal. The search for the max value is performed over the 9 pixels of the 3×3 window. This gray dilation module produces an 8-bit output that is made up of the largest pixel value  76  found within the boundaries of the search window. The MX 3  max algorithm is illustrated in  FIG. 6B . 
     Referring now to  FIGS. 7A and 7B , these C 3  Contrast module  48  is designed for measuring the amount of local contrast at the input. The contrast is defined as the difference between the largest and smallest pixel values within a window centered on the current pixel  74  of interest. The C 3  Contrast unit  48  utilizes a window size of 3×3, centered on the current pixel  74  of interest. The input to the contrast units is an 8-bit signal. The contrast module  48  produces an 8-bit monochrome output (single channel)  84 . The operation of the C 3  Contrast Unit  48  is illustrated in  FIG. 7B . The operation is as following: for each pixel location, the content of a 3×3 window is independently searched for the minimum and maximum pixel values. The output contrast value is defined to be:
 
Contrast=max−min
 
     Since the largest and smallest pixel values are always between 0 and 255 for an unsigned 8-bit input signal, the contrast is guaranteed to be in the range [0 . . . 255], and no special normalization is necessary. 
     The Min-Max Detection module  32  is used for finding peaks and valleys in the input signal. By counting the number of peaks and valleys per unit area, a measure of the local frequency is obtained. 
     The MM 3  unit  32  operates on a one component gray source. The unit utilizes 3×3 window to indicate when the center pixel is at an extreme value (either peak or valley) relative to its 8 neighbors, following the logic below. The output from the Min-Max Detection unit  32  is a 1-bit signal indicating that the corresponding Src pixel is in an extreme value state (can be extended to other color channels as well). 
     The MM 3  Min-Max Detection structure is depicted in  FIG. 8 . For each pixel, the outer ring of 8 pixels surrounding it (the current pixel of interest) is first analyzed. The 8 outer pixels are further divided into two sets of 4 pixels each as shown in  FIG. 8 . The partitioning of the outer ring into two sets is useful for reducing the likelihood of false alarms in detecting straight-line segments as halftones (since most commonly encountered halftones are likely to be clustered dots). 
     For each set, the pixel values are compared among the members  78  and  86  of the set to determine the minimum and maximum values within each set independently:
 
 A   max =max ( Aij ); over all ( i,j ) belonging to the set  A 
 
 A   min =min ( Aij ); over all ( i,j ) belonging to the set  A 
 
 B   max =max ( Bij ); over all ( i,j ) belonging to the set  B 
 
 B   min =min ( Bij ); over all ( i,j ) belonging to the set  B 
 
From these, the overall outer ring and total min are computed. Using the total min and 2 configuration parameters, a noise level is then computed.
 
Noise= ConThr+X *Noise Fac /256
 
     The center pixel  74  value X is defined to be at a peak if it is [significantly] larger than the maximum pixel value of either set:
 
If [( A   max +Noise&lt; X ) AND ( B   max   ≦X )] return(1)
 
     Similarly, the center pixel  74  value X is defined to be at a valley if it is [significantly] smaller than the minimum pixel value from either set:
 
If [( A   min   &gt;X +Noise) AND ( B   min   ≧X )] return(1)
 
The above equations determine the two conditions where the output from the 3×3 detection window are set to 1; in all other cases the output will be set to 0.
 
     The single channel screen estimator module SEM makes use of a Bilinear Interpolation Unit BIU. The Bilinear Interpolation Unit interpolates (up-samples) the signal back to the source resolution. The input signals are up-sampled by a factor of 32 in each direction to restore it to the original resolution. Each interpolation unit is performing bilinear interpolation, essentially generating 32*32=1024 pixels for each original pixel. The step size of the bilinear interpolation is 1/32 nd  of the original pixel grid. The following paragraphs describe in more details Bilinear Interpolation Unit. 
     The structure of one of the Bilinear Interpolation Unit BIU  54  is shown in  FIG. 10 . The Bilinear Interpolation Unit operates on 3 signals  94 ,  96  and  98  generated in the single channel  40 . 
     As can be seen in  FIG. 10 , the Bilinear Interpolation Unit  54  is composed of two interpolation stages  100  and  102 , respectively. The first stage includes the interpolation  100  of the A 5    94  and C 5    98  inputs by 2× in each direction. The interpolation  100  uses a simple bi-linear interpolation technique. The A 5  input  94  corresponds to the output of the F 5  filter 64 units. Note the subscripts in  FIG. 10  correspond to the level of subsampling. The subscript  5  indicates that the signal has been subsampled 5 times by a factor of ½ ( 1/32 total). The C 5  input  98  corresponds to the output of the 3×3 contrast units. As indicated in  FIG. 1 , both of these inputs have been previously sub-sampled by a factor of 32× in each direction. After interpolating the A 4  and C 4  outputs, of this first stage of interpolation are subsampled by 1/16. That is the same subsampling level of the B 4  input  96 . It is now possible to compute BmA 4 , the B 4  minus A 4  difference signal  104 . BmA 3  is multiplied by the magnitude fine blend factor MFB 3  that is generated by applying C 4  to the MagFineBlenVsCon function  106 . The BmAxC 4  signal is the result of multiplying 108 BmA 4  times MFB 4  and shifting right by 8. This gets added to A 4  in  110  to create HI 4  or LO 4  signals depending on the channel. The results are then fed to the 16× bilinear interpolation unit  112  producing the Lo or Hi output depending on the channel. 
     The MagFineBlenVsCon function  106  above is a programmable function. In one embodiment, the typical MagFineBlenVsCon function  106  above can be easily computed as y=(x−16)*12 where the output is then clamped between 0 and 192. The equations below incorporate this typical configuration value of MagFineBlenVsCon  106 .
 
 BmA   4   =B   4 −A 4  
 
 MFB   4 =MagFineBlend VsCn   3 ( C   4 )=max(0, min(192,(C 4 −16)*12))
 
 BmAxC   4 =( BmA   4   *MFB   4 )&gt;&gt;8
 
The functional relationship defined above for MFB 4  is helpful in insuring the successful operation of the single channel  40 . The relationship defines a linear curve starting at 16, with a slope of 12, and cutting off to zero at 192. This relationship insures that the control signal adjusts the blend of a and b, such that as the contrast increases, the proportion of B which is derived from the MX 3   44  and is therefore a measure of the frequency occurring within a 3×3 pixel window, also increases.
 
     If the contrast is very low, the Bilinear Interpolation module outputs a signal based on the A input, which is the heavily filtered image signal. If the contrast is larger, the output signal is more weighted toward the B component, which is the frequency measurement. Therefore, the output signal Scm can be used alone, without the additional magnitude estimate, because when it is small, it indicates that a relatively small amount of halftone noise is present and a precise measurement of its frequency will not be needed by downstream processing. However, when it is larger, it is based primarily on the frequency measurement, and so it is a reliable estimate of the halftone frequency present in the image. 
     While certain exemplary embodiments have been described in detail and shown in the accompanying drawings, those of ordinary skill in the art will recognize that the invention is not limited to the embodiments described and that various modifications may be made to the illustrated and other embodiments of the invention described above, without departing from the broad inventive scope thereof. It will be understood, therefore, that the invention is not limited to the particular embodiments or arrangements disclosed, but is rather intended to cover any changes, adaptations or modifications which are within the scope and spirit of the invention as defined by the appended claims.