Loading...
4 results
Search Results
Now showing 1 - 4 of 4
- XtokaxtikoX: a stochastic computing-based autonomous cyber-physical systemPublication . Duarte, Rui Policarpo; Neto, Horácio; Véstias, MárioThis paper presents XtokaxtikoX, a fully autonomous cyber-physical system employing only stochastic arithmetic to perform computations on its data-path. Traditional implementations of stochastic computing systems benefit from fast and compact implementation of arithmetic operators, and high tolerance to errors, but depend heavily on the conversion between stochastic bitstreams and binary to implement many parts of the system. Furthermore, if a system requires any interaction with analog electronic components it must have additional ADC/DAC conversion circuitry, which further increases the complexity of the system. Conversely, the proposed work is able to directly translate analog signals into stochastic bitstreams, process the stochastic bitstreams and finally control analog actuators relying only on the information on the stochastic bitstreams. Details on the architectures to accomplish such functionality are presented as well as other stochastic arithmetic units. This paper also presents a small stochastic computing-based autonomous cyber-physical system implemented on a Cyclone IV FPGA to carry out a proof-of-concept.
- Stochastic theater: stochastic datapath generation framework for fault-tolerant IoT sensorsPublication . Duarte, Rui Policarpo; Véstias, Mário; Carvalho, Carlos; Casaleiro, JoãoStochastic Computing has emerged as a competitive computing paradigm that produces fast and simple implementations of arithmetic operations, while offering high levels of parallelism, and graceful degradation of the results when in the presence of errors. IoT devices are often operate under limited power and area constraints and subjected to harsh environments, for which, traditional computing paradigms struggle to provide high availability and fault-tolerance. Stochastic Computing is based on the computation of pseudo-random sequences of bits, hence requiring only a single bit per signal, rather than a data-bus. Notwithstanding, we haven’t witnessed its inclusion in custom computing systems. In this direction, this work presents Stochastic Theater, a framework to specify, simulate, and test Stochastic Datapaths to perform computations using stochastic bitstreams targeting IoT systems. In virtue of the granularity of the bitstreams, the bit-level specification of circuits, high-performance characteristics and reconfigurable capabilities, FPGAs were adopted to implement and test such systems. The proposed framework creates Stochastic Machines from a set of user defined arithmetic expressions, and then tests them with the corresponding input values and specific fault injection patterns. Besides the support to create autonomous Stochastic Computing systems, the presented framework also provides generation of stochastic units, being able to produce estimates on performance, resources and power. A demonstration is presented targeting KLT, typical method for data compression in IoT applications.
- Fast convolutional neural networks in low density FPGAs using zero-skipping and weight pruningPublication . Véstias, Mário; Duarte, Rui Policarpo; De Sousa, Jose; Cláudio de Campos Neto, HorácioEdge devices are becoming smarter with the integration of machine learning methods, such as deep learning, and are therefore used in many application domains where decisions have to be made without human intervention. Deep learning and, in particular, convolutional neural networks (CNN) are more efficient than previous algorithms for several computer vision applications such as security and surveillance, where image and video analysis are required. This better efficiency comes with a cost of high computation and memory requirements. Hence, running CNNs in embedded computing devices is a challenge for both algorithm and hardware designers. New processing devices, dedicated system architectures and optimization of the networks have been researched to deal with these computation requirements. In this paper, we improve the inference execution times of CNNs in low density FPGAs (Field-Programmable Gate Arrays) using fixed-point arithmetic, zero-skipping and weight pruning. The developed architecture supports the execution of large CNNs in FPGA devices with reduced on-chip memory and computing resources. With the proposed architecture, it is possible to infer an image in AlexNet in 2.9 ms in a ZYNQ7020 and 1.0 ms in a ZYNQ7045 with less than 1% accuracy degradation. These results improve previous state-of-the-art architectures for CNN inference.
- Configurable hardware core for IoT object detectionPublication . Miranda, Pedro R.; Pestana, Daniel; D. Lopes, João; Duarte, Rui Policarpo; Véstias, Mário; Neto, Horácio C; De Sousa, JoseObject detection is an important task for many applications, like transportation, security, and medical applications. Many of these applications are needed on edge devices to make local decisions. Therefore, it is necessary to provide low-cost, fast solutions for object detection. This work proposes a configurable hardware core on a field-programmable gate array (FPGA) for object detection. The configurability of the core allows its deployment on target devices with diverse hardware resources. The object detection accelerator is based on YOLO, for its good accuracy at moderate computational complexity. The solution was applied to the design of a core to accelerate the Tiny-YOLOv3, based on a CNN developed for constrained environments. However, it can be applied to other YOLO versions. The core was integrated into a full system-on-chip solution and tested with the COCO dataset. It achieved a performance from 7 to 14 FPS in a low-cost ZYNQ7020 FPGA, depending on the quantization, with an accuracy reduction from 2.1 to 1.4 points of mAP50.