1. Field of the Invention
The present invention relates to helical and circular x-ray computed tomographic (CT) imaging, and in particular to CT imaging with circular reconstruction with extended volume coverage and improved dose utilization.
2. Discussion of the Background
For computed tomography (CT), there are two main types of detectors: curved and flat, as shown in
The most commonly used reconstruction algorithm for circular cone beam CT is proposed in L. A. Feldkamp, L. C. Davis and J. W. Kress, “Practical cone beam algorithm,” Journal of Optical Society of America, vol. 1 (6), pp. 612-619 (1984), hereinafter FDK. The algorithm uses full rotation of data, also called full scan (FS). Parker proposed a method where only π+FA, where FA is the Full detector fan angle opening. These parameters are not defined yet) of data angular range is used. D. Parker, “Optimal short scan convolution reconstruction for fan-beam CT,” Med. Phys., vol. 9, pp. 254-257 (1982).
The reconstruction volume for FS will be described with reference to
The volume z-coverage at the distance r from the center is given by
W is the detector half-width at center. At the center (r=0) maximum z-coverage is obtained, with H=W. Moving away from the center, z-coverage linearly reduces. Note that in the case of the full scan, z-coverage is independent of detector type, i.e., flat or curved. A reconstruction pixel has polar coordinates (r, φ). Its short scan reconstruction range, denoted [βstart, βend], is shown in
View-range endpoints are given by:
βstart(r,φ)=φ+π−Δβ(r)/2
βend(r,φ)=φ+π+Δβ(r)/2=βstart(r,φ)+Δβ(r) (3)
where Δβ(r) is the reconstruction view-range and is given by:
Δβ(r)=π+2γ(r) (4)
The volume z-coverage at the distance r from the center in case of short scan with curved detector is given by:
The volume z-coverage at the distance r from the center in case of short scan with flat detector is given by:
Volume z-coverage with different scans as a function of r is shown in
The present invention is directed to a computed-tomography method and apparatus. In one aspect, the method includes scanning an object with x-rays to obtain projection data, reconstructing a first part of an image of the object where full scan data is available, reconstructing a second part of the image using half-scanning where full scan data is not available, reconstructing a third part of the image using data extrapolated from the full scan data, combining weighted sums of overlapping portions of the second and third parts; and obtaining the image using the first to third parts and the combined weighted sums.
In another aspect, the computed-tomography apparatus includes an x-ray source, an x-ray detector, and a reconstruction processor for reconstructing an image of an subject from data collected by said x-ray detector. The processor reconstructs a first part of the image where full scan data is available, reconstructs a second part of the image using half-scanning data where full scan data is not available, reconstructs a third part of the image using data extrapolated from the full scan data, combines weighted sums of overlapping portions of the second and third parts, and reconstructs the image using the first to third parts and combined weighted sums.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
In a first embodiment of the invention, a subject is scanned in a circular trajectory for a plurality of scans to obtain circular image data over the subject. In circular scan reconstruction, the field-of-view (FOV) size in the z-direction is determined by the projection of the detector on the central axis. Typically, the volume reconstruction region with circular scanning is limited in the z-direction by the divergent x-ray beam. A divergent x-ray beam does not cover the full z-extent of the FOV on the source side, so that some corner parts of the FOV are not exposed at a particular view angle. Thus, z-coverage is maximum at the center, and reduces at the periphery, so that the reconstruction FOV has a hexagonal shape. This is shown in
Even though there is not enough data to reconstruct the corner parts of the FOV using the full-scan reconstruction, they can still be reconstructed using short-scan reconstruction. Each radial direction uses its own short-scan arc on the opposite side of the trajectory. The reconstruction according to the invention fully covers the FOV at the periphery, resulting in a full rectangular shape of reconstruction FOV and an improved image.
A first embodiment of the method according to the invention is shown in
Reconstruction in the corner regions is performed using a reconstruction process termed Pixel-Based Sector (PBS) reconstruction (described in more detail below). PBS reconstruction is used in regions 43 and 44, and extrapolated data is reconstructed in region 43. In the PBS approach, each image pixel has its own short-scan (SS) reconstruction view-range. Pixels on a radial ray share the same short scan view-range. However, in discrete image coordinates it is unlikely that any two image pixels will belong to the same radial ray, and therefore the short-scan weighting function is computed for image pixels. Such sector assignment allows the best possible data utilization and leads to improved image quality.
For slices in the FOV from z=0 up to the line shown as 46, 360 degree data is available and full scan reconstruction is used (step 31). From line 46 up to the top of the FOV, a combination of full scan, expanded full scan and PBS reconstruction are used (step 32). In the regions 43, where expanded full scan and PBS reconstruction overlap, the image subvolumes are weighted using a weighting function (step 33), which is described in more detail below. In a preferred manner, the expanded full scan and PBS reconstructed subvolumes are feathered. The image is reconstructed from the various reconstructed subvolumes and weighting (step 34).
In more detail, given a reconstruction pixel
The full-scan reconstruction region is given by:
ΩFS={(x,y,z)∥z|≦HFS(r(x,y))}, (8)
where HFS(r) is given by (1). The half-scan reconstruction region is given by:
ΩHS={(x,y,z)∥z|≦HHS-CD(r(x,y))} (9)
where HHS-CD(r) is given by (5). Note that ΩFS is a subset of ΩHS, and the extended region is given by difference
ΩEXTΩHS−ΩFS. (10)
If a reconstruction pixel belongs to the full-scan region (i.e.,
where Q0[•] is the DC-adjusted ramp convolution as described in Zamyatin et al. and L(β,
If a reconstruction pixel belongs to the extended region (i.e.,
where K[•] denotes the hybrid convolution as described in Zamyatin et al. and wN denotes [a weighting function (described in more detail below)].
The first embodiment will be described in more detail. Note that equations (3) above define a 1π view range, i.e., the minimum view range. These equations are useful to find the region where short scan reconstruction without extrapolation is possible. However, a larger short scan range (up to 2π) may be used. Including more data into reconstruction reduces noise and cone beam artifacts. Thus, the maximum short scan range as a function of image slice z-position and r is derived.
As the trajectory arc wraps around the image slice, projection cone angles increase. For given z and r the reconstruction view-range [βstart, βend] is determined by the value d, as shown in
that is, d is the shortest distance at which the source can approach the pixel (r, φ) without projecting outside of the detector. From
βstart(r,φ,z)=φ+π−Δβ(r,z)/2
βend(r,φ,z)=φ+π+Δβ(r,z)/2=βstart(r,φ,z)+Δβ(r,z) (14)
Δβ(r,z)=π+2θ (15)
Or, after some simplifications the following equations are obtained:
Δβ(r,z)=2π−2φ (18)
Each image pixel is given its own redundancy weight depending upon the position of the pixel and the source position. The commonly used FDK-type algorithm with short scan weighting applies weighting before convolution. Each pixel data needs to be convolved and back-projected. It is much more efficient if redundancy weighting is applied after convolution, as data needs to be convolved only once for all image pixels, and redundancy weighting is applied during back-projection step. In R. Grimmer, M. Oelhafen, U. Elstrom, and M. Kachelriess, CT Reconstruction with Extended z-Range, Conf. Record of IEEE NSS-MIC, October 2008, this is achieved by rebinning data to parallel geometry. In the present invention, the algorithm proposed in A. A. Zamyatin, K. Taguchi and M. D. Silver, Practical Hybrid Convolution Algorithm for Helical CT Reconstruction, IEEE Transactions on Nuclear Sciences, vol. 53, no. 1, pages 167-174, which is herein incorporated by reference, is used, which allows switching the order of weighting and convolution without rebinning to parallel geometry.
The preferred redundancy weighting function is described in F. Noo, M. Defrise, R. Clackdoyle and H. Kudo, Image reconstruction from fan-beam projections on less than a short scan, Phys. Med. Biol., 47 (2002) 2525-2546, (NDCK weight), given by
where N=1, 2, . . . is the number of 1π arcs used for image reconstruction, and the function c(β) is given by:
where σ is the smoothing interval.
Therefore, is it preferable to make σ variable, depending on the view range Δβ(r,z). If Δβ(r,z) is close to 2π, then make σ is made small, for example σ=0.05×Δβ(r,z). If, on the other hand, as Δβ(r,z) approaches Δβπ(r), then, preferably, σ→0.5×Δβ(r,z). In other words, σ can be found by:
σ=k(Δβ(r,z))×Δβ(r,z)
where kmin=0.05 and kmax=0.5.
Preferably, a pre-computed weight table is used. Finding the weight value is preferably accomplished by table look-up.
Extrapolated data is obtained outside the FS region, as shown in
Img=w×ImgExtFS+(1−w)×ImgPBS.
At the edge of the extended region with the FS region, w=1, at the edge of the extended region and the PBS region, w=0, and w smoothly varies in between. A linear or smooth nonlinear (for example polynomial 3x2−2x3, or trigonometric) function may be used. Thus, a smooth, gapless transition is obtained between the FS and PBS regions.
A second embodiment of the invention is shown in
X-ray controller 8 supplies a trigger signal to high voltage generator 7. High voltage generator 7 applies high voltage to x-ray source 3 with the timing with which the trigger signal is received. This causes x-rays to be emitted from x-ray source 3. Gantry/bed controller 9 synchronously controls the revolution of rotating ring 2 of gantry 1 and the sliding of the sliding sheet of bed 6. System controller 10 constitutes the control center of the entire system and controls x-ray controller 8 and gantry/bed controller 9 such that, as seen from the subject, x-ray source 3 executes so-called helical scanning, in which it moves along a helical path. Specifically, rotating ring 2 is continuously rotated with fixed angular speed while the sliding plate is displaced with fixed speed, and x-rays are emitted continuously or intermittently at fixed angular intervals from x-ray source 3. The source may also be scanned circularly.
The output signal of two-dimensional array type x-ray detector 5 is amplified by a data collection unit 11 for each channel and converted to a digital signal, to produce projection data. The projection data output from data collection unit 11 is fed to processing unit 12. Processing unit 12 performs various processing described above using the projection data. Unit 12 performs interpolation, backprojection and reconstruction, as described above, on the FS, extended and PBS regions to produce the improved image with full rectangular FOV. Unit 12 determines backprojection data reflecting the x-ray absorption in each voxel. In the helical scanning system using a cone-beam of x-rays, the imaging region (effective field of view) is of cylindrical shape of radius o) centered on the axis of revolution. Unit 12 defines a plurality of voxels (three-dimensional pixels) in this imaging region, and finds the backprojection data for each voxel. The three-dimensional image data or tomographic image data compiled by using this backprojection data is sent to display device 14, where it is displayed visually as a three-dimensional image or tomographic image.
An example of the invention is shown in
Another example is shown in
The invention may also be embodied in the form a computer-readable medium containing a stored program to cause a computer to carry out the various operations and functions described above.
Numerous other modifications and variations of the present invention are possible in light of the above teachings. This document and equations have been developed for a curved detector array. For example, a flat or other detector array shape can be implemented. Images can be reconstructed either in native cone-beam (CB) or rebinned cone-parallel (CP) geometry. CP geometry offers computational simplicity, but loses spatial resolution due to the additional re-sampling step that uses interpolated data. Using CB geometry better preserves the spatial resolution.
It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.
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6282256 | Grass et al. | Aug 2001 | B1 |
20100283779 | Chiang et al. | Nov 2010 | A1 |
Number | Date | Country |
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WO 2008064367 | May 2008 | WO |
Number | Date | Country | |
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20110103662 A1 | May 2011 | US |