Towards real-time image understanding with convolutional networks / Analyse sémantique des images en temps-réel avec des réseaux convolutifs

Farabet, Clément

18 December 2013

One of the open questions of artificial computer vision is how to produce good internal representations of the visual world. What sort of internal representation would allow an artificial vision system to detect and classify objects into categories, independently of pose, scale, illumination, conformation, and clutter ? More interestingly, how could an artificial vision system {em learn} appropriate internal representations automatically, the way animals and humans seem to learn by simply looking at the world ? Another related question is that of computational tractability, and more precisely that of computational efficiency. Given a good visual representation, how efficiently can it be trained, and used to encode new sensorial data. Efficiency has several dimensions: power requirements, processing speed, and memory usage. In this thesis I present three new contributions to the field of computer vision:(1) a multiscale deep convolutional network architecture to easily capture long-distance relationships between input variables in image data, (2) a tree-based algorithm to efficiently explore multiple segmentation candidates, to produce maximally confident semantic segmentations of images,(3) a custom dataflow computer architecture optimized for the computation of convolutional networks, and similarly dense image processing models. All three contributions were produced with the common goal of getting us closer to real-time image understanding. Scene parsing consists in labeling each pixel in an image with the category of the object it belongs to. In the first part of this thesis, I propose a method that uses a multiscale convolutional network trained from raw pixels to extract dense feature vectors that encode regions of multiple sizes centered on each pixel. The method alleviates the need for engineered features. In parallel to feature extraction, a tree of segments is computed from a graph of pixel dissimilarities. The feature vectors associated with the segments covered by each node in the tree are aggregated and fed to a classifier which produces an estimate of the distribution of object categories contained in the segment. A subset of tree nodes that cover the image are then selected so as to maximize the average "purity" of the class distributions, hence maximizing the overall likelihood that each segment contains a single object (...) / One of the open questions of artificial computer vision is how to produce good internal representations of the visual world. What sort of internal representation would allow an artificial vision system to detect and classify objects into categories, independently of pose, scale, illumination, conformation, and clutter ? More interestingly, how could an artificial vision system {em learn} appropriate internal representations automatically, the way animals and humans seem to learn by simply looking at the world ? Another related question is that of computational tractability, and more precisely that of computational efficiency. Given a good visual representation, how efficiently can it be trained, and used to encode new sensorial data. Efficiency has several dimensions: power requirements, processing speed, and memory usage. In this thesis I present three new contributions to the field of computer vision:(1) a multiscale deep convolutional network architecture to easily capture long-distance relationships between input variables in image data, (2) a tree-based algorithm to efficiently explore multiple segmentation candidates, to produce maximally confident semantic segmentations of images,(3) a custom dataflow computer architecture optimized for the computation of convolutional networks, and similarly dense image processing models. All three contributions were produced with the common goal of getting us closer to real-time image understanding. Scene parsing consists in labeling each pixel in an image with the category of the object it belongs to. In the first part of this thesis, I propose a method that uses a multiscale convolutional network trained from raw pixels to extract dense feature vectors that encode regions of multiple sizes centered on each pixel. The method alleviates the need for engineered features. In parallel to feature extraction, a tree of segments is computed from a graph of pixel dissimilarities. The feature vectors associated with the segments covered by each node in the tree are aggregated and fed to a classifier which produces an estimate of the distribution of object categories contained in the segment. A subset of tree nodes that cover the image are then selected so as to maximize the average "purity" of the class distributions, hence maximizing the overall likelihood that each segment contains a single object. The system yields record accuracies on several public benchmarks. The computation of convolutional networks, and related models heavily relies on a set of basic operators that are particularly fit for dedicated hardware implementations. In the second part of this thesis I introduce a scalable dataflow hardware architecture optimized for the computation of general-purpose vision algorithms, neuFlow, and a dataflow compiler, luaFlow, that transforms high-level flow-graph representations of these algorithms into machine code for neuFlow. This system was designed with the goal of providing real-time detection, categorization and localization of objects in complex scenes, while consuming 10 Watts when implemented on a Xilinx Virtex 6 FPGA platform, or about ten times less than a laptop computer, and producing speedups of up to 100 times in real-world applications (results from 2011)

Réseaux Convolutifs

Deep Learning

Vision Informatique

Temps-Réel

Fpga/asic

Dataflow

Convolutional Networks

Apprentissage Profond

Computer Vision

Real-Time

Fpga/asic

Dataflow

Parameterizable Wishbone Bus

Hussain Fawzi, Omar, Alagedi, Alfiqar

January 2012

In the industry of intellectual property products "IP-cores", a communication link is almost always needed. A semiconductor intellectual property IP core is a reusable unit of logic in electronic design. IP cores are used as building blocks for ASIC chip design or FPGA logic designs. A bus creates a communication link between the IP cores in a system. The company AnaCatum Design AB have many projects where a bus is needed. Creating a new bus structure for every project is time consuming. By having a generic bus structure of a known standard with changeable parameters, the user only has to set the desired parameters to fit the system. Also having interfaces for master and slave the user has only to make minor changes to have a fully functional bus for the system.

Annan elektroteknik och elektronik

Ring Oscillator Based Hardware Trojan Detection

Hoque, Tamzidul

January 2015

No description available.

Electrical Engineering

Computer Engineering

Multidimensional Signal Processing Using Mixed-Microwave-Digital Circuits and Systems

Sengupta, Arindam

17 September 2014

No description available.

Electrical Engineering

Computer Engineering