Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Rapid Computation of LROC Figures of Merit Using Numerical Observers (for SPECT/PET Reconstruction).

Literature DB >> 20442799

Rapid Computation of LROC Figures of Merit Using Numerical Observers (for SPECT/PET Reconstruction).

Abstract

The assessment of PET and SPECT image reconstructions by image quality metrics is typically time consuming, even if methods employing model observers and samples of reconstructions are used to replace human testing. We consider a detection task where the background is known exactly and the signal is known except for location. We develop theoretical formulae to rapidly evaluate two relevant figures of merit, the area under the LROC curve and the probability of correct localization. The formulae can accommodate different forms of model observer. The theory hinges on the fact that we are able to rapidly compute the mean and covariance of the reconstruction. For four forms of model observer, the theoretical expressions are validated by Monte Carlo studies for the case of MAP (maximum a posteriori) reconstruction. The theory method affords a 10(2) - 10(3) speedup relative to methods in which model observers are applied to sample reconstructions.

Entities: Species

Year: 2003 PMID： 20442799 PMCID： PMC2862501 DOI： 10.1109/TNS.2005.851458

Source DB: PubMed Journal: IEEE Trans Nucl Sci ISSN： 0018-9499 Impact factor: 1.679

15 in total

Rapid Computation of LROC Figures of Merit Using Numerical Observers (for SPECT/PET Reconstruction).

1. A theoretical study of the contrast recovery and variance of MAP reconstructions from PET data.

2. Resolution and noise properties of MAP reconstruction for fully 3-D PET.

3. Theoretical study of lesion detectability of MAP reconstruction using computer observers.

4. Performance evaluation of a modular gamma camera using a detectability index.

5. Theoretical evaluation of the detectability of random lesions in Bayesian emission reconstruction.

6. Analysis of lesion detectability in Bayesian emission reconstruction with nonstationary object variability.

7. Noise properties of the EM algorithm: I. Theory.

8. Spatial resolution properties of penalized-likelihood image reconstruction: space-invariant tomographs.

9. Noise analysis of MAP-EM algorithms for emission tomography.

10. Addition of a channel mechanism to the ideal-observer model.

1. Fast LROC analysis of Bayesian reconstructed emission tomographic images using model observers.

2. Fast predictions of variance images for fan-beam transmission tomography with quadratic regularization.

3. Analysis of observer performance in unknown-location tasks for tomographic image reconstruction.

4. Effect of Using 2mm Voxels on Observer Performance for PET Lesion Detection.

5. Regularization design in penalized maximum-likelihood image reconstruction for lesion detection in 3D PET.

6. Effect of Scan Time on Oncologic Lesion Detection in Whole-Body PET.

7. SPECT system optimization against a discrete parameter space.

8. Effect of varying number of OSEM subsets on PET lesion detectability.

Review 9. Model observers in medical imaging research.