Track Before Detect in Active Sonar Systems

Ljung, Johnny

January 2021

Detection of an underwater target with active sonar in shallow waters such as the Baltic sea is a big challenge. This since the sound beams from the sonar will be reflected on the surfaces, sea surface and sea bottom, and the water volume itself which generates reverberation. Reverberation which will be reflected back to the receiver, is strong in intensity which give rise to many false targets in terms of classifying a target in a surveillance area. These false targets are unwanted and a real target might benefit from these miss-classifications in terms of remaining undetected. It is especially hard if the signal-to-noise ratio (SNR) is approaching zero, i.e. the target strength and the reverberation strength are equal in magnitude. The classical approach to a target detection problem is to assign a threshold value to the measurement, and the data point exceeding the threshold is classified as a target. This approach does not hold for low levels of SNR, since a threshold would not have a statistical significance and could lead to neglecting important data. Track-before-detect (TrBD) is a proposed method for low-SNR situations which tracks and detects a target based on unthresholded data. TrBD enables tracking and detecting of weak and/or stealthy targets. Due to the issues with target detection in shallow waters, the hypothesis of this thesis is to investigate the possibility to implement TrBD, and evaluate the performance of it, when applied on a low-SNR target. The TrBD is implemented with a particle filter which is a recursive Bayesian solution to the problem of integrated tracking and detection. The reverberation data was generated by filtering white noise with an Autoregressive filter of order 1. The target is assigned to propagate according to a constant velocity state space model. Two types of TrBD algorithms are implemented, one which is trained on the background and one which is not. The untrained TrBD is able to track and detect the target but only for levels of SNR down to 4dB. Lower SNR leads to the algorithm not being able to distinguish the target signal from the reverberation. The trained TrBD on the other hand, is able to perform very well for levels of SNR down to 0dB, it is able to track and detect the target and neglect the reverberation. For trajectories passing through areas with high reverberation, the target was lost for a short period of time until it could be retracked again. Overall, the TrBD was successfully implemented on the self-generated data and has a good performance for various target trajectories.

signal processing

active sonar systems

track-before-detect

target tracking

reverberation

signalbehandling

aktiva sonarsystem

spårning innan detektion

målspårning

reverberation

Signal Processing

Signalbehandling

Robust Non-Linear State Estimation for Underwater Acoustic Localization : Expanding on Gaussian Mixture Methods / Robust icke-linjär tillståndsuppskattning för akustisk lokalisering under vatten : Expanderande pa Gaussiska blandnings metoder

Antunes, Diogo

January 2023

Robust state estimation solutions must deal with faulty measurements, called outliers, and unknown data associations, which lead to multiple feasible hypotheses. Take, for instance, the scenario of tracking two indistinguishable targets based on position measurements, where each measurement could refer to either of the targets or even be a faulty reading. Common estimation methods model the state as having a unimodal distribution, so they are called unimodal methods. Likewise, multimodal methods model the state as a multimodal distribution. Difficult problems, such as autonomous underwater vehicle (AUV) navigation relying on acoustic localization, frequently involve recurring outliers. In these situations, the correct hypothesis only emerges as the most likely one when a substantial number of measurements are considered. Robust solutions for these problems need to consider multiple hypotheses simultaneously, which, in turn, calls for the representation of multimodal distributions. In this work, a novel approximate inference method is presented, called the Gaussian mixture sum-product algorithm (GM-SPA), as it implements the sum-product algorithm (SPA) for Gaussian mixtures. The GM-SPA can exactly represent under-constrained linear measurements and approximate important non-linear models, such as range measurements and 2D pose kinematics. The outlier robustness of the GM-SPA is tested and compared against the particle filter (PF) and multimodal incremental smoothing and mapping (MMiSAM), both of which are non-parametric methods. Robustness, accuracy, and run-time are improved in simulation tests. The test problems include 1D localization with unknown data association, 3D linear target tracking with correlated outliers, and 2D range-only pose estimation with Gaussian mixture noise. / Robusta lösningar för tillståndsuppskattning måste kunna hantera felaktiga mätningar, så kallade outliers, och okända dataassociationer, vilket leder till flera möjliga hypoteser. Ta till exempel scenariot att spåra två likadana mål baserat på positionsmätningar, där varje mätning kan tillhöra något av målen eller till och med vara en felaktig avläsning. Vanliga skattningsmetoder modellerar tillståndet som en unimodal fördelning, och kallas därför unimodala metoder. På samma sätt modellerar multimodala metoder tillståndet som en multimodal fördelning. Svåra problem, som navigering av autonoma undervattensfarkoster (AUV) med hjälp av akustisk lokalisering, involverar ofta upprepade outliers. I dessa situationer framstår den korrekta hypotesen som den mest sannolika först när ett stort antal mätningar beaktas. Robusta lösningar för dessa problem måste ta hänsyn till flera hypoteser samtidigt, vilket i sin tur kräver representation av multimodala fördelningar. I detta arbete presenteras en ny approximativ inferensmetod, kallad Gaussian mixture sum-product algorithm (GM-SPA), eftersom den implementerar sum-product algorithm (SPA) för gaussiska blandningar. GM-SPA kan representera underbegränsade linjära mätningar exakt och approximera viktiga icke-linjära modeller, till exempel avståndsmätningar eller 2D-posekinematik. GM-SPA:s robusthet mot outliers testas och jämförs med partikelfiltret (PF) och multimodal incremental smoothing and mapping (MM-iSAM), som båda är icke-parametriska metoder. Robusthet, noggrannhet och körtid förbättras i simuleringstester. Simulerade tester inkluderar 1D-lokalisering med okänd dataassociation, 3D linjär målföljning med korrelerade outliers och 2D-ställningsuppskattning av endast räckvidd med Gaussiskt blandningsljud. / Soluções robustas para estimação de estado devem lidar com medidas defeituosas, chamadas de outliers, e com associações de dados desconhecidas, que levam a múltiplas hipóteses possíveis. Considere-se, por exemplo, o cenário de rastreamento de dois alvos indistinguíveis com base em medidas de posição, em que cada medida pode-se referir a qualquer um dos alvos ou até mesmo ser uma leitura defeituosa. Métodos de estimação comuns modelam o estado como tendo uma distribuição unimodal, sendo assim chamados de métodos unimodais. Da mesma forma, métodos multimodais modelam o estado como uma distribuição multimodal. Problemas difíceis, como a navegação de veículos subaquáticos autónomos (AUVs) baseada em localização acústica, frequentemente envolvem outliers recorrentes. Nestas situações, a hipótese correta apenas surge como a mais provável quando um número substancial de medidas é considerado. Soluções robustas para estes problemas precisam de considerar múltiplas hipóteses simultaneamente, o que, por sua vez, exige a representação de distribuições multimodais. Neste trabalho, é apresentado um novo método de inferência aproximada, chamado Gaussian mixture sum-product algorithm (GM-SPA), pois implementa o sum-product algorithm (SPA) para misturas Gaussianas. O GM-SPA pode representar exatamente medidas lineares sub-determinadas e aproximar modelos não lineares importantes, como medidas de distância e cinemática de pose 2D. A robustez a outliers do GM-SPA é testada e comparada com o filtro de partículas (PF) e com multimodal incremental smoothing and mapping (MM- -iSAM), ambos métodos não-paramétricos. A robustez, a exatidão e o tempo de execução em testes de simulação são melhorados. Os problemas de teste incluem localização 1D com associação de dados desconhecida, rastreamento linear de alvos em 3D com outliers correlacionados e estimação de pose 2D com base em medidas de distância com ruído de mistura Gaussiana.

Robust state estimation

Underwater localization

Target tracking

Gaussian mixture

AUV

Estimação robusta de estado

Localização subaquática

Rastreamento de alvos

Mistura Gaussiana

AUV

Robust tillståndsuppskattning

Undervattenslokalisering

Målspårning

Gaussisk blandning

AUV

Elektroteknik och elektronik