NAME

Image::Leptonica::Func::baseline

VERSION

version 0.04

baseline.c

baseline.c

    Locate text baselines in an image
         NUMA     *pixFindBaselines()

    Projective transform to remove local skew
         PIX      *pixDeskewLocal()

    Determine local skew
         l_int32   pixGetLocalSkewTransform()
         NUMA     *pixGetLocalSkewAngles()

We have two apparently different functions here:
  - finding baselines
  - finding a projective transform to remove keystone warping
The function pixGetLocalSkewAngles() returns an array of angles,
one for each raster line, and the baselines of the text lines
should intersect the left edge of the image with that angle.

FUNCTIONS

pixDeskewLocal

PIX * pixDeskewLocal ( PIX *pixs, l_int32 nslices, l_int32 redsweep, l_int32 redsearch, l_float32 sweeprange, l_float32 sweepdelta, l_float32 minbsdelta )

pixDeskewLocal()

    Input:  pixs
            nslices  (the number of horizontal overlapping slices; must
                be larger than 1 and not exceed 20; use 0 for default)
            redsweep (sweep reduction factor: 1, 2, 4 or 8;
                      use 0 for default value)
            redsearch (search reduction factor: 1, 2, 4 or 8, and
                       not larger than redsweep; use 0 for default value)
            sweeprange (half the full range, assumed about 0; in degrees;
                        use 0.0 for default value)
            sweepdelta (angle increment of sweep; in degrees;
                        use 0.0 for default value)
            minbsdelta (min binary search increment angle; in degrees;
                        use 0.0 for default value)
    Return: pixd, or null on error

Notes:
    (1) This function allows deskew of a page whose skew changes
        approximately linearly with vertical position.  It uses
        a projective tranform that in effect does a differential
        shear about the LHS of the page, and makes all text lines
        horizontal.
    (2) The origin of the keystoning can be either a cheap document
        feeder that rotates the page as it is passed through, or a
        camera image taken from either the left or right side
        of the vertical.
    (3) The image transformation is a projective warping,
        not a rotation.  Apart from this function, the text lines
        must be properly aligned vertically with respect to each
        other.  This can be done by pre-processing the page; e.g.,
        by rotating or horizontally shearing it.
        Typically, this can be achieved by vertically aligning
        the page edge.

pixFindBaselines

NUMA * pixFindBaselines ( PIX *pixs, PTA **ppta, l_int32 debug )

pixFindBaselines()

    Input:  pixs (1 bpp)
            &pta (<optional return> pairs of pts corresponding to
                  approx. ends of each text line)
            debug (usually 0; set to 1 for debugging output)
    Return: na (of baseline y values), or null on error

Notes:
    (1) Input binary image must have text lines already aligned
        horizontally.  This can be done by either rotating the
        image with pixDeskew(), or, if a projective transform
        is required, by doing pixDeskewLocal() first.
    (2) Input null for &pta if you don't want this returned.
        The pta will come in pairs of points (left and right end
        of each baseline).
    (3) Caution: this will not work properly on text with multiple
        columns, where the lines are not aligned between columns.
        If there are multiple columns, they should be extracted
        separately before finding the baselines.
    (4) This function constructs different types of output
        for baselines; namely, a set of raster line values and
        a set of end points of each baseline.
    (5) This function was designed to handle short and long text lines
        without using dangerous thresholds on the peak heights.  It does
        this by combining the differential signal with a morphological
        analysis of the locations of the text lines.  One can also
        combine this data to normalize the peak heights, by weighting
        the differential signal in the region of each baseline
        by the inverse of the width of the text line found there.
    (6) There are various debug sections that can be turned on
        with the debug flag.

pixGetLocalSkewAngles

NUMA * pixGetLocalSkewAngles ( PIX *pixs, l_int32 nslices, l_int32 redsweep, l_int32 redsearch, l_float32 sweeprange, l_float32 sweepdelta, l_float32 minbsdelta, l_float32 *pa, l_float32 *pb )

pixGetLocalSkewAngles()

    Input:  pixs
            nslices  (the number of horizontal overlapping slices; must
                be larger than 1 and not exceed 20; use 0 for default)
            redsweep (sweep reduction factor: 1, 2, 4 or 8;
                      use 0 for default value)
            redsearch (search reduction factor: 1, 2, 4 or 8, and
                       not larger than redsweep; use 0 for default value)
            sweeprange (half the full range, assumed about 0; in degrees;
                        use 0.0 for default value)
            sweepdelta (angle increment of sweep; in degrees;
                        use 0.0 for default value)
            minbsdelta (min binary search increment angle; in degrees;
                        use 0.0 for default value)
            &a (<optional return> slope of skew as fctn of y)
            &b (<optional return> intercept at y=0 of skew as fctn of y)
    Return: naskew, or null on error

Notes:
    (1) The local skew is measured in a set of overlapping strips.
        We then do a least square linear fit parameters to get
        the slope and intercept parameters a and b in
            skew-angle = a * y + b  (degrees)
        for the local skew as a function of raster line y.
        This is then used to make naskew, which can be interpreted
        as the computed skew angle (in degrees) at the left edge
        of each raster line.
    (2) naskew can then be used to find the baselines of text, because
        each text line has a baseline that should intersect
        the left edge of the image with the angle given by this
        array, evaluated at the raster line of intersection.

pixGetLocalSkewTransform

l_int32 pixGetLocalSkewTransform ( PIX *pixs, l_int32 nslices, l_int32 redsweep, l_int32 redsearch, l_float32 sweeprange, l_float32 sweepdelta, l_float32 minbsdelta, PTA **pptas, PTA **pptad )

pixGetLocalSkewTransform()

    Input:  pixs
            nslices  (the number of horizontal overlapping slices; must
                be larger than 1 and not exceed 20; use 0 for default)
            redsweep (sweep reduction factor: 1, 2, 4 or 8;
                      use 0 for default value)
            redsearch (search reduction factor: 1, 2, 4 or 8, and
                       not larger than redsweep; use 0 for default value)
            sweeprange (half the full range, assumed about 0; in degrees;
                        use 0.0 for default value)
            sweepdelta (angle increment of sweep; in degrees;
                        use 0.0 for default value)
            minbsdelta (min binary search increment angle; in degrees;
                        use 0.0 for default value)
            &ptas  (<return> 4 points in the source)
            &ptad  (<return> the corresponding 4 pts in the dest)
    Return: 0 if OK, 1 on error

Notes:
    (1) This generates two pairs of points in the src, each pair
        corresponding to a pair of points that would lie along
        the same raster line in a transformed (dewarped) image.
    (2) The sets of 4 src and 4 dest points returned by this function
        can then be used, in a projective or bilinear transform,
        to remove keystoning in the src.

AUTHOR

Zakariyya Mughal <zmughal@cpan.org>

COPYRIGHT AND LICENSE

This software is copyright (c) 2014 by Zakariyya Mughal.

This is free software; you can redistribute it and/or modify it under the same terms as the Perl 5 programming language system itself.