A New Sense for Depth of Field
IEEE Transactions on Pattern Analysis and Machine Intelligence
Visual reconstruction
An Investigation of Methods for Determining Depth from Focus
IEEE Transactions on Pattern Analysis and Machine Intelligence
Three-dimensional computer vision: a geometric viewpoint
Three-dimensional computer vision: a geometric viewpoint
Depth from defocus: a spatial domain approach
International Journal of Computer Vision
IEEE Transactions on Pattern Analysis and Machine Intelligence
International Journal of Computer Vision
Rational Filters for Passive Depth from Defocus
International Journal of Computer Vision
Depth from defocus estimation in spatial domain
Computer Vision and Image Understanding
Optimization by Vector Space Methods
Optimization by Vector Space Methods
Computer Vision: A Modern Approach
Computer Vision: A Modern Approach
Observing Shape from Defocused Images
International Journal of Computer Vision
ECCV '02 Proceedings of the 7th European Conference on Computer Vision-Part II
Optimal Selection of Camera Parameters for Recovery of Depth from Defocused Images
CVPR '97 Proceedings of the 1997 Conference on Computer Vision and Pattern Recognition (CVPR '97)
Minimal operator set for passive depth from defocus
CVPR '96 Proceedings of the 1996 Conference on Computer Vision and Pattern Recognition (CVPR '96)
A block shift-variant blur model for recovering depth from defocused images
ICIP '95 Proceedings of the 1995 International Conference on Image Processing (Vol. 3)-Volume 3 - Volume 3
ICCV '99 Proceedings of the International Conference on Computer Vision-Volume 2 - Volume 2
The Optimal Axial Interval in Estimating Depth from Defocus
ICCV '99 Proceedings of the International Conference on Computer Vision-Volume 2 - Volume 2
Optimal Recovery of Depth from Defocused Images Using an MRF Model
ICCV '98 Proceedings of the Sixth International Conference on Computer Vision
An Invitation to 3-D Vision: From Images to Geometric Models
An Invitation to 3-D Vision: From Images to Geometric Models
Projection defocus analysis for scene capture and image display
ACM SIGGRAPH 2006 Papers
On defocus, diffusion and depth estimation
Pattern Recognition Letters
Focus Area Extraction by Blind Deconvolution for Defining Regions of Interest
IEEE Transactions on Pattern Analysis and Machine Intelligence
International Journal of Computer Vision
Augmented reality based on estimation of defocusing and motion blurring from captured images
ISMAR '06 Proceedings of the 5th IEEE and ACM International Symposium on Mixed and Augmented Reality
Discontinuity-Adaptive Shape from Focus Using a Non-convex Prior
Proceedings of the 31st DAGM Symposium on Pattern Recognition
Real Aperture Axial Stereo: Solving for Correspondences in Blur
Proceedings of the 31st DAGM Symposium on Pattern Recognition
A framework for modeling 3D scenes using pose-free equations
ACM Transactions on Graphics (TOG)
Restoration of images with piecewise space-variant blur
SSVM'07 Proceedings of the 1st international conference on Scale space and variational methods in computer vision
Evolving measurement regions for depth from defocus
ACCV'07 Proceedings of the 8th Asian conference on Computer vision - Volume Part II
A nonparametric learning approach to range sensing from omnidirectional vision
Robotics and Autonomous Systems
Single image defocus map estimation using local contrast prior
ICIP'09 Proceedings of the 16th IEEE international conference on Image processing
A novel iterative shape from focus algorithm based on combinatorial optimization
Pattern Recognition
Coded Aperture Pairs for Depth from Defocus and Defocus Deblurring
International Journal of Computer Vision
Reconstruction of 3d surface from 2d images using five lighting sources
Machine Graphics & Vision International Journal
Defocus map estimation from a single image
Pattern Recognition
Depth estimation using shifted digital still camera
Proceedings of the 12th International Conference on Computer Systems and Technologies
Rational filter design for depth from defocus
Pattern Recognition
Structure from motion and photometric stereo for dense 3D shape recovery
ICIAP'11 Proceedings of the 16th international conference on Image analysis and processing: Part I
Depth recovery from motion and defocus blur
ICIAR'06 Proceedings of the Third international conference on Image Analysis and Recognition - Volume Part II
Perceptual depth estimation from a single 2d image based on visual perception theory
PCM'06 Proceedings of the 7th Pacific Rim conference on Advances in Multimedia Information Processing
Towards Unrestrained Depth Inference with Coherent Occlusion Filling
International Journal of Computer Vision
Single image blind deconvolution with higher-order texture statistics
Proceedings of the 2010 international conference on Video Processing and Computational Video
Fast restoration of nonuniform blurred images
IScIDE'12 Proceedings of the third Sino-foreign-interchange conference on Intelligent Science and Intelligent Data Engineering
Depth recovery from a single defocused image based on depth locally consistency
Proceedings of the Fifth International Conference on Internet Multimedia Computing and Service
Optimized aperture shapes for depth estimation
Pattern Recognition Letters
Robust depth sensing with adaptive structured light illumination
Journal of Visual Communication and Image Representation
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We introduce a novel approach to shape from defocus, i.e., the problem of inferring the three-dimensional (3D) geometry of a scene from a collection of defocused images. Typically, in shape from defocus, the task of extracting geometry also requires deblurring the given images. A common approach to bypass this task relies on approximating the scene locally by a plane parallel to the image (the so-called equifocal assumption). We show that this approximation is indeed not necessary, as one can estimate 3D geometry while avoiding deblurring without strong assumptions on the scene. Solving the problem of shape from defocus requires modeling how light interacts with the optics before reaching the imaging surface. This interaction is described by the so-called point spread function (PSF). When the form of the PSF is known, we propose an optimal method to infer 3D geometry from defocused images that involves computing orthogonal operators which are regularized via functional singular value decomposition. When the form of the PSF is unknown, we propose a simple and efficient method that first learns a set of projection operators from blurred images and then uses these operators to estimate the 3D geometry of the scene from novel blurred images. Our experiments on both real and synthetic images show that the performance of the algorithm is relatively insensitive to the form of the PSF. Our general approach is to minimize the Euclidean norm of the difference between the estimated images and the observed images. The method is geometric in that we reduce the minimization to performing projections onto linear subspaces, by using inner product structures on both infinite and finite-dimensional Hilbert spaces. Both proposed algorithms involve only simple matrix-vector multiplications which can be implemented in real-time.