140,244 research outputs found
Alternative Archaeological Representations within Virtual Worlds
Traditional VR methods allow the user to tour and view the virtual world from different perspectives. Increasingly, more interactive and adaptive worlds are being generated, potentially allowing the user to interact with and affect objects in the virtual world. We describe and compare four models of operation that allow the publisher to generate views, with the client manipulating and affecting specific objects in the world. We demonstrate these approaches through a problem in archaeological visualization
Interpretation of Neural Networks is Fragile
In order for machine learning to be deployed and trusted in many
applications, it is crucial to be able to reliably explain why the machine
learning algorithm makes certain predictions. For example, if an algorithm
classifies a given pathology image to be a malignant tumor, then the doctor may
need to know which parts of the image led the algorithm to this classification.
How to interpret black-box predictors is thus an important and active area of
research. A fundamental question is: how much can we trust the interpretation
itself? In this paper, we show that interpretation of deep learning predictions
is extremely fragile in the following sense: two perceptively indistinguishable
inputs with the same predicted label can be assigned very different
interpretations. We systematically characterize the fragility of several
widely-used feature-importance interpretation methods (saliency maps, relevance
propagation, and DeepLIFT) on ImageNet and CIFAR-10. Our experiments show that
even small random perturbation can change the feature importance and new
systematic perturbations can lead to dramatically different interpretations
without changing the label. We extend these results to show that
interpretations based on exemplars (e.g. influence functions) are similarly
fragile. Our analysis of the geometry of the Hessian matrix gives insight on
why fragility could be a fundamental challenge to the current interpretation
approaches.Comment: Published as a conference paper at AAAI 201
Generalized Boundaries from Multiple Image Interpretations
Boundary detection is essential for a variety of computer vision tasks such
as segmentation and recognition. In this paper we propose a unified formulation
and a novel algorithm that are applicable to the detection of different types
of boundaries, such as intensity edges, occlusion boundaries or object category
specific boundaries. Our formulation leads to a simple method with
state-of-the-art performance and significantly lower computational cost than
existing methods. We evaluate our algorithm on different types of boundaries,
from low-level boundaries extracted in natural images, to occlusion boundaries
obtained using motion cues and RGB-D cameras, to boundaries from
soft-segmentation. We also propose a novel method for figure/ground
soft-segmentation that can be used in conjunction with our boundary detection
method and improve its accuracy at almost no extra computational cost
Contextual Outlier Interpretation
Outlier detection plays an essential role in many data-driven applications to
identify isolated instances that are different from the majority. While many
statistical learning and data mining techniques have been used for developing
more effective outlier detection algorithms, the interpretation of detected
outliers does not receive much attention. Interpretation is becoming
increasingly important to help people trust and evaluate the developed models
through providing intrinsic reasons why the certain outliers are chosen. It is
difficult, if not impossible, to simply apply feature selection for explaining
outliers due to the distinct characteristics of various detection models,
complicated structures of data in certain applications, and imbalanced
distribution of outliers and normal instances. In addition, the role of
contrastive contexts where outliers locate, as well as the relation between
outliers and contexts, are usually overlooked in interpretation. To tackle the
issues above, in this paper, we propose a novel Contextual Outlier
INterpretation (COIN) method to explain the abnormality of existing outliers
spotted by detectors. The interpretability for an outlier is achieved from
three aspects: outlierness score, attributes that contribute to the
abnormality, and contextual description of its neighborhoods. Experimental
results on various types of datasets demonstrate the flexibility and
effectiveness of the proposed framework compared with existing interpretation
approaches
Image mining: issues, frameworks and techniques
[Abstract]: Advances in image acquisition and storage technology have led to tremendous growth in significantly large and detailed image databases. These images, if analyzed, can reveal useful information to the human users. Image mining deals with the extraction of implicit knowledge, image data relationship, or other patterns not explicitly stored in the images. Image mining is more than just an extension of data mining to image domain. It is an
interdisciplinary endeavor that draws upon expertise in
computer vision, image processing, image retrieval, data
mining, machine learning, database, and artificial
intelligence. Despite the development of many
applications and algorithms in the individual research
fields cited above, research in image mining is still in its infancy. In this paper, we will examine the research issues in image mining, current developments in image mining, particularly, image mining frameworks, state-of-the-art techniques and systems. We will also identify some future research directions for image mining at the end of this paper
Medical imaging analysis with artificial neural networks
Given that neural networks have been widely reported in the research community of medical imaging, we provide a focused literature survey on recent neural network developments in computer-aided diagnosis, medical image segmentation and edge detection towards visual content analysis, and medical image registration for its pre-processing and post-processing, with the aims of increasing awareness of how neural networks can be applied to these areas and to provide a foundation for further research and practical development. Representative techniques and algorithms are explained in detail to provide inspiring examples illustrating: (i) how a known neural network with fixed structure and training procedure could be applied to resolve a medical imaging problem; (ii) how medical images could be analysed, processed, and characterised by neural networks; and (iii) how neural networks could be expanded further to resolve problems relevant to medical imaging. In the concluding section, a highlight of comparisons among many neural network applications is included to provide a global view on computational intelligence with neural networks in medical imaging
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