Computationally efficient vessel classification using shallow neural networks on SAR data

O radar de abertura sintética (SAR) ´e um radar ativo montado em uma plataforma em movimento, que simula um comprimento de antena maior do que o comprimento real da antena física. De forma semelhante ao radar convencional, ondas eletromagnéticas são transmitidas sequencialmente e os ecos são coletados pelo radar. Com o devido processamento de sinal, este tipo de sistema ´e capaz de fornecer imagens de micro-ondas de alta resolução de uma área-alvo desejada, em praticamente todas as condições meteorológicas. Atualmente, os sistemas SAR tem sido amplamente utilizados para a deteção remota possuindo várias aplicações, como observação da superfície terrestre, cartografia e aplicações militares. Dado que ´e independente do clima e pode operar tanto de dia quanto de noite, o SAR pode ser uma fonte mais confiável quando comparado com imagens ´óticas [1]. A deteção e reconhecimento de navios em imagens SAR tornou-se um tópico importante de pesquisa nos últimos anos. Esta tese apresenta um algoritmo computacionalmente eficiente para a classificação de embarcações em imagens de SAR usando Redes Neuronais com um número reduzido de camadas, também conhecidas como shallow neural networks. A utilização de shallow networks para a classificação de embarcações será dividida em duas etapas: extração de características e classificação. A extração de características tem como objetivo reduzir a carga computacional que as deep neural networks causam nos recursos computacionais, extraindo antecipadamente características-chave da imagem SAR. Os baixos requisitos computacionais tornam esta implementação compatível com sistemas a bordo de navios e aplicações em tempo real. A classificação ´e realizada usando uma rede neural com um número reduzido de camadas, que utiliza parâmetros obtidos a partir de algoritmos de extração de características para classificar a embarcação presente na imagem de radar. O processo de extração de características processa dados do conjunto de dados Open SAR ship [2] para obter várias características da embarcação, como comprimento, largura, média, desvio padrão e o número de pontos de dispersão presentes na embarcação.Synthetic aperture radar (SAR) is an active radar that is mounted on a moving platform, simulating a longer antenna length than the physical antenna real length. Similar to a conventional radar, electromagnetic waves are sequentially transmitted and the backscattered echoes are collected by the radar. With the proper signal processing, this kind of system is able to provide high resolution microwave images of a desired target area by synthesising a larger antenna aperture, in virtually all-weather conditions. Nowadays SAR systems have been extensively used for remote sensing. It has various applications such as Earth surface monitoring, charting and militar applications. Since it is weather independent and is able to operate whether it is day or night, SAR can be a more reliable source when compared with optical imagery [1]. Ship detection and recognition in SAR images has become an importante topic in research in recent years. This thesis presents a computationally eficiente algorithm for the classification of vessels in SAR images using Neural Networks (NN) with a reduced number of hidden layers, also called Shallow Neural Networks (SNN). Herein the use of SNN for vessel classification will be divided into two main steps: feature extraction and classification. Feature extraction aims to lessen the burden deep neural networks cause on computational resources by extracting key features beforehand from the SAR image. The low computational requirements make this implementation compatible with onboard vessel systems and real time applications. The classification is implemented using a SNN that uses parameters obtained from feature extraction algorithms to classify the vessel present in the radar image. In this thesis feature extraction processes data from the Open SAR Ship dataset [2] in order to obtain the vessel’s various features, such as ship length, width, mean, standard deviation and the number of scatter points present on the vessel.N/

Operational Monitoring of Illegal Fishing in Ghana through Exploitation of Satellite Earth Observation and AIS Data.

Over the last decade, West African coastal countries, including Ghana, have experienced extensive economic damage due to illegal, unreported and unregulated (IUU) fishing activity, estimated at about USD 100 million in losses each year. Illegal, unreported and unregulated fishing poses an enormous threat to the conservation and management of the dwindling fish stocks, causing multiple adverse consequences for fisheries, coastal and marine ecosystems and for the people who depend on these resources. The Integrated System for Surveillance of Illegal, Unlicensed and Unreported Fishing (INSURE) is an efficient and inexpensive system that has been developed for the monitoring of IUU fishing in Ghanaian waters. It makes use of fast-delivery Earth observation data from the synthetic aperture radar instrument on Sentinel-1 and the Multi Spectral Imager on Sentinel-2, detecting objects that differ markedly from their immediate background using a constant false alarm rate test. Detections are matched to, and verified by, Automatic Identification System (AIS) data, which provide the location and dimensions of ships that are legally operating in the region. Matched and unmatched data are then displayed on a web portal for use by coastal management authorities in Ghana. The system has a detection success rate of 91% for AIS-registered vessels, and a fast throughput, processing and delivering information within 2 h of acquiring the satellite overpass. However, over the 17-month analysis period, 75% of SAR detections have no equivalent in the AIS record, suggesting significant unregulated marine activity, including vessels potentially involved in IUU. The INSURE system demonstrated its efficiency in Ghana’s exclusive economic zone and it can be extended to the neighbouring states in the Gulf of Guinea, or other geographical regions that need to improve fisheries surveillance

Fast Vessel Detection in Gaofen-3 SAR Images with Ultrafine Strip-Map Mode

This study aims to detect vessels with lengths ranging from about 70 to 300 m, in Gaofen-3 (GF-3) SAR images with ultrafine strip-map (UFS) mode as fast as possible. Based on the analysis of the characteristics of vessels in GF-3 SAR imagery, an effective vessel detection method is proposed in this paper. Firstly, the iterative constant false alarm rate (CFAR) method is employed to detect the potential ship pixels. Secondly, the mean-shift operation is applied on each potential ship pixel to identify the candidate target region. During the mean-shift process, we maintain a selection matrix recording which pixels can be taken, and these pixels are called as the valid points of the candidate target. The l 1 norm regression is used to extract the principal axis and detect the valid points. Finally, two kinds of false alarms, the bright line and the azimuth ambiguity, are removed by comparing the valid area of the candidate target with a pre-defined value and computing the displacement between the true target and the corresponding replicas respectively. Experimental results on three GF-3 SAR images with UFS mode demonstrate the effectiveness and efficiency of the proposed method

Symmetry in Applied Mathematics

Applied mathematics and symmetry work together as a powerful tool for problem reduction and solving. We are communicating applications in probability theory and statistics (A Test Detecting the Outliers for Continuous Distributions Based on the Cumulative Distribution Function of the Data Being Tested, The Asymmetric Alpha-Power Skew-t Distribution), fractals - geometry and alike (Khovanov Homology of Three-Strand Braid Links, Volume Preserving Maps Between p-Balls, Generation of Julia and Mandelbrot Sets via Fixed Points), supersymmetry - physics, nanostructures -chemistry, taxonomy - biology and alike (A Continuous Coordinate System for the Plane by Triangular Symmetry, One-Dimensional Optimal System for 2D Rotating Ideal Gas, Minimal Energy Configurations of Finite Molecular Arrays, Noether-Like Operators and First Integrals for Generalized Systems of Lane-Emden Equations), algorithms, programs and software analysis (Algorithm for Neutrosophic Soft Sets in Stochastic Multi-Criteria Group Decision Making Based on Prospect Theory, On a Reduced Cost Higher Order Traub-Steffensen-Like Method for Nonlinear Systems, On a Class of Optimal Fourth Order Multiple Root Solvers without Using Derivatives) to specific subjects (Facility Location Problem Approach for Distributed Drones, Parametric Jensen-Shannon Statistical Complexity and Its Applications on Full-Scale Compartment Fire Data). Diverse topics are thus combined to map out the mathematical core of practical problems