25 research outputs found
Towards the Success Rate of One: Real-time Unconstrained Salient Object Detection
In this work, we propose an efficient and effective approach for
unconstrained salient object detection in images using deep convolutional
neural networks. Instead of generating thousands of candidate bounding boxes
and refining them, our network directly learns to generate the saliency map
containing the exact number of salient objects. During training, we convert the
ground-truth rectangular boxes to Gaussian distributions that better capture
the ROI regarding individual salient objects. During inference, the network
predicts Gaussian distributions centered at salient objects with an appropriate
covariance, from which bounding boxes are easily inferred. Notably, our network
performs saliency map prediction without pixel-level annotations, salient
object detection without object proposals, and salient object subitizing
simultaneously, all in a single pass within a unified framework. Extensive
experiments show that our approach outperforms existing methods on various
datasets by a large margin, and achieves more than 100 fps with VGG16 network
on a single GPU during inference
Visual Search at eBay
In this paper, we propose a novel end-to-end approach for scalable visual
search infrastructure. We discuss the challenges we faced for a massive
volatile inventory like at eBay and present our solution to overcome those. We
harness the availability of large image collection of eBay listings and
state-of-the-art deep learning techniques to perform visual search at scale.
Supervised approach for optimized search limited to top predicted categories
and also for compact binary signature are key to scale up without compromising
accuracy and precision. Both use a common deep neural network requiring only a
single forward inference. The system architecture is presented with in-depth
discussions of its basic components and optimizations for a trade-off between
search relevance and latency. This solution is currently deployed in a
distributed cloud infrastructure and fuels visual search in eBay ShopBot and
Close5. We show benchmark on ImageNet dataset on which our approach is faster
and more accurate than several unsupervised baselines. We share our learnings
with the hope that visual search becomes a first class citizen for all large
scale search engines rather than an afterthought.Comment: To appear in 23rd SIGKDD Conference on Knowledge Discovery and Data
Mining (KDD), 2017. A demonstration video can be found at
https://youtu.be/iYtjs32vh4
Multi-level feature fusion network combining attention mechanisms for polyp segmentation
Clinically, automated polyp segmentation techniques have the potential to
significantly improve the efficiency and accuracy of medical diagnosis, thereby
reducing the risk of colorectal cancer in patients. Unfortunately, existing
methods suffer from two significant weaknesses that can impact the accuracy of
segmentation. Firstly, features extracted by encoders are not adequately
filtered and utilized. Secondly, semantic conflicts and information redundancy
caused by feature fusion are not attended to. To overcome these limitations, we
propose a novel approach for polyp segmentation, named MLFF-Net, which
leverages multi-level feature fusion and attention mechanisms. Specifically,
MLFF-Net comprises three modules: Multi-scale Attention Module (MAM),
High-level Feature Enhancement Module (HFEM), and Global Attention Module
(GAM). Among these, MAM is used to extract multi-scale information and polyp
details from the shallow output of the encoder. In HFEM, the deep features of
the encoders complement each other by aggregation. Meanwhile, the attention
mechanism redistributes the weight of the aggregated features, weakening the
conflicting redundant parts and highlighting the information useful to the
task. GAM combines features from the encoder and decoder features, as well as
computes global dependencies to prevent receptive field locality. Experimental
results on five public datasets show that the proposed method not only can
segment multiple types of polyps but also has advantages over current
state-of-the-art methods in both accuracy and generalization ability
Interfacial Current Distribution Between Helium Plasma Jet and Water Solution
The plasma-liquid interaction holds great importance for a number of emerging applications such as plasma biomedicine, yet a main fundamental question remains about the nature of the physiochemical processes occurring at the plasma-liquid interface. In this paper, the interfacial current distribution between helium plasma jet and water solution was measured for the first time by means of the splitting electrode method, which was borrowed from the field of arc plasma. For a plasma plume in continuous mode, it was found that the mean absolute current distribution at the plasma-liquid interface typically had an annular shape. This shape could be affected by regulating the air doping from the surrounding atmosphere, the gas flow rate, the applied voltage and the conductivity of the water solution. However, only the air doping fraction and the water conductivity could fundamentally change the interfacial current distribution from the annular shape to the central maximum shape. It was deduced that a certain amount of ambient air doping (mainly N2 and O2) and a low conductivity (typically \u3c 300 μS/cm) of the treated water were essential for the formation of the annular current distribution at the plasma-liquid interface