118 research outputs found
Number Systems for Deep Neural Network Architectures: A Survey
Deep neural networks (DNNs) have become an enabling component for a myriad of
artificial intelligence applications. DNNs have shown sometimes superior
performance, even compared to humans, in cases such as self-driving, health
applications, etc. Because of their computational complexity, deploying DNNs in
resource-constrained devices still faces many challenges related to computing
complexity, energy efficiency, latency, and cost. To this end, several research
directions are being pursued by both academia and industry to accelerate and
efficiently implement DNNs. One important direction is determining the
appropriate data representation for the massive amount of data involved in DNN
processing. Using conventional number systems has been found to be sub-optimal
for DNNs. Alternatively, a great body of research focuses on exploring suitable
number systems. This article aims to provide a comprehensive survey and
discussion about alternative number systems for more efficient representations
of DNN data. Various number systems (conventional/unconventional) exploited for
DNNs are discussed. The impact of these number systems on the performance and
hardware design of DNNs is considered. In addition, this paper highlights the
challenges associated with each number system and various solutions that are
proposed for addressing them. The reader will be able to understand the
importance of an efficient number system for DNN, learn about the widely used
number systems for DNN, understand the trade-offs between various number
systems, and consider various design aspects that affect the impact of number
systems on DNN performance. In addition, the recent trends and related research
opportunities will be highlightedComment: 28 page
Implementation of a real time Hough transform using FPGA technology
This thesis is concerned with the modelling, design and implementation of efficient architectures for performing the Hough Transform (HT) on mega-pixel resolution real-time images using Field Programmable Gate Array (FPGA) technology. Although the HT has been around for many years and a number of algorithms have been developed it still remains a significant bottleneck in many image processing applications.
Even though, the basic idea of the HT is to locate curves in an image that can be parameterized: e.g. straight lines, polynomials or circles, in a suitable parameter space, the research presented in this thesis will focus only on location of straight lines on binary images. The HT algorithm uses an accumulator array (accumulator bins) to detect the existence of a straight line on an image. As the image needs to be binarized, a novel generic synchronization circuit for windowing operations was designed to perform edge detection. An edge detection method of special interest, the canny method, is used and the design and implementation of it in hardware is achieved in this thesis.
As each image pixel can be implemented independently, parallel processing can be performed. However, the main disadvantage of the HT is the large storage and computational requirements. This thesis presents new and state-of-the-art hardware implementations for the minimization of the computational cost, using the Hybrid-Logarithmic Number System (Hybrid-LNS) for calculating the HT for fixed bit-width architectures. It is shown that using the Hybrid-LNS the computational cost is minimized, while the precision of the HT algorithm is maintained.
Advances in FPGA technology now make it possible to implement functions as the HT in reconfigurable fabrics. Methods for storing large arrays on FPGA’s are presented, where data from a 1024 x 1024 pixel camera at a rate of up to 25 frames per second are processed
Conference on the Programming Environment for Development of Numerical Software
Systematic approaches to numerical software development and testing are presented
- …