11,498 research outputs found
Domain-Specific Face Synthesis for Video Face Recognition from a Single Sample Per Person
The performance of still-to-video FR systems can decline significantly
because faces captured in unconstrained operational domain (OD) over multiple
video cameras have a different underlying data distribution compared to faces
captured under controlled conditions in the enrollment domain (ED) with a still
camera. This is particularly true when individuals are enrolled to the system
using a single reference still. To improve the robustness of these systems, it
is possible to augment the reference set by generating synthetic faces based on
the original still. However, without knowledge of the OD, many synthetic images
must be generated to account for all possible capture conditions. FR systems
may, therefore, require complex implementations and yield lower accuracy when
training on many less relevant images. This paper introduces an algorithm for
domain-specific face synthesis (DSFS) that exploits the representative
intra-class variation information available from the OD. Prior to operation, a
compact set of faces from unknown persons appearing in the OD is selected
through clustering in the captured condition space. The domain-specific
variations of these face images are projected onto the reference stills by
integrating an image-based face relighting technique inside the 3D
reconstruction framework. A compact set of synthetic faces is generated that
resemble individuals of interest under the capture conditions relevant to the
OD. In a particular implementation based on sparse representation
classification, the synthetic faces generated with the DSFS are employed to
form a cross-domain dictionary that account for structured sparsity.
Experimental results reveal that augmenting the reference gallery set of FR
systems using the proposed DSFS approach can provide a higher level of accuracy
compared to state-of-the-art approaches, with only a moderate increase in its
computational complexity
Small unmanned airborne systems to support oil and gas pipeline monitoring and mapping
Acknowledgments We thank Johan Havelaar, Aeryon Labs Inc., AeronVironment Inc. and Aeronautics Inc. for kindly permitting the use of materials in Fig. 1.Peer reviewedPublisher PD
A Nonconvex Projection Method for Robust PCA
Robust principal component analysis (RPCA) is a well-studied problem with the
goal of decomposing a matrix into the sum of low-rank and sparse components. In
this paper, we propose a nonconvex feasibility reformulation of RPCA problem
and apply an alternating projection method to solve it. To the best of our
knowledge, we are the first to propose a method that solves RPCA problem
without considering any objective function, convex relaxation, or surrogate
convex constraints. We demonstrate through extensive numerical experiments on a
variety of applications, including shadow removal, background estimation, face
detection, and galaxy evolution, that our approach matches and often
significantly outperforms current state-of-the-art in various ways.Comment: In the proceedings of Thirty-Third AAAI Conference on Artificial
Intelligence (AAAI-19
Examples of current radar technology and applications, chapter 5, part B
Basic principles and tradeoff considerations for SLAR are summarized. There are two fundamental types of SLAR sensors available to the remote sensing user: real aperture and synthetic aperture. The primary difference between the two types is that a synthetic aperture system is capable of significant improvements in target resolution but requires equally significant added complexity and cost. The advantages of real aperture SLAR include long range coverage, all-weather operation, in-flight processing and image viewing, and lower cost. The fundamental limitation of the real aperture approach is target resolution. Synthetic aperture processing is the most practical approach for remote sensing problems that require resolution higher than 30 to 40 m
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