35,175 research outputs found
Robust filtering for bilinear uncertain stochastic discrete-time systems
Copyright [2002] IEEE. This material is posted here with permission of the IEEE. Such permission of the IEEE does not in any way imply IEEE endorsement of any of Brunel University's products or services. Internal or personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution must be obtained from the IEEE by writing to [email protected]. By choosing to view this document, you agree to all provisions of the copyright laws protecting it.This paper deals with the robust filtering problem for uncertain bilinear stochastic discrete-time systems with estimation error variance constraints. The uncertainties are allowed to be norm-bounded and enter into both the state and measurement matrices. We focus on the design of linear filters, such that for all admissible parameter uncertainties, the error state of the bilinear stochastic system is mean square bounded, and the steady-state variance of the estimation error of each state is not more than the individual prespecified value. It is shown that the design of the robust filters can be carried out by solving some algebraic quadratic matrix inequalities. In particular, we establish both the existence conditions and the explicit expression of desired robust filters. A numerical example is included to show the applicability of the present method
DJpsiFDC: an event generator for the process at LHC
DJpsiFDC is an event generator package for the process .
It generates events for primary leading-order processes. The package
could generate a LHE document and this document could easily be embedded into
detector simulation software frameworks. The package is produced in Fortran
codes.Comment: 10 pages, 3 figure
LSTD: A Low-Shot Transfer Detector for Object Detection
Recent advances in object detection are mainly driven by deep learning with
large-scale detection benchmarks. However, the fully-annotated training set is
often limited for a target detection task, which may deteriorate the
performance of deep detectors. To address this challenge, we propose a novel
low-shot transfer detector (LSTD) in this paper, where we leverage rich
source-domain knowledge to construct an effective target-domain detector with
very few training examples. The main contributions are described as follows.
First, we design a flexible deep architecture of LSTD to alleviate transfer
difficulties in low-shot detection. This architecture can integrate the
advantages of both SSD and Faster RCNN in a unified deep framework. Second, we
introduce a novel regularized transfer learning framework for low-shot
detection, where the transfer knowledge (TK) and background depression (BD)
regularizations are proposed to leverage object knowledge respectively from
source and target domains, in order to further enhance fine-tuning with a few
target images. Finally, we examine our LSTD on a number of challenging low-shot
detection experiments, where LSTD outperforms other state-of-the-art
approaches. The results demonstrate that LSTD is a preferable deep detector for
low-shot scenarios.Comment: Accepted by AAAI201
On Reject and Refine Options in Multicategory Classification
In many real applications of statistical learning, a decision made from
misclassification can be too costly to afford; in this case, a reject option,
which defers the decision until further investigation is conducted, is often
preferred. In recent years, there has been much development for binary
classification with a reject option. Yet, little progress has been made for the
multicategory case. In this article, we propose margin-based multicategory
classification methods with a reject option. In addition, and more importantly,
we introduce a new and unique refine option for the multicategory problem,
where the class of an observation is predicted to be from a set of class
labels, whose cardinality is not necessarily one. The main advantage of both
options lies in their capacity of identifying error-prone observations.
Moreover, the refine option can provide more constructive information for
classification by effectively ruling out implausible classes. Efficient
implementations have been developed for the proposed methods. On the
theoretical side, we offer a novel statistical learning theory and show a fast
convergence rate of the excess -risk of our methods with emphasis on
diverging dimensionality and number of classes. The results can be further
improved under a low noise assumption. A set of comprehensive simulation and
real data studies has shown the usefulness of the new learning tools compared
to regular multicategory classifiers. Detailed proofs of theorems and extended
numerical results are included in the supplemental materials available online.Comment: A revised version of this paper was accepted for publication in the
Journal of the American Statistical Association Theory and Methods Section.
52 pages, 6 figure
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