| |
|
|
09:30 - 09:50
|
Refreshments and tagging
|
| |
|
|
09:50 - 10:00
|
Greetings :
Ohad Ben-Shahar , Ben Gurion University
|
| |
|
|
10:00 - 10:50
|
Joseph Francos,
Ben-Gurion University
A Universal and Exact Linear Framework for Estimation, Registration and Recognition of Deformable Objects
|
|
|
We consider the problem of estimating the geometric
deformation of an object, with respect to some reference observation
on it. Existing solutions, set in the standard coordinate system
imposed by the measurement system, lead to high-dimensional,
non-convex optimization problems. We propose a novel framework that
employs a set of non-linear functionals to replace this originally
high dimensional problem by an equivalent problem that is
linear in the unknown transformation parameters.
The proposed solution is unique and exact and is applicable to any elastic or affine transformation
regardless of its magnitude.
By analyzing the stochastic properties of the proposed non-linear functionals in the presence of various error
sources, optimal estimators of the deformation models are derived.
|
| |
|
|
10:50 - 11:40
|
Ariel Shamir,
Interdisciplinary Center
Sketch2Photo: Internet Image Montage
|
|
|
We present a system that composes a realistic picture from a simple
freehand sketch annotated with text labels. The composed picture
is generated by seamlessly stitching several photographs in agreement
with the sketch and text labels; these are found by searching
the Internet. Although online image search generates many inappropriate
results, our system is able to automatically select suitable
photographs to generate a high quality composition, using a filtering
scheme to exclude undesirable images. We also provide a novel
image blending algorithm to allow seamless image composition.
Each blending result is given a numeric score, allowing us to find
an optimal combination of discovered images. Experimental results
show the method is very successful; we also evaluate our system using
the results from two user studies.
Joint work with:
Tao Chen, Ming-Ming Cheng, and Shi-Min Hu from Tsinghua University
and Ping Tan from National University of Singapore
|
| |
|
|
11:40 - 12:30
|
Nathan Intrator,
Tel-Aviv University
Mosaicing and Super Resolution of Sonar Images
|
|
|
Sonar systems generate noisy low resolution images. Creating a mosaic from multiple images
is thus, far more difficult than in regular video cameras.
In this talk I will present some aspects of the process of building super
resolution and mosaiced images Using computer vision and robust statistics tools.
|
| |
|
|
12:30 - 13:30
|
Lunch
|
| |
|
|
13:30 - 14:20
|
Michael Lindenbaum,
Technion
Unsupervised estimation of segmentation quality using nonnegative matrix factorization
|
|
|
Common segmentation evaluation methods are typically based on evaluating smoothness
within segments and contrast between them, and the measure they provide is
not explicitly related to segmentation errors. The proposed approach differs
from these methods on several important points and has several advantages
over them. First, it provides a meaningful, quantitative assessment of
segmentation quality, in precision/recall terms, which were applicable so
far only for supervised evaluation. Second, it builds on a new image model,
which characterizes the segments as a mixture of basic feature
distributions. The precision/recall estimates are then obtained by a
nonnegative matrix factorization (NMF) process. A third important advantage
is that the estimates, which are based on intrinsic properties of the
specific image being evaluated and not on a comparison to typical images
(learning), are relatively robust to context factors such as image quality
or the presence of texture. Experimental results demonstrate the accuracy of
the precision/recall estimates in comparison to ground truth based on human
judgment. Moreover, it is shown that tuning a segmentation algorithm using
the unsupervised measure improves the algorithm's quality (as measured by a
supervised method).
|
| |
|
|
14:20 - 15:10
|
Ronen Segev,
Ben-Gurion University
Encoding of color information - Insights from biology
|
|
|
As we look around in order to grasp the colors of different objects, optical signals that reach our
retina are encoded by the retinal ganglion cells, the only cells to project axons from the retina
to the brain, into sequences of action potentials. These pulses transmit information about the
spectral properties of light arriving at the eye to the brain. Indeed, during many years of study
an immense progress was achieved in the understanding of spectral information processing in the
retina. The progress is both in terms of characterizing the molecular level of signal transduction
from light into electrical signal and in the whole cell level where the responses of ganglion cells
to different color stimuli have been worked out. Despite these great achievements two important
aspects of encoding of color information by ganglion cells were neglected.
The first is the role of retinal adaptation to chromatic properties of visual signals. That is, how
the retina modifies the representation of information according to spectral properties of different
visual environments the animal encounters. The second important aspect is how exactly the different
color channels, realized by different types of ganglion cells, are combined in order to enable an
animal to distinguish between objects with different colors. I will discuss these two aspects of
the neural code of the retina.
|
| |
|
|
15:10 - 15:20
|
Coffee break
|
| |
|
|
15:20 - 16:10
|
Shmuel Peleg,
Hebrew University
Shift-Map Image Editing
|
|
|
Geometric rearrangement of images includes operations such as image retargeting, inpainting, or object
rearrangement. Each such operation can be characterized by a shiftmap: the relative shift of every
pixel in the output image from its source in an input image. We describe a new representation of these
operations as an optimal graph labeling, where the shift-map represents the selected label for each
output pixel. Two terms are used in computing the optimal shift-map: (i) A data term which indicates
constraints such as the change in image size, object rearrangement, a possible saliency map, etc. (ii)
A smoothness term, minimizing the new discontinuities in the output image caused by discontinuities in
the shift-map. This graph labeling problem can be solved using graph cuts. Since the optimization is
global and discrete, it outperforms state of the art methods in most cases. Efficient hierarchical
solutions for graph-cuts are presented, and operations on 1M images can take only a few seconds.
|
| |
|
|
16:10 - 17:00
|
Ilan Shimshoni,
Haifa University
Feature curves in range images with application to archaeology
|
|
|
Archaeological artifacts are of vital importance in archaeological
research. At present there is a drive to scan these artifacts and
store the scanned objects on the internet making them accessible to
the whole research community. We propose a new approach for
automatic processing of these 3D model. Given such an artifact our
first goal is to find edges termed relief edges on the surface. The
3D curves that we defined are the 3D equivalent of Canny Edges in
images. These edges can be used to illustrate the object replacing
the human illustrator or at least helping him produce accurate
illustrations efficiently using an interactive computerized tool.
Based on these curves we have defined a new direction field on
surfaces (a normalized vector field), termed the \emph{prominent
field}. We demonstrate the applicability of the prominent field in
two applications. The first is surface enhancement if archaeological
artifacts, which helps enhance eroded features and remove scanning
noise. The second is artificial coloring that can replace manual
artifact illustration in archaeological reports.
This work which is on the border between computer vision and
computer graphics is being carried out in cooperation with
archaeologists who help guide the research to make its results
applicable to them.
|
|
|
 |
|
|
