Difference between revisions of "3D Reslicing using COMKAT image tool (basic)"
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| − | ====Approach I. Demonstrate coordinate transformations==== | + | ====Approach I. Demonstrate the method for coordinate transformations==== |
Load a file using COMKAT image tool and use the functions to translate and rotate the image volume as you desire. | Load a file using COMKAT image tool and use the functions to translate and rotate the image volume as you desire. | ||
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| − | ====Approach II. Use coordinateGen() to do the coordinate transformation | + | ====Approach II. Use coordinateGen() to do the coordinate transformation==== |
* This should create same result as approach I but require fewer lines of coding since coordinateGen() does most things that are needed. | * This should create same result as approach I but require fewer lines of coding since coordinateGen() does most things that are needed. | ||
Revision as of 23:28, 7 August 2012
Reslicing 3D image volume using COMKAT image tool (basic)
Overview
Reslicing a 3D (or 3D vs time) image dataset can be accomplished using the COMKAT image tool and sliceVolume(). This example explains how to create image slices from a volume in at a position, plane orientation, and magnification. The approach is to load the image volume dataset into an instance if an ImageVolumeData (abbreviated IVD) object and to use the sliceVolume() method.
Background
sliceVolume() is a mex-file written in c with an interface to MATLAB that makes the operation particularly efficient. COMKATImageTool uses sliceVolume() and you can use it too.
Approach I. Demonstrate the method for coordinate transformations
Load a file using COMKAT image tool and use the functions to translate and rotate the image volume as you desire.
ivd = ImageVolumeData();
Read data to ivd, e.g. read_DICOM()
ivd = read_DICOM(ivd, pathName, fileName); % load volume into an instance of IVD object;
Create a list of indicies of all pixels in slice that we are creating
[i, j] = meshgrid(0 : Nc-1, 0 : Nr-1); ij = [c(:)’ ; r(:)’]; % make matrix, each column corresponding to a single pixel in the slice we are creating
Specify the transformation matrix based on desired pixel spacing (zoom), position (location), orientation. ref [1] p. 275
M = ( Insert the method for generating the transformation matrix );
Calculate physical (mm) location of each pixel in the desired slice
xyz = M * ij;
Specify the reverse mapping matrix ( xyz --> index space of the original image volume )
Mhat = ( Insert the method for generate the mapping);
Calculate voxel indcies into the volume corresponding to xyz physical location
uvw = Mhat * xyz;
Use sliceVolume() to interpolate the slice
slice = sliceVolume(idv, v, u, w, backgroundPixelValue, ‘linear);
Display new slice
figure, imagesc(slice); axis image % isotropic
Approach II. Use coordinateGen() to do the coordinate transformation
- This should create same result as approach I but require fewer lines of coding since coordinateGen() does most things that are needed.
Read the image volume into an ImageVolumeData object
ivd = ( Insert the method for reading data );
Use coordinateGen() to generate uvw
[u, v, w] = coordinateGen(ivd, Nc, Nr, pixelSpacing, planePos, orientation); % Input the desired pixelSpacing, planePos and orientation matrices
Use sliceVolume() to interpolate
slice = sliceVolume(idv, v, u, w, backgroundPixelValue, ‘linear);
Display slice
figure, imagesc(slice); axis image % isotropic