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1. Learning to Swim: Reinforcement Learning for 6-DOF Control of Thruster-driven Autonomous Underwater Vehicles

Author

Cai, Levi, Chang, Kevin, and Girdhar, Yogesh

Subjects
Computer Science - Robotics
Abstract

Controlling AUVs can be challenging because of the effect of complex non-linear hydrodynamic forces acting on the robot, which, unlike ground robots, are significant in water and cannot be ignored. The problem is especially challenging for small AUVs for which the dynamics can change significantly with payload changes and deployments under different water conditions. The common approach to AUV control is a combination of passive stabilization with added buoyancy on top and weights on the bottom, and a PID controller tuned for simple and smooth motion primitives. However, the approach comes at the cost of sluggish controls and often the need to re-tune controllers with configuration changes. We propose a fast (trainable in minutes), reinforcement learning based approach for full 6 degree of freedom (DOF) control of an AUV, enabled by a new, highly parallelized simulator for underwater vehicle dynamics. We demonstrate that the proposed simulator models approximate hydrodynamic forces with enough accuracy that a zero-shot transfer of the learned policy to a real robot produces performance comparable to a hand-tuned PID controller. Furthermore, we show that domain randomization on the simulator produces policies that are robust to small variations in vehicle's physical parameters.

Published
2024

2. SeaSplat: Representing Underwater Scenes with 3D Gaussian Splatting and a Physically Grounded Image Formation Model

Author

Yang, Daniel, Leonard, John J., and Girdhar, Yogesh

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Robotics
Abstract

We introduce SeaSplat, a method to enable real-time rendering of underwater scenes leveraging recent advances in 3D radiance fields. Underwater scenes are challenging visual environments, as rendering through a medium such as water introduces both range and color dependent effects on image capture. We constrain 3D Gaussian Splatting (3DGS), a recent advance in radiance fields enabling rapid training and real-time rendering of full 3D scenes, with a physically grounded underwater image formation model. Applying SeaSplat to the real-world scenes from SeaThru-NeRF dataset, a scene collected by an underwater vehicle in the US Virgin Islands, and simulation-degraded real-world scenes, not only do we see increased quantitative performance on rendering novel viewpoints from the scene with the medium present, but are also able to recover the underlying true color of the scene and restore renders to be without the presence of the intervening medium. We show that the underwater image formation helps learn scene structure, with better depth maps, as well as show that our improvements maintain the significant computational improvements afforded by leveraging a 3D Gaussian representation., Comment: Project page here: https://seasplat.github.io

Published
2024

3. ReefGlider: A highly maneuverable vectored buoyancy engine based underwater robot

Author

Macauley, Kevin, Cai, Levi, Adamczyk, Peter, and Girdhar, Yogesh

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

There exists a capability gap in the design of currently available autonomous underwater vehicles (AUV). Most AUVs use a set of thrusters, and optionally control surfaces, to control their depth and pose. AUVs utilizing thrusters can be highly maneuverable, making them well-suited to operate in complex environments such as in close-proximity to coral reefs. However, they are inherently power-inefficient and produce significant noise and disturbance. Underwater gliders, on the other hand, use changes in buoyancy and center of mass, in combination with a control surface to move around. They are extremely power efficient but not very maneuverable. Gliders are designed for long-range missions that do not require precision maneuvering. Furthermore, since gliders only activate the buoyancy engine for small time intervals, they do not disturb the environment and can also be used for passive acoustic observations. In this paper we present ReefGlider, a novel AUV that uses only buoyancy for control but is still highly maneuverable from additional buoyancy control devices. ReefGlider bridges the gap between the capabilities of thruster-driven AUVs and gliders. These combined characteristics make ReefGlider ideal for tasks such as long-term visual and acoustic monitoring of coral reefs. We present the overall design and implementation of the system, as well as provide analysis of some of its capabilities., Comment: In IEEE International Conference on Robotics and Automation (ICRA), 2024

Published
2024

4. Robot Goes Fishing: Rapid, High-Resolution Biological Hotspot Mapping in Coral Reefs with Vision-Guided Autonomous Underwater Vehicles

Author

Yang, Daniel, Cai, Levi, Jamieson, Stewart, and Girdhar, Yogesh

Subjects
Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition
Abstract

Coral reefs are fast-changing and complex ecosystems that are crucial to monitor and study. Biological hotspot detection can help coral reef managers prioritize limited resources for monitoring and intervention tasks. Here, we explore the use of autonomous underwater vehicles (AUVs) with cameras, coupled with visual detectors and photogrammetry, to map and identify these hotspots. This approach can provide high spatial resolution information in fast feedback cycles. To the best of our knowledge, we present one of the first attempts at using an AUV to gather visually-observed, fine-grain biological hotspot maps in concert with topography of a coral reefs. Our hotspot maps correlate with rugosity, an established proxy metric for coral reef biodiversity and abundance, as well as with our visual inspections of the 3D reconstruction. We also investigate issues of scaling this approach when applied to new reefs by using these visual detectors pre-trained on large public datasets., Comment: CV4Animals Workshop at CVPR 2023

Published
2023

5. DeepSeeColor: Realtime Adaptive Color Correction for Autonomous Underwater Vehicles via Deep Learning Methods

Author

Jamieson, Stewart, How, Jonathan P., and Girdhar, Yogesh

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Robotics
Abstract

Successful applications of complex vision-based behaviours underwater have lagged behind progress in terrestrial and aerial domains. This is largely due to the degraded image quality resulting from the physical phenomena involved in underwater image formation. Spectrally-selective light attenuation drains some colors from underwater images while backscattering adds others, making it challenging to perform vision-based tasks underwater. State-of-the-art methods for underwater color correction optimize the parameters of image formation models to restore the full spectrum of color to underwater imagery. However, these methods have high computational complexity that is unfavourable for realtime use by autonomous underwater vehicles (AUVs), as a result of having been primarily designed for offline color correction. Here, we present DeepSeeColor, a novel algorithm that combines a state-of-the-art underwater image formation model with the computational efficiency of deep learning frameworks. In our experiments, we show that DeepSeeColor offers comparable performance to the popular "Sea-Thru" algorithm (Akkaynak & Treibitz, 2019) while being able to rapidly process images at up to 60Hz, thus making it suitable for use onboard AUVs as a preprocessing step to enable more robust vision-based behaviours., Comment: 7 pages, 5 figures, 2 tables. Presented at the 2023 International Conference on Robotics and Automation (ICRA)

Published
2023

6. CUREE: A Curious Underwater Robot for Ecosystem Exploration

Author

Girdhar, Yogesh, McGuire, Nathan, Cai, Levi, Jamieson, Stewart, McCammon, Seth, Claus, Brian, Soucie, John E. San, Todd, Jessica E., and Mooney, T. Aran

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition
Abstract

The current approach to exploring and monitoring complex underwater ecosystems, such as coral reefs, is to conduct surveys using diver-held or static cameras, or deploying sensor buoys. These approaches often fail to capture the full variation and complexity of interactions between different reef organisms and their habitat. The CUREE platform presented in this paper provides a unique set of capabilities in the form of robot behaviors and perception algorithms to enable scientists to explore different aspects of an ecosystem. Examples of these capabilities include low-altitude visual surveys, soundscape surveys, habitat characterization, and animal following. We demonstrate these capabilities by describing two field deployments on coral reefs in the US Virgin Islands. In the first deployment, we show that CUREE can identify the preferred habitat type of snapping shrimp in a reef through a combination of a visual survey, habitat characterization, and a soundscape survey. In the second deployment, we demonstrate CUREE's ability to follow arbitrary animals by separately following a barracuda and stingray for several minutes each in midwater and benthic environments, respectively., Comment: 7 pages

Published
2023
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7. Semi-Supervised Visual Tracking of Marine Animals using Autonomous Underwater Vehicles

Author

Cai, Levi, McGuire, Nathan E., Hanlon, Roger, Mooney, T. Aran, and Girdhar, Yogesh

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Machine Learning, Computer Science - Robotics
Abstract

In-situ visual observations of marine organisms is crucial to developing behavioural understandings and their relations to their surrounding ecosystem. Typically, these observations are collected via divers, tags, and remotely-operated or human-piloted vehicles. Recently, however, autonomous underwater vehicles equipped with cameras and embedded computers with GPU capabilities are being developed for a variety of applications, and in particular, can be used to supplement these existing data collection mechanisms where human operation or tags are more difficult. Existing approaches have focused on using fully-supervised tracking methods, but labelled data for many underwater species are severely lacking. Semi-supervised trackers may offer alternative tracking solutions because they require less data than fully-supervised counterparts. However, because there are not existing realistic underwater tracking datasets, the performance of semi-supervised tracking algorithms in the marine domain is not well understood. To better evaluate their performance and utility, in this paper we provide (1) a novel dataset specific to marine animals located at http://warp.whoi.edu/vmat/, (2) an evaluation of state-of-the-art semi-supervised algorithms in the context of underwater animal tracking, and (3) an evaluation of real-world performance through demonstrations using a semi-supervised algorithm on-board an autonomous underwater vehicle to track marine animals in the wild., Comment: To appear in IJCV SI: Animal Tracking

Published
2023
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9. Streaming Gaussian Dirichlet Random Fields for Spatial Predictions of High Dimensional Categorical Observations

Author

Soucie, John E. San, Sosik, Heidi M., Girdhar, Yogesh, Siciliano, Bruno, Series Editor, Khatib, Oussama, Series Editor, Antonelli, Gianluca, Advisory Editor, Fox, Dieter, Advisory Editor, Harada, Kensuke, Advisory Editor, Hsieh, M. Ani, Advisory Editor, Kröger, Torsten, Advisory Editor, Kulic, Dana, Advisory Editor, Park, Jaeheung, Advisory Editor, and Ang Jr, Marcelo H., editor

Published
2024
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11. Multi-Robot Distributed Semantic Mapping in Unfamiliar Environments through Online Matching of Learned Representations

Author

Jamieson, Stewart, Fathian, Kaveh, Khosoussi, Kasra, How, Jonathan P., and Girdhar, Yogesh

Subjects
Computer Science - Robotics, Computer Science - Multiagent Systems
Abstract

We present a solution to multi-robot distributed semantic mapping of novel and unfamiliar environments. Most state-of-the-art semantic mapping systems are based on supervised learning algorithms that cannot classify novel observations online. While unsupervised learning algorithms can invent labels for novel observations, approaches to detect when multiple robots have independently developed their own labels for the same new class are prone to erroneous or inconsistent matches. These issues worsen as the number of robots in the system increases and prevent fusing the local maps produced by each robot into a consistent global map, which is crucial for cooperative planning and joint mission summarization. Our proposed solution overcomes these obstacles by having each robot learn an unsupervised semantic scene model online and use a multiway matching algorithm to identify consistent sets of matches between learned semantic labels belonging to different robots. Compared to the state of the art, the proposed solution produces 20-60% higher quality global maps that do not degrade even as many more local maps are fused., Comment: 7 pages, 6 figures, 1 table; accepted for presentation in IEEE Int. Conf. on Robotics and Automation, ICRA '21, Xi'an, China, June 2021

Published
2021

12. Seeing Through your Skin: Recognizing Objects with a Novel Visuotactile Sensor

Author

Hogan, Francois Robert, Jenkin, Michael, Rezaei-Shoshtari, Sahand, Girdhar, Yogesh, Meger, David, and Dudek, Gregory

Subjects
Computer Science - Robotics
Abstract

We introduce a new class of vision-based sensor and associated algorithmic processes that combine visual imaging with high-resolution tactile sending, all in a uniform hardware and computational architecture. We demonstrate the sensor's efficacy for both multi-modal object recognition and metrology. Object recognition is typically formulated as an unimodal task, but by combining two sensor modalities we show that we can achieve several significant performance improvements. This sensor, named the See-Through-your-Skin sensor (STS), is designed to provide rich multi-modal sensing of contact surfaces. Inspired by recent developments in optical tactile sensing technology, we address a key missing feature of these sensors: the ability to capture a visual perspective of the region beyond the contact surface. Whereas optical tactile sensors are typically opaque, we present a sensor with a semitransparent skin that has the dual capabilities of acting as a tactile sensor and/or as a visual camera depending on its internal lighting conditions. This paper details the design of the sensor, showcases its dual sensing capabilities, and presents a deep learning architecture that fuses vision and touch. We validate the ability of the sensor to classify household objects, recognize fine textures, and infer their physical properties both through numerical simulations and experiments with a smart countertop prototype., Comment: A version of this paper appears in WACV 2021

Published
2020

13. Gaussian-Dirichlet Random Fields for Inference over High Dimensional Categorical Observations

Author

Soucie, John E. San, Sosik, Heidi M., and Girdhar, Yogesh

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning, Computer Science - Robotics, I.2.9
Abstract

We propose a generative model for the spatio-temporal distribution of high dimensional categorical observations. These are commonly produced by robots equipped with an imaging sensor such as a camera, paired with an image classifier, potentially producing observations over thousands of categories. The proposed approach combines the use of Dirichlet distributions to model sparse co-occurrence relations between the observed categories using a latent variable, and Gaussian processes to model the latent variable's spatio-temporal distribution. Experiments in this paper show that the resulting model is able to efficiently and accurately approximate the temporal distribution of high dimensional categorical measurements such as taxonomic observations of microscopic organisms in the ocean, even in unobserved (held out) locations, far from other samples. This work's primary motivation is to enable deployment of informative path planning techniques over high dimensional categorical fields, which until now have been limited to scalar or low dimensional vector observations., Comment: 8 pages, 10 figures, accepted to proceedings of International Conference on Robotics and Automation (ICRA) 2020

Published
2020

14. Active Reward Learning for Co-Robotic Vision Based Exploration in Bandwidth Limited Environments

Author

Jamieson, Stewart, How, Jonathan P., and Girdhar, Yogesh

Subjects
Computer Science - Robotics, Computer Science - Artificial Intelligence
Abstract

We present a novel POMDP problem formulation for a robot that must autonomously decide where to go to collect new and scientifically relevant images given a limited ability to communicate with its human operator. From this formulation we derive constraints and design principles for the observation model, reward model, and communication strategy of such a robot, exploring techniques to deal with the very high-dimensional observation space and scarcity of relevant training data. We introduce a novel active reward learning strategy based on making queries to help the robot minimize path "regret" online, and evaluate it for suitability in autonomous visual exploration through simulations. We demonstrate that, in some bandwidth-limited environments, this novel regret-based criterion enables the robotic explorer to collect up to 17% more reward per mission than the next-best criterion., Comment: 7 pages, 4 figures; accepted for presentation in IEEE Int. Conf. on Robotics and Automation, ICRA '20, Paris, France, June 2020

Published
2020
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15. Information-Guided Robotic Maximum Seek-and-Sample in Partially Observable Continuous Environments

Author

Flaspohler, Genevieve, Preston, Victoria, Michel, Anna P. M., Girdhar, Yogesh, and Roy, Nicholas

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

We present PLUMES, a planner to localizing and collecting samples at the global maximum of an a priori unknown and partially observable continuous environment. The "maximum-seek-and-sample" (MSS) problem is pervasive in the environmental and earth sciences. Experts want to collect scientifically valuable samples at an environmental maximum (e.g., an oil-spill source), but do not have prior knowledge about the phenomenon's distribution. We formulate the MSS problem as a partially-observable Markov decision process (POMDP) with continuous state and observation spaces, and a sparse reward signal. To solve the MSS POMDP, PLUMES uses an information-theoretic reward heuristic with continous-observation Monte Carlo Tree Search to efficiently localize and sample from the global maximum. In simulation and field experiments, PLUMES collects more scientifically valuable samples than state-of-the-art planners in a diverse set of environments, with various platforms, sensors, and challenging real-world conditions., Comment: 8 pages, 8 figures, To appear in the proceedings of IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) 2019 Macau

Published
2019
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16. Streaming Scene Maps for Co-Robotic Exploration in Bandwidth Limited Environments

Author

Girdhar, Yogesh, Cai, Levi, Jamieson, Stewart, McGuire, Nathan, Flaspohler, Genevieve, Suman, Stefano, and Claus, Brian

Subjects
Computer Science - Robotics
Abstract

This paper proposes a bandwidth tunable technique for real-time probabilistic scene modeling and mapping to enable co-robotic exploration in communication constrained environments such as the deep sea. The parameters of the system enable the user to characterize the scene complexity represented by the map, which in turn determines the bandwidth requirements. The approach is demonstrated using an underwater robot that learns an unsupervised scene model of the environment and then uses this scene model to communicate the spatial distribution of various high-level semantic scene constructs to a human operator. Preliminary experiments in an artificially constructed tank environment as well as simulated missions over a 10m$\times$10m coral reef using real data show the tunability of the maps to different bandwidth constraints and science interests. To our knowledge this is the first paper to quantify how the free parameters of the unsupervised scene model impact both the scientific utility of and bandwidth required to communicate the resulting scene model., Comment: 8 pages, 6 figures, accepted for presentation in IEEE Int. Conf. on Robotics and Automation, ICRA '19, Montreal, Canada, May 2019

Published
2019
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17. Feature discovery and visualization of robot mission data using convolutional autoencoders and Bayesian nonparametric topic models

Author

Flaspohler, Genevieve, Roy, Nicholas, and Girdhar, Yogesh

Subjects
Computer Science - Learning, Statistics - Machine Learning
Abstract

The gap between our ability to collect interesting data and our ability to analyze these data is growing at an unprecedented rate. Recent algorithmic attempts to fill this gap have employed unsupervised tools to discover structure in data. Some of the most successful approaches have used probabilistic models to uncover latent thematic structure in discrete data. Despite the success of these models on textual data, they have not generalized as well to image data, in part because of the spatial and temporal structure that may exist in an image stream. We introduce a novel unsupervised machine learning framework that incorporates the ability of convolutional autoencoders to discover features from images that directly encode spatial information, within a Bayesian nonparametric topic model that discovers meaningful latent patterns within discrete data. By using this hybrid framework, we overcome the fundamental dependency of traditional topic models on rigidly hand-coded data representations, while simultaneously encoding spatial dependency in our topics without adding model complexity. We apply this model to the motivating application of high-level scene understanding and mission summarization for exploratory marine robots. Our experiments on a seafloor dataset collected by a marine robot show that the proposed hybrid framework outperforms current state-of-the-art approaches on the task of unsupervised seafloor terrain characterization., Comment: 8 pages

Published
2017
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18. Near-optimal irrevocable sample selection for periodic data streams with applications to marine robotics

Author

Flaspohler, Genevieve, Roy, Nicholas, and Girdhar, Yogesh

Subjects
Computer Science - Robotics, Computer Science - Data Structures and Algorithms
Abstract

We consider the task of monitoring spatiotemporal phenomena in real-time by deploying limited sampling resources at locations of interest irrevocably and without knowledge of future observations. This task can be modeled as an instance of the classical secretary problem. Although this problem has been studied extensively in theoretical domains, existing algorithms require that data arrive in random order to provide performance guarantees. These algorithms will perform arbitrarily poorly on data streams such as those encountered in robotics and environmental monitoring domains, which tend to have spatiotemporal structure. We focus on the problem of selecting representative samples from phenomena with periodic structure and introduce a novel sample selection algorithm that recovers a near-optimal sample set according to any monotone submodular utility function. We evaluate our algorithm on a seven-year environmental dataset collected at the Martha's Vineyard Coastal Observatory and show that it selects phytoplankton sample locations that are nearly optimal in an information-theoretic sense for predicting phytoplankton concentrations in locations that were not directly sampled. The proposed periodic secretary algorithm can be used with theoretical performance guarantees in many real-time sensing and robotics applications for streaming, irrevocable sample selection from periodic data streams., Comment: 8 pages, accepted for presentation in IEEE Int. Conf. on Robotics and Automation, ICRA '18, Brisbane, Australia, May 2018

Published
2017

19. Learning Seasonal Phytoplankton Communities with Topic Models

Author

Kalmbach, Arnold, Sosik, Heidi M., Dudek, Gregory, and Girdhar, Yogesh

Subjects
Statistics - Applications, Computer Science - Computational Engineering, Finance, and Science
Abstract

In this work we develop and demonstrate a probabilistic generative model for phytoplankton communities. The proposed model takes counts of a set of phytoplankton taxa in a timeseries as its training data, and models communities by learning sparse co-occurrence structure between the taxa. Our model is probabilistic, where communities are represented by probability distributions over the species, and each time-step is represented by a probability distribution over the communities. The proposed approach uses a non-parametric, spatiotemporal topic model to encourage the communities to form an interpretable representation of the data, without making strong assumptions about the communities. We demonstrate the quality and interpretability of our method by its ability to improve performance of a simplistic regression model. We show that simple linear regression is sufficient to predict the community distribution learned by our method, and therefore the taxon distributions, from a set of naively chosen environment variables. In contrast, a similar regression model is insufficient to predict the taxon distributions directly or through PCA with the same level of accuracy.

Published
2017

20. Phytoplankton Hotspot Prediction With an Unsupervised Spatial Community Model

Author

Kalmbach, Arnold, Girdhar, Yogesh, Sosik, Heidi M., and Dudek, Gregory

Subjects
Computer Science - Robotics, Statistics - Applications
Abstract

Many interesting natural phenomena are sparsely distributed and discrete. Locating the hotspots of such sparsely distributed phenomena is often difficult because their density gradient is likely to be very noisy. We present a novel approach to this search problem, where we model the co-occurrence relations between a robot's observations with a Bayesian nonparametric topic model. This approach makes it possible to produce a robust estimate of the spatial distribution of the target, even in the absence of direct target observations. We apply the proposed approach to the problem of finding the spatial locations of the hotspots of a specific phytoplankton taxon in the ocean. We use classified image data from Imaging FlowCytobot (IFCB), which automatically measures individual microscopic cells and colonies of cells. Given these individual taxon-specific observations, we learn a phytoplankton community model that characterizes the co-occurrence relations between taxa. We present experiments with simulated robot missions drawn from real observation data collected during a research cruise traversing the US Atlantic coast. Our results show that the proposed approach outperforms nearest neighbor and k-means based methods for predicting the spatial distribution of hotspots from in-situ observations., Comment: To appear in ICRA 2017, Singapore

Published
2017

22. Assessment of attraction and avoidance behaviors of fish in response to the proximity of transiting underwater vehicles

Author

Campbell, Matthew D., Huddleston, Ariane, Somerton, David, Clarke, M. Elizabeth, Wakefield, Waldo, Murawski, Steve, Taylor, Chris, Singh, Hanumant, Girdhar, Yogesh, and Yoklavich, Mary

Subjects
Animal behavior -- Analysis, Fishes -- Analysis, Zoology and wildlife conservation
Abstract

High-relief, complex seafloor habitats (e.g., rock and coral reef) present a number of challenges for the deployment of traditional fishing gears, such as seines, gill nets, bottom trawls, and longlines. [...]

Published
2021
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23. Modeling Curiosity in a Mobile Robot for Long-Term Autonomous Exploration and Monitoring

Author

Girdhar, Yogesh and Dudek, Gregory

Subjects
Computer Science - Robotics, Computer Science - Computer Vision and Pattern Recognition, Computer Science - Learning
Abstract

This paper presents a novel approach to modeling curiosity in a mobile robot, which is useful for monitoring and adaptive data collection tasks, especially in the context of long term autonomous missions where pre-programmed missions are likely to have limited utility. We use a realtime topic modeling technique to build a semantic perception model of the environment, using which, we plan a path through the locations in the world with high semantic information content. The life-long learning behavior of the proposed perception model makes it suitable for long-term exploration missions. We validate the approach using simulated exploration experiments using aerial and underwater data, and demonstrate an implementation on the Aqua underwater robot in a variety of scenarios. We find that the proposed exploration paths that are biased towards locations with high topic perplexity, produce better terrain models with high discriminative power. Moreover, we show that the proposed algorithm implemented on Aqua robot is able to do tasks such as coral reef inspection, diver following, and sea floor exploration, without any prior training or preparation., Comment: 20 pages, in-press, Autonomous Robots, 2015. arXiv admin note: substantial text overlap with arXiv:1310.6767

Published
2015
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24. Anomaly Detection in Unstructured Environments using Bayesian Nonparametric Scene Modeling

Author

Girdhar, Yogesh, Cho, Walter, Campbell, Matthew, Pineda, Jesus, Clarke, Elizabeth, and Singh, Hanumant

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Robotics
Abstract

This paper explores the use of a Bayesian non-parametric topic modeling technique for the purpose of anomaly detection in video data. We present results from two experiments. The first experiment shows that the proposed technique is automatically able characterize the underlying terrain, and detect anomalous flora in image data collected by an underwater robot. The second experiment shows that the same technique can be used on images from a static camera in a dynamic unstructured environment. In the second dataset, consisting of video data from a static seafloor camera capturing images of a busy coral reef, the proposed technique was able to detect all three instances of an underwater vehicle passing in front of the camera, amongst many other observations of fishes, debris, lighting changes due to surface waves, and benthic flora., Comment: 6 pages, ICRA 2016

Published
2015

25. Gibbs Sampling Strategies for Semantic Perception of Streaming Video Data

Author

Girdhar, Yogesh and Dudek, Gregory

Subjects
Computer Science - Robotics, Computer Science - Learning
Abstract

Topic modeling of streaming sensor data can be used for high level perception of the environment by a mobile robot. In this paper we compare various Gibbs sampling strategies for topic modeling of streaming spatiotemporal data, such as video captured by a mobile robot. Compared to previous work on online topic modeling, such as o-LDA and incremental LDA, we show that the proposed technique results in lower online and final perplexity, given the realtime constraints.

Published
2015

26. Curiosity Based Exploration for Learning Terrain Models

Author

Girdhar, Yogesh, Whitney, David, and Dudek, Gregory

Subjects
Computer Science - Robotics
Abstract

We present a robotic exploration technique in which the goal is to learn to a visual model and be able to distinguish between different terrains and other visual components in an unknown environment. We use ROST, a realtime online spatiotemporal topic modeling framework to model these terrains using the observations made by the robot, and then use an information theoretic path planning technique to define the exploration path. We conduct experiments with aerial view and underwater datasets with millions of observations and varying path lengths, and find that paths that are biased towards locations with high topic perplexity produce better terrain models with high discriminative power, especially with paths of length close to the diameter of the world., Comment: 7 pages, 5 figures, submitted to ICRA 2014

Published
2013
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31. Toward a New Era of Coral Reef Monitoring

Author

Apprill, Amy, primary, Girdhar, Yogesh, additional, Mooney, T. Aran, additional, Hansel, Colleen M., additional, Long, Matthew H., additional, Liu, Yaqin, additional, Zhang, W. Gordon, additional, Kapit, Jason, additional, Hughen, Konrad, additional, Coogan, Jeff, additional, and Greene, Austin, additional

Published
2023
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33. Semi-supervised Visual Tracking of Marine Animals Using Autonomous Underwater Vehicles

Author

Woods Hole Oceanographic Institution, Cai, Levi, McGuire, Nathan E., Hanlon, Roger, Mooney, T. A., Girdhar, Yogesh, Woods Hole Oceanographic Institution, Cai, Levi, McGuire, Nathan E., Hanlon, Roger, Mooney, T. A., and Girdhar, Yogesh

Abstract

In-situ visual observations of marine organisms is crucial to developing behavioural understandings and their relations to their surrounding ecosystem. Typically, these observations are collected via divers, tags, and remotely-operated or human-piloted vehicles. Recently, however, autonomous underwater vehicles equipped with cameras and embedded computers with GPU capabilities are being developed for a variety of applications, and in particular, can be used to supplement these existing data collection mechanisms where human operation or tags are more difficult. Existing approaches have focused on using fully-supervised tracking methods, but labelled data for many underwater species are severely lacking. Semi-supervised trackers may offer alternative tracking solutions because they require less data than fully-supervised counterparts. However, because there are not existing realistic underwater tracking datasets, the performance of semi-supervised tracking algorithms in the marine domain is not well understood. To better evaluate their performance and utility, in this paper we provide (1) a novel dataset specific to marine animals located at http://warp.whoi.edu/vmat/ , (2) an evaluation of state-of-the-art semi-supervised algorithms in the context of underwater animal tracking, and (3) an evaluation of real-world performance through demonstrations using a semi-supervised algorithm on-board an autonomous underwater vehicle to track marine animals in the wild.

Published
2023

37. Active Reward Learning for Co-Robotic Vision Based Exploration in Bandwidth Limited Environments

Author

Joint Program in Applied Ocean Physics and Engineering, Woods Hole Oceanographic Institution, Jamieson, Stewart Christopher., How, Jonathan P, Girdhar, Yogesh, Joint Program in Applied Ocean Physics and Engineering, Woods Hole Oceanographic Institution, Jamieson, Stewart Christopher., How, Jonathan P, and Girdhar, Yogesh

Abstract

© 2020 IEEE. We present a novel POMDP problem formulation for a robot that must autonomously decide where to go to collect new and scientifically relevant images given a limited ability to communicate with its human operator. From this formulation we derive constraints and design principles for the observation model, reward model, and communication strategy of such a robot, exploring techniques to deal with the very high-dimensional observation space and scarcity of relevant training data. We introduce a novel active reward learning strategy based on making queries to help the robot minimize path regret online, and evaluate it for suitability in autonomous visual exploration through simulations. We demonstrate that, in some bandwidth-limited environments, this novel regret-based criterion enables the robotic explorer to collect up to 17% more reward per mission than the next-best criterion.

Published
2021

38. Information-Guided Robotic Maximum Seek-and-Sample in Partially Observable Continuous Environments

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Woods Hole Oceanographic Institution, Flaspohler, Genevieve, Preston, Victoria, Michel, Anna PM, Girdhar, Yogesh, Roy, Nicholas, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Woods Hole Oceanographic Institution, Flaspohler, Genevieve, Preston, Victoria, Michel, Anna PM, Girdhar, Yogesh, and Roy, Nicholas

Published
2021

41. Near-optimal irrevocable sample selection for periodic data streams with applications to marine robotics

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Flaspohler, Genevieve Elaine, Roy, Nicholas, Girdhar, Yogesh, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Flaspohler, Genevieve Elaine, Roy, Nicholas, and Girdhar, Yogesh

Abstract

We consider the task of monitoring spatiotemporal phenomena in real-time by deploying limited sampling resources at locations of interest irrevocably and without knowledge of future observations. This task can be modeled as an instance of the classical secretary problem. Although this problem has been studied extensively in theoretical domains, existing algorithms require that data arrive in random order to provide performance guarantees. These algorithms will perform arbitrarily poorly on data streams such as those encountered in robotics and environmental monitoring domains, which tend to have spatiotemporal structure. We focus on the problem of selecting representative samples from phenomena with periodic structure and introduce a novel sample selection algorithm that recovers a near-optimal sample set according to any monotone submodular utility function. We evaluate our algorithm on a seven-year environmental dataset collected at the Martha’s Vineyard Coastal Observatory and show that it selects phytoplankton sample locations that are nearly optimal in an information-theoretic sense for predicting phytoplankton concentrations in locations that were not directly sampled. The proposed periodic secretary algorithm can be used with theoretical performance guarantees in many real-time sensing and robotics applications for streaming, irrevocable sample selection from periodic data streams.

Published
2020

42. Approximate Distributed Spatiotemporal Topic Models for Multi-Robot Terrain Characterization

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Woods Hole Oceanographic Institution, Doherty, Kevin, Flaspohler, Genevieve Elaine, Roy, Nicholas, Girdhar, Yogesh, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Woods Hole Oceanographic Institution, Doherty, Kevin, Flaspohler, Genevieve Elaine, Roy, Nicholas, and Girdhar, Yogesh

Abstract

Unsupervised learning techniques, such as Bayesian topic models, are capable of discovering latent structure directly from raw data. These unsupervised models can endow robots with the ability to learn from their observations without human supervision, and then use the learned models for tasks such as autonomous exploration, adaptive sampling, or surveillance. This paper extends single-robot topic models to the domain of multiple robots. The main difficulty of this extension lies in achieving and maintaining global consensus among the unsupervised models learned locally by each robot. This is especially challenging for multi-robot teams operating in communication-constrained environments, such as marine robots. We present a novel approach for multi-robot distributed learning in which each robot maintains a local topic model to categorize its observations and model parameters are shared to achieve global consensus. We apply a combinatorial optimization procedure that combines local robot topic distributions into a globally consistent model based on topic similarity, which we find mitigates topic drift when compared to a baseline approach that matches topics naïvely, We evaluate our methods experimentally by demonstrating multi-robot underwater terrain characterization using simulated missions on real seabed imagery. Our proposed method achieves similar model quality under bandwidth-constraints to that achieved by models that continuously communicate, despite requiring less than one percent of the data transmission needed for continuous communication., National Science Foundation (Award 1734400)

Published
2020

48. Detection of unanticipated faults for autonomous underwater vehicles using online topic models

Author

Raanan, Ben-Yair, Bellingham, James G., Zhang, Yanwu, Kemp, Mathieu, Kieft, Brian, Singh, Hanumant, Girdhar, Yogesh, Raanan, Ben-Yair, Bellingham, James G., Zhang, Yanwu, Kemp, Mathieu, Kieft, Brian, Singh, Hanumant, and Girdhar, Yogesh

Abstract

© The Author(s), 2017. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Journal of Field Robotics 35 (2018): 705-716, doi:10.1002/rob.21771., For robots to succeed in complex missions, they must be reliable in the face of subsystem failures and environmental challenges. In this paper, we focus on autonomous underwater vehicle (AUV) autonomy as it pertains to self‐perception and health monitoring, and we argue that automatic classification of state‐sensor data represents an important enabling capability. We apply an online Bayesian nonparametric topic modeling technique to AUV sensor data in order to automatically characterize its performance patterns, then demonstrate how in combination with operator‐supplied semantic labels these patterns can be used for fault detection and diagnosis by means of a nearest‐neighbor classifier. The method is evaluated using data collected by the Monterey Bay Aquarium Research Institute's Tethys long‐range AUV in three separate field deployments. Our results show that the proposed method is able to accurately identify and characterize patterns that correspond to various states of the AUV, and classify faults at a high rate of correct detection with a very low false detection rate., Office of Naval Research Grant Number: N00014‐14‐1‐0199; David and Lucile Packard Foundation

Published
2018

49. Feature discovery and visualization of robot mission data using convolutional autoencoders and Bayesian nonparametric topic models

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Flaspohler, Genevieve Elaine, Roy, Nicholas, Girdhar, Yogesh, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Massachusetts Institute of Technology. Department of Aeronautics and Astronautics, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Flaspohler, Genevieve Elaine, Roy, Nicholas, and Girdhar, Yogesh

Abstract

© 2017 IEEE. The gap between our ability to collect interesting data and our ability to analyze these data is growing at an unprecedented rate. Recent algorithmic attempts to fill this gap have employed unsupervised tools to discover structure in data. Some of the most successful approaches have used probabilistic models to uncover latent thematic structure in discrete data. Despite the success of these models on textual data, they have not generalized as well to image data, in part because of the spatial and temporal structure that may exist in an image stream. We introduce a novel unsupervised machine learning framework that incorporates the ability of convolutional autoencoders to discover features from images that directly encode spatial information, within a Bayesian nonparametric topic model that discovers meaningful latent patterns within discrete data. By using this hybrid framework, we overcome the fundamental dependency of traditional topic models on rigidly hand-coded data representations, while simultaneously encoding spatial dependency in our topics without adding model complexity. We apply this model to the motivating application of high-level scene understanding and mission summarization for exploratory marine robots. Our experiments on a seafloor dataset collected by a marine robot show that the proposed hybrid framework outperforms current state-of-the-art approaches on the task of unsupervised seafloor terrain characterization., NSF Graduate Research Fellowship Program award, The John P. Chase Memorial Endowed Fund

Published
2018

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