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- A review of synthetic-aperture radar image formation algorithms and implementations: a computational perspectivePublication . Cruz, Helena; Véstias, Mário; Monteiro, J; Cláudio de Campos Neto, Horácio; Duarte, RuiDesigning synthetic-aperture radar image formation systems can be challenging due to the numerous options of algorithms and devices that can be used. There are many SAR image formation algorithms, such as backprojection, matched-filter, polar format, Range–Doppler and chirp scaling algorithms. Each algorithm presents its own advantages and disadvantages considering efficiency and image quality; thus, we aim to introduce some of the most common SAR image formation algorithms and compare them based on these two aspects. Depending on the requisites of each individual system and implementation, there are many device options to choose from, for in stance, FPGAs, GPUs, CPUs, many-core CPUs, and microcontrollers. We present a review of the state of the art of SAR imaging systems implementations. We also compare such implementations in terms of power consumption, execution time, and image quality for the different algorithms used.
- Onboard processing of synthetic aperture radar backprojection algorithm in FPGAPublication . Mota, David; Cruz, Helena; Miranda, Pedro R.; Duarte, Rui Policarpo; De Sousa, Jose; Cláudio de Campos Neto, Horácio; Véstias, MárioSynthetic aperture radar is a microwave technique to extracting image information of the target. Electromagnetic waves that are reflected from the target are acquired by the aircraft or satellite receivers and sent to a ground station to be processed by applying computational demanding algorithms. Radar data streams are acquired by an aircraft or satellite and sent to a ground station to be processed in order to extract images from the data since these processing algorithms are computationally demanding. However, novel applications require real-time processing for real-time analysis and decisions and so onboard processing is necessary. Running computationally demanding algorithms on onboard embedded systems with limited energy and computational capacity is a challenge. This article proposes a configurable hardware core for the execution of the backprojection algorithm with high performance and energy efficiency. The original backprojection algorithm is restructured to expose computational parallelism and then optimized by replacing floating-point with fixed-point arithmetic. The backprojection core was integrated into a system-onchip architecture and implemented in a field-programmable gate array. The proposed solution runs the optimized backprojection algorithm over images of sizes 512 x 512 and 1024 x 1024 in 0.14 s (0.41 J) and 1.11 s (3.24 J), respectively. The architecture is 2.6x faster and consumes 13x less energy than an embedded Jetson TX2 GPU. The solution is scalable and, therefore, a tradeoff exists between performance and utilization of resources.
- Energy-efficient and real-time wearable for wellbeing-monitoring IoT system based on SoC-FPGAPublication . Frutuoso, Maria Inês; Cláudio de Campos Neto, Horácio; Véstias, Mário; Duarte, Rui PolicarpoWearable devices used for personal monitoring applications have been improved over the last decades. However, these devices are limited in terms of size, processing capability and power consumption. This paper proposes an efficient hardware/software embedded system for monitoring bio-signals in real time, including a heart rate calculator using PPG and an emotion classifier from EEG. The system is suitable for outpatient clinic applications requiring data transfers to external medical staff. The proposed solution contributes with an effective alternative to the traditional approach of processing bio-signals offline by proposing a SoC-FPGA based system that is able to fully process the signals locally at the node. Two sub-systems were developed targeting a Zynq 7010 device and integrating custom hardware IP cores that accelerate the processing of the most complex tasks. The PPG sub-system implements an autocorrelation peak detection algorithm to calculate heart rate values. The EEG sub-system consists of a KNN emotion classifier of preprocessed EEG features. This work overcomes the processing limitations of microcontrollers and general-purpose units, presenting a scalable and autonomous wearable solution with high processing capability and real-time response.
- A configurable architecture for running hybrid convolutional neural networks in low-density FPGAsPublication . Véstias, Mário; Duarte, Rui; De Sousa, Jose; Cláudio de Campos Neto, HorácioConvolutional neural networks have become the state of the art of machine learning for a vast set of applications, especially for image classification and object detection. There are several advantages to running inference on these models at the edge, including real-time performance and data privacy. The high computing and memory requirements of convolutional neural networks have been major obstacles to the broader deployment of CNNs on edge devices. Data quantization is an optimization method that reduces the number of bits used to represent weights and activations of a network model, minimizing storage requirements and computing complexity. Quantization can be applied at the layer level, by using different bit widths in different layers: this is called hybrid quantization. This article proposes a new efficient and configurable architecture for running CNNs with hybrid quantization in low-density Field-Programmable Gate Arrays (FPGAs) targeting edge devices. The architecture has been implemented on the Xilinx ZYNQ7020/45 devices and is running the AlexNet and VGG16 networks. Running AlexNet, the architecture has a throughput up to 508 images per second on the ZYNQ7020 device, and 1639 images per second on the ZYNQ7045 device. Considering VGG16, the architecture delivers up to 43 images per second on the ZYNQ7020 device, and 81 images per second on the ZYNQ7045 device. The proposed hybrid architecture achieves up to 13.7 x improvement in performance compared to state-of-the-art solutions, with small accuracy degradation.