Sidescan Only Neural Bathymetry from Large-Scale Survey

Abstract: Sidescan sonar is a small and low-cost sensor that can be mounted on most unmanned underwater vehicles (UUVs) and unmanned surface vehicles (USVs). It has the advantages of high resolution and wide coverage, which could be valuable in providing an efficient and cost-effective solution for obtaining the bathymetry when bathymetric data are unavailable. This work proposes a method of reconstructing bathymetry using only sidescan data from large-scale surveys by formulating the problem as a global optimization, w… Show more

“…However, the "ground truth" bathymetry is needed for creating a training set, which is not always practical underwater. Neural rendering [7], [8] methods that leverage the continuity and differentiablity of implicit neural representations have been recently proposed to fit many sidescan lines into a self-consistent bathymetry with a global optimization. Specifically, a multi-layer perceptron (MLP) with sine activation functions, known as SIREN [27] was used to represent the bathymetry where the gradients of the bathymetry were constrained by SSS intensities through a Lambertian model.…”

“…Specifically, a multi-layer perceptron (MLP) with sine activation functions, known as SIREN [27] was used to represent the bathymetry where the gradients of the bathymetry were constrained by SSS intensities through a Lambertian model. Extended from [7], a nadir model was proposed in [8] to model the nadir region in SSS waterfall images so that the optimization can converge without any external bathymetric data, e.g., altimeter readings. However, acoustic shadows cannot be explained by the Lambertian model in [8].…”

“…Nevertheless, one can address such a chicken-and-egg problem by iteratively improving the estimates of the bathymetry and the pose estimation. Following this principle, we present a framework † , NeuRSS, that leverages the advances of neural rendering to estimate bathymetry from SSS [7], [8], which provides an elevation prior addressing the degeneracy in SSS SLAM problems and showcase that one can significantly improve the AUV's DR estimate and subsequently produce high-quality bathymetry using SSS data from a standard survey.…”

“…The contribution of this work is to extend our previous work [7], [8], [21] and combine them into a new framework. For the sonar scattering model in [8], we extend it to be able to model shadows.…”

“…The contribution of this work is to extend our previous work [7], [8], [21] and combine them into a new framework. For the sonar scattering model in [8], we extend it to be able to model shadows. For the back-end of the SSS SLAM framework in [21], we extend it to a submap-based optimization with a prior map to better address the elevation degeneracy.…”

Towards Differentiable Rendering for Sidescan Sonar Imagery

“…However, the "ground truth" bathymetry is needed for creating a training set, which is not always practical underwater. Neural rendering [7], [8] methods that leverage the continuity and differentiablity of implicit neural representations have been recently proposed to fit many sidescan lines into a self-consistent bathymetry with a global optimization. Specifically, a multi-layer perceptron (MLP) with sine activation functions, known as SIREN [27] was used to represent the bathymetry where the gradients of the bathymetry were constrained by SSS intensities through a Lambertian model.…”

“…Specifically, a multi-layer perceptron (MLP) with sine activation functions, known as SIREN [27] was used to represent the bathymetry where the gradients of the bathymetry were constrained by SSS intensities through a Lambertian model. Extended from [7], a nadir model was proposed in [8] to model the nadir region in SSS waterfall images so that the optimization can converge without any external bathymetric data, e.g., altimeter readings. However, acoustic shadows cannot be explained by the Lambertian model in [8].…”

“…Nevertheless, one can address such a chicken-and-egg problem by iteratively improving the estimates of the bathymetry and the pose estimation. Following this principle, we present a framework † , NeuRSS, that leverages the advances of neural rendering to estimate bathymetry from SSS [7], [8], which provides an elevation prior addressing the degeneracy in SSS SLAM problems and showcase that one can significantly improve the AUV's DR estimate and subsequently produce high-quality bathymetry using SSS data from a standard survey.…”

“…The contribution of this work is to extend our previous work [7], [8], [21] and combine them into a new framework. For the sonar scattering model in [8], we extend it to be able to model shadows.…”

“…The contribution of this work is to extend our previous work [7], [8], [21] and combine them into a new framework. For the sonar scattering model in [8], we extend it to be able to model shadows. For the back-end of the SSS SLAM framework in [21], we extend it to a submap-based optimization with a prior map to better address the elevation degeneracy.…”

Towards Differentiable Rendering for Sidescan Sonar Imagery

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