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Super-resolution MRI Using Finite Rate of Innovation Curves Greg Ongie*, Mathews Jacob Computational Biomedical Imaging Group (CBIG) University of Iowa.

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Presentation on theme: "Super-resolution MRI Using Finite Rate of Innovation Curves Greg Ongie*, Mathews Jacob Computational Biomedical Imaging Group (CBIG) University of Iowa."— Presentation transcript:

1 Super-resolution MRI Using Finite Rate of Innovation Curves Greg Ongie*, Mathews Jacob Computational Biomedical Imaging Group (CBIG) University of Iowa ISBI 2015 New York City

2 1. Introduction 2. Off-the-Grid Image Recovery: New Framework 3. Algorithms 4. Experiments 5. Discussion & Conclusion

3 Our goal is to develop theory and algorithms for off-the-grid imaging Off-the-grid = Continuous domain representation Avoids discretization errors Continuous domain sparsity Discrete domain sparsity Few measurements

4 SR MRI: k-space undersampling approach – Modalites: Multi-slice, Dynamic, MRSI CS MRI Outside MRI: Deconvolution Microscopy, Denoising, etc. interpolation extrapolation Wide-range of applications vs.

5 Main inspiration: Finite-Rate-of-Innovation (FRI) Uniform Fourier samples Off-the-grid PWC signal Recent extension to 2-D images: Pan et al. (2014), “Sampling Curves with FRI”

6 Annihilation Relation: spatial domain multiplication annihilating function annihilating filter convolution Fourier domain

7 annihilating function annihilating filter Stage 1: solve linear system for filter recover signal Stage 2: solve linear system for amplitudes

8 Isolated Diracs Extensions of FRI recovery to higher dimensions is non-trivial! 2-D PWC function Diracs on a Curve

9 1. Introduction 2. Off-the-Grid Image Recovery: New Framework 3. Algorithms 4. Experiments 5. Discussion & Conclusion

10 spatial domain Fourier domain multiplication annihilating function annihilating filter convolution Recall 1-D Case…

11 2-D PWC functions satisfy an annihilation relation spatial domain Annihilation relation: Fourier domain multiplication annihilating filter convolution

12 Can recover edge set when it is the level-set of a 2-D bandlimited function (Pan et al., 2014) “FRI Curve”

13 21x21 coefficients 13x13 coefficients Multiple curves & intersections Non-smooth points Approximate complex curves 7x9 coefficients FRI curves can represent complicated edge geometries

14 Pan et al. (2014): 2-D only No uniqueness guarantees New formulation: Extends to n-D Provable uniqueness Fewer samples We give an improved theoretical framework for higher dimensional FRI recovery PW complex analytic PW constant/polynomial

15 Sampling guarantees for unique edge set recovery Theorem: If the level-set function is bandlimited to we can recover it uniquely from Fourier samples in Necessary Sufficient

16 1. Introduction 2. Off-the-Grid Image Recovery: New Framework 3. Algorithms 4. Experiments 5. Discussion & Conclusion

17 LR INPUT Two-stage SR MRI recovery scheme: 1. Recover edge set Off-the-grid HR OUTPUT Extrapolate k-space 2. Recover amplitudes

18 LR INPUT Two-stage SR MRI recovery scheme: Off-the-grid 1. Recover edge set 2. Recover amplitudes Computational Challenge! Off-the-grid Spatial Domain Recovery Discretize HR OUTPUT 2. Recover amplitudes On-the-grid

19 1. Spurious zeros / model order selection 2. Sensitivity to noise / model-mismatch Practical difficulties to recovery of annihilating filter/edge set

20 Matrix representation of annihilation 2-D convolution matrix (block Toeplitz) 2(#shifts) x (filter size) gridded center k-space samples vector of filter coefficients

21 Annihilation matrix is typically low-rank Prop: If the level-set function is bandlimited to and the assumed filter support then Spatial domain Fourier domain

22 1. Compute SVD Stage 1: Robust annihilting filter estimation Average over entire null-space Eliminates spurious zeros / improves robustness Generalizes Spectral MUSIC 3. Compute sum-of-squares average Recover common zeros 2. Identify null space

23 Stage 2: Weighted TV Recovery discretize relax x = discrete spatial domain image A = Fourier undersampling operator D = discrete gradient b = k-space samples Edge wts. If f is PWC with edges then it is a minimizer of: Annihilation relation

24 1. Introduction 2. Off-the-Grid Image Recovery: New Framework 3. Algorithms 4. Experiments 5. Discussion & Conclusion

25 Recovery of Phantoms (Noiseless) Analytical phantoms from (Guerquin-Kern, 2012) x8 x4

26 Recovery of Phantoms (Noisy) 25dB complex AWGN added to k-space x8 x4

27 Recovery of Real MR Data Simulated Single Coil Acquisition (8 Coil SENSE w/phase) x2

28 1. Introduction 2. Off-the-Grid Image Recovery: New Framework 3. Algorithms 4. Experiments 5. Discussion & Conclusion

29 Entirely off the grid Extends to CS paradigm Fast algorithm Use regularization penalty for other inverse problems  off-the-grid alternative to TV, HDTV, etc We can pose recovery as a structured low-rank matrix completion problem [*] or Data Consistency Regularization penalty [*]Accepted to SampTA 2015

30 20-fold accel.

31 Summary New framework for off-the-grid image recovery – Piecewise polynomial signal model – Extends easily to n-D – Sampling guarantees Two stage recovery scheme for SR MRI – Robust edge mask estimation – Fast weighted TV algorithm – Better performance than standard TV Novel Fourier domain low-rank prior – Convex, Off-the-Grid, & widely applicable WTV

32 Thank You! Acknowledgements Supported by grants: NSF CCF-0844812, NSF CCF-1116067, NIH 1R21HL109710-01A1, ACS RSG-11-267-01-CCE, and ONR-N000141310202. References Pan, H., Blu, T., & Dragotti, P. L. (2014). Sampling curves with finite rate of innovation. Signal Processing, IEEE Transactions on, 62(2), 458-471. Guerquin-Kern, M., Lejeune, L., Pruessmann, K. P., & Unser, M. (2012). Realistic analytical phantoms for parallel Magnetic Resonance Imaging.Medical Imaging, IEEE Transactions on, 31(3), 626-636 Ongie, G., & Mathews, J. (2015) Recovery of Piecewise Smooth Images from Few Fourier Samples. SampTA 2015, to appear.

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