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How can someone use Qt for image processing? Are there libraries or plugins for Qt for this purpose?

Thanks.

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3 Answers

up vote 8 down vote accepted

Qt is rather meant for developing graphical user interfaces (GUIs). However, it comes with a lot of supplementary libraries, including one dedicated to image processing. However, if you want to get serious, I would recommend a dedicated library such as OpenCV.

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Thankd for your reply. Is there a difference between computer vision and image processing? Does OpenCV work well for image processing operations? –  Simplicity Feb 25 '11 at 20:10
    
Well, I guess that purists would say that there is a clear difference between the two, but really it's the same field. You might say that image processing focuses more on offline (i.e., not real-time), and often 2-d images whereas computer vision is concerned with real-time and 3-d images. But that's really just nitpicking. OpenCV provides a lot of interesting methods for both fields. –  Greg Feb 25 '11 at 20:17
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Greg is wrong, there is a massive difference between computer vision and image processing. I'm not nitpicking; please read up on CV or ask another question. –  koan Jan 12 '12 at 12:12
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I did use Qt for GUI plus LTIlib for image processing.

Qt itself won't be very helpful for processing any image, but there are a couple of independent libraries that you can use best fitting your needs. Bear in mind that Qt is essentially meant to be a GUI framework. It is very very good, if not the best, to make windows, buttons, tree views, etc. but don't expect it to be so comprehensive that can do everything.

Please let us to know more preciselly what you mean when you say "image processing". It is a vast reign with hundreds or thousands of possible goals and approaches...

EDIT:

Here is a small excerpt or what I used to do with Qt+LTI. See LTI documentation for all operators available. I used to do convolutions, self-correlations, basic erosion/dilation and a lot more.

#include    <ltiDilation.h>
#include    <ltiErosion.h>

#include    <ltiBinaryKernels.h>

#include    <ltiFastRelabeling.h>
#include    <ltiLabelAdjacencyMap.h>

void QLTIDialog::init()
{
    viewLayout = new QGridLayout( frmView, 1, 1, 4, 4, "viewLayout" );

    view= new QImageLabel( frmView, "view" );
    viewLayout->addWidget( view, 0, 0 );

    frmView->setUpdatesEnabled( false );

    view->image( &qimg );
}


void QLTIDialog::btnOpen_clicked()
{
    QString fn= QFileDialog::getOpenFileName(
                    "",
                    tr( "All files (*.*)" ),
                    this,
                    tr( "Open image" ),
                    tr( "Select image file" ) );
    if ( !fn.isEmpty(  ) )
    {
        if ( !qimg.load( fn ) )
        {
            QMessageBox::critical( this, tr( "Fatal error" ),
                QString( tr( "Unable to open %1" ) ).arg( fn ),
                tr( "Exit" ) );

            return;
        }

        view->update(  );

        setCaption( fn );
    }
}


void QLTIDialog::btnProcess_clicked()
{
    lti::image      img;
    lti::channel8   tmp0,
                    h, s, v;

    // Taking QImage data, as in the wiki.
    img.useExternData( qimg.width(  ), qimg.height(  ), ( lti::rgbPixel * )qimg.bits(  ) );

    // Converting to HSV gives-me best results, but it can be left out.
    lti::splitImageToHSV    hsv;
    hsv.apply( img, h, s, v );

    // I do some manipulation over the channels to achieve my objects positions.
    lti::maskFunctor< lti::channel8::value_type > masker;
    masker.invert( v, tmp0 );
    masker.algebraicSum( s, tmp0 );

    // Show the resulting processed image (ilustrative)...
    QLTIDialog  *dh= new QLTIDialog;
    dh->showImage( tmp0 );

    // Apply relabeling (example). Any other operator can be used.
    lti::fastRelabeling::parameters flPar;
    flPar.sortSize= true;
    flPar.minimumObjectSize= 25;
    flPar.fourNeighborhood= true;
    flPar.minThreshold= 40;
    lti::fastRelabeling fr( flPar );
    fr.apply( tmp0 );

    lti::image              imgLam;
    lti::labelAdjacencyMap  lam;
    lam.apply( tmp0, imgLam );

    // By hand copy to QImage.
    lti::image::iterator iit= imgLam.begin(  );
    lti::rgbPixel   *pix= ( lti::rgbPixel * )qimg.bits(  );
    for ( ; iit != imgLam.end(  ); ++iit, ++pix )
        *pix= *iit;

    view->update(  );
}


void QLTIDialog::showImage( lti::image &img )
{
    qimg= QImage( reinterpret_cast< uchar * >( &( *img.begin(  ) ) ),
                    img.rows(  ), img.columns(  ), 32, ( QRgb * )NULL,
                    0, QImage::LittleEndian ).copy(  );

    QDialog::show(  );
}


void QLTIDialog::showImage( lti::channel8 &ch )
{
    lti::image  img;
    img.castFrom( ch );

    qimg= QImage( reinterpret_cast< uchar * >( &( *img.begin(  ) ) ),
                    img.rows(  ), img.columns(  ), 32, ( QRgb * )NULL,
                    0, QImage::LittleEndian ).copy(  );

    QDialog::show(  );
}

EDIT Again:

I found another sample that may be more interesting to you...

lti::image      img;
lti::channel8   chnl8( false, imgH, imgW ), h, s, v;

// Pass image data to LTI.
img.useExternData( imgH, imgW, ( lti::rgbPixel * )pixels );

// I got better results in HSV for my images.
lti::splitImageToHSV    hsv;
hsv.apply( img, h, s, v );

// Segmentation.
lti::channel8::iterator it= chnl8.begin(  );
lti::channel8::iterator hit= h.begin(  ),
            sit= s.begin(  ),
            vit= v.begin(  );

for ( ; it != chnl8.end(  ); ++it, ++hit, ++sit, ++vit )
{
    int tmp= *sit * 2;
    tmp-=   *hit - 320 + *vit;
    *it= ( *hit > 40 && tmp > 460 ? 1 : 0 );
}

// Distinguish connected objects.
lti::imatrix    objs;

std::vector< lti::geometricFeatureGroup0 >  objF;

lti::geometricFeaturesFromMask::parameters  gfPar;
gfPar.merge=            true;   // Join close objects.
gfPar.minimumDistance=  lti::point( 24, 24 );
gfPar.minimumMergedObjectSize=  2;  // Exclude small ones.
gfPar.nBest=            800;    // Limit no. of objects.

lti::geometricFeaturesFromMask  gf( gfPar );
gf.apply( chnl8, objs, objF );

points.clear(  );

for( std::vector< lti::geometricFeatureGroup0 >::const_iterator gfg0= objF.begin(  );
        gfg0 != objF.end(  ); ++gfg0 )
    points.push_back( Point( gfg0->cog.x, gfg0->cog.y ) );

The rest is like the first example. Hope it helps.

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I'm interested in feature extraction –  Simplicity Feb 26 '11 at 13:11
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Image processing is a rather generic term. Have a look at VTK and ITK from Kitware. Also Freemat (a Matlab clone) is based on Qt. Qt is popular among quantitative scientists, I expect that there quite a few Qt-based imaging libraries and products.

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VTK is meant for data vizualization, not image processing. ITK might come in handy indeed, but it is more specialized than OpenCV. –  Greg Feb 25 '11 at 20:19
    
Greg, I agree with all you are saying, my answer above is not great. –  radim Feb 25 '11 at 20:29
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