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1. Adaptive Robotic Information Gathering via non-stationary Gaussian processes

   https://doi.org/10.1177/02783649231184498  

   Chen, Weizhe; Khardon, Roni; Liu, Lantao (April 2024, The International Journal of Robotics Research)

   Robotic Information Gathering (RIG) is a foundational research topic that answers how a robot (team) collects informative data to efficiently build an accurate model of an unknown target function under robot embodiment constraints. RIG has many applications, including but not limited to autonomous exploration and mapping, 3D reconstruction or inspection, search and rescue, and environmental monitoring. A RIG system relies on a probabilistic model’s prediction uncertainty to identify critical areas for informative data collection. Gaussian processes (GPs) with stationary kernels have been widely adopted for spatial modeling. However, real-world spatial data is typically non-stationary—different locations do not have the same degree of variability. As a result, the prediction uncertainty does not accurately reveal prediction error, limiting the success of RIG algorithms. We propose a family of non-stationary kernels named Attentive Kernel (AK), which is simple and robust and can extend any existing kernel to a non-stationary one. We evaluate the new kernel in elevation mapping tasks, where AK provides better accuracy and uncertainty quantification over the commonly used stationary kernels and the leading non-stationary kernels. The improved uncertainty quantification guides the downstream informative planner to collect more valuable data around the high-error area, further increasing prediction accuracy. A field experiment demonstrates that the proposed method can guide an Autonomous Surface Vehicle (ASV) to prioritize data collection in locations with significant spatial variations, enabling the model to characterize salient environmental features. 

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2. Implications of Multivariate Non-Gaussian Data Assimilation for Multi-scale Weather Prediction

   https://doi.org/10.1175/MWR-D-21-0228.1  

   Poterjoy, Jonathan (March 2022, Monthly Weather Review)

   Abstract Weather prediction models currently operate within a probabilistic framework for generating forecasts conditioned on recent measurements of Earth’s atmosphere. This framework can be conceptualized as one that approximates parts of a Bayesian posterior density estimated under assumptions of Gaussian errors. Gaussian error approximations are appropriate for synoptic-scale atmospheric flow, which experiences quasi-linear error evolution over time scales depicted by measurements, but are often hypothesized to be inappropriate for highly nonlinear, sparsely-observed mesoscale processes. The current study adopts an experimental regional modeling system to examine the impact of Gaussian prior error approximations, which are adopted by ensemble Kalman filters (EnKFs) to generate probabilistic predictions. The analysis is aided by results obtained using recently-introduced particle filter (PF) methodology that relies on an implicit non-parametric representation of prior probability densities—but with added computational expense. The investigation focuses on EnKF and PF comparisons over month-long experiments performed using an extensive domain, which features the development and passage of numerous extratropical and tropical cyclones. The experiments reveal spurious small-scale corrections in EnKF members, which come about from inappropriate Gaussian approximations for priors dominated by alignment uncertainty in mesoscale weather systems. Similar behavior is found in PF members, owing to the use of a localization operator, but to a much lesser extent. This result is reproduced and studied using a low-dimensional model, which permits the use of large sample estimates of the Bayesian posterior distribution. Findings from this study motivate the use of data assimilation techniques that provide a more appropriate specification of multivariate non-Gaussian prior densities or a multi-scale treatment of alignment errors during data assimilation. 

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3. Multi-view Sensor Fusion by Integrating Model-based Estimation and Graph Learning for Collaborative Object Localization

   https://doi.org/10.1109/ICRA48506.2021.9561810  

   Gao, Peng; Guo, Rui; Lu, Hongsheng; Zhang, Hao (May 2021, IEEE International Conference on Robotics and Automation (ICRA))

   Collaborative object localization aims to collaboratively estimate locations of objects observed from multiple views or perspectives, which is a critical ability for multi-agent systems such as connected vehicles. To enable collaborative localization, several model-based state estimation and learning-based localization methods have been developed. Given their encouraging performance, model-based state estimation often lacks the ability to model the complex relationships among multiple objects, while learning-based methods are typically not able to fuse the observations from an arbitrary number of views and cannot well model uncertainty. In this paper, we introduce a novel spatiotemporal graph filter approach that integrates graph learning and model-based estimation to perform multi-view sensor fusion for collaborative object localization. Our approach models complex object relationships using a new spatiotemporal graph representation and fuses multi-view observations in a Bayesian fashion to improve location estimation under uncertainty. We evaluate our approach in the applications of connected autonomous driving and multiple pedestrian localization. Experimental results show that our approach outperforms previous techniques and achieves the state-of-the-art performance on collaborative localization. 

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4. Navigating Uncertainty: Ambiguity Quantification in Fingerprinting-based Indoor Localization

   https://doi.org/10.1109/AIoT63253.2024.00033  

   Ma, Junwei; Wang, Xiangyu; Zhang, Jian; Mao, Shiwen; Periaswamy, Senthilkumar_C G; Patton, Justin (July 2024, IEEE)

   In this paper, we present a conformal prediction (CP) based method to evaluate the performance of a finger-printing localization system through uncertainty quantification. The proposed method emphasizes a standalone module that is compatible with any well-trained fingerprint classifier without incurring extra training costs. It provides rigorous statistical guarantees for revealing true labels in the fingerprinting multi-class classification problems with high efficiency. Uncertainty quantification of the predictions is accomplished by leveraging a small calibration dataset and a given error tolerance level. Three specific metrics are introduced to quantify the uncertainty of the CP-based method from the perspective of efficiency, adaptivity, and accuracy, respectively. The proposed method allows developers to track the model state with minimal effort and evaluate the reliability of their model and measurements, such as in a dynamic environment. The proposed technique, therefore, prevents the intrinsic label inaccuracy and the additional labor cost of ground truth collection. We evaluate the proposed method and metrics in two representative indoor environments using vanilla fingerprint-based localization models with extensive experiments. Our experimental results show that the proposed method can successfully quantify the uncertainty of predictions. 

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5. Uncertainty Quantification in Inverse Models in Hydrology

   Chatterjee, Somya Sharma; Ghosh, Rahul; Renganathan, Arvind; Li, Xiang; Chatterjee, Snigdhansu; Nieber, John; Duffy, Christopher; Kumar, Vipin (August 2023, ACM)

   In hydrology, modeling streamflow remains a challenging task due to the limited availability of basin characteristics information such as soil geology and geomorphology. These characteristics may be noisy due to measurement errors or may be missing altogether. To overcome this challenge, we propose a knowledge-guided, probabilistic inverse modeling method for recovering physical characteristics from streamflow and weather data, which are more readily available. We compare our framework with state-of-the-art inverse models for estimating river basin characteristics. We also show that these estimates offer improvement in streamflow modeling as opposed to using the original basin characteristic values. Our inverse model offers a 3% improvement in R2 for the inverse model (basin characteristic estimation) and 6% for the forward model (streamflow prediction). Our framework also offers improved explainability since it can quantify uncertainty in both the inverse and the forward model. Uncertainty quantification plays a pivotal role in improving the explainability of machine learning models by providing additional insights into the reliability and limitations of model predictions. In our analysis, we assess the quality of the uncertainty estimates. Compared to baseline uncertainty quantification methods, our framework offers a 10% improvement in the dispersion of epistemic uncertainty and a 13% improvement in coverage rate. This information can help stakeholders understand the level of uncertainty associated with the predictions and provide a more comprehensive view of the potential outcomes. 

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