Your search keyword '"Sujoy Ganguly"' showing total 4 results

1. Technology readiness levels for machine learning systems

Author

Alexander Lavin, Ciarán M. Gilligan-Lee, Alessya Visnjic, Siddha Ganju, Dava Newman, Sujoy Ganguly, Danny Lange, Atílím Güneş Baydin, Amit Sharma, Adam Gibson, Stephan Zheng, Eric P. Xing, Chris Mattmann, James Parr, and Yarin Gal

Subjects

FOS: Computer and information sciences, Technology, Computer Science - Machine Learning, Multidisciplinary, Computer Science - Artificial Intelligence, General Physics and Astronomy, General Chemistry, General Biochemistry, Genetics and Molecular Biology, Machine Learning (cs.LG), Software Engineering (cs.SE), Machine Learning, Computer Science - Software Engineering, Artificial Intelligence (cs.AI), Engineering, Artificial Intelligence, Humans, Software

Abstract

The development and deployment of machine learning (ML) systems can be executed easily with modern tools, but the process is typically rushed and means-to-an-end. The lack of diligence can lead to technical debt, scope creep and misaligned objectives, model misuse and failures, and expensive consequences. Engineering systems, on the other hand, follow well-defined processes and testing standards to streamline development for high-quality, reliable results. The extreme is spacecraft systems, where mission critical measures and robustness are ingrained in the development process. Drawing on experience in both spacecraft engineering and ML (from research through product across domain areas), we have developed a proven systems engineering approach for machine learning development and deployment. Our "Machine Learning Technology Readiness Levels" (MLTRL) framework defines a principled process to ensure robust, reliable, and responsible systems while being streamlined for ML workflows, including key distinctions from traditional software engineering. Even more, MLTRL defines a lingua franca for people across teams and organizations to work collaboratively on artificial intelligence and machine learning technologies. Here we describe the framework and elucidate it with several real world use-cases of developing ML methods from basic research through productization and deployment, in areas such as medical diagnostics, consumer computer vision, satellite imagery, and particle physics.

Published

2022

2. Technology Readiness Levels for Machine Learning Systems

Author

Yarin Gal, Chris A. Mattmann, Alexander Lavin, Danny Lange, Siddha Ganju, Ciarán M. Gilligan-Lee, Sujoy Ganguly, Dava J. Newman, Adam Gibson, Alessya Visnjic, James Parr, Amit Sharma, Eric P. Xing, and Atılım Güneş Baydin

Subjects

Technology readiness, Spacecraft, business.industry, Computer science, media_common.quotation_subject, Mission critical, Machine learning, computer.software_genre, Diligence, Software deployment, Robustness (computer science), Technical debt, Scope creep, Artificial intelligence, business, computer, media_common

Abstract

The development and deployment of machine learning (ML) systems can be executed easily with modern tools, but the process is typically rushed and means-to-an-end. The lack of diligence can lead to technical debt, scope creep and misaligned objectives, model misuse and failures, and expensive consequences. Engineering systems, on the other hand, follow well-defined processes and testing standards to streamline development for high-quality, reliable results. The extreme is spacecraft systems, where mission critical measures and robustness are ingrained in the development process. Drawing on experience in both spacecraft engineering and ML (from research through product across domain areas), we have developed a proven systems engineering approach for machine learning development and deployment. Our Machine Learning Technology Readiness Levels (MLTRL) framework defines a principled process to ensure robust, reliable, and responsible systems while being streamlined for ML workflows, including key distinctions from traditional software engineering. Even more, MLTRL defines a lingua franca for people across teams and organizations to work collaboratively on artificial intelligence and machine learning technologies. Here we describe the framework and elucidate it with several real world use-cases of developing ML methods from basic research through productization and deployment, in areas such as medical diagnostics, consumer computer vision, satellite imagery, and particle physics.

Published

2021

3. End-to-End Camera Calibration for Broadcast Videos

Author

Panna Felsen, Sujoy Ganguly, Jennifer Hobbs, Xinyu Wei, Patrick Lucey, and Long Sha

Subjects

Computer science, business.industry, Calibration (statistics), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, 020207 software engineering, Tracking system, 02 engineering and technology, Image segmentation, 01 natural sciences, 010309 optics, End-to-end principle, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Segmentation, Computer vision, Artificial intelligence, business, Pose, Homography (computer vision), Camera resectioning

Abstract

The increasing number of vision-based tracking systems deployed in production have necessitated fast, robust camera calibration. In the domain of sport, the majority of current work focuses on sports where lines and intersections are easy to extract, and appearance is relatively consistent across venues. However, for more challenging sports like basketball, those techniques are not sufficient. In this paper, we propose an end-to-end approach for single moving camera calibration across challenging scenarios in sports. Our method contains three key modules: 1) area-based court segmentation, 2) camera pose estimation with embedded templates, 3) homography prediction via a spatial transform network (STN). All three modules are connected, enabling end-to-end training. We evaluate our method on a new college basketball dataset and demonstrate state of the art performance in variable and dynamic environments. We also validate our method on the World Cup 2014 dataset to show its competitive performance against the state-of-the-art methods. Lastly, we show that our method is two orders of magnitude faster than the previous state of the art on both datasets.

Published

2020

4. Where Will They Go? Predicting Fine-Grained Adversarial Multi-agent Motion Using Conditional Variational Autoencoders

Author

Panna Felsen, Patrick Lucey, and Sujoy Ganguly

Subjects

0209 industrial biotechnology, Computer science, business.industry, Volume (computing), 020207 software engineering, 02 engineering and technology, Autoencoder, Motion (physics), Adversarial system, 020901 industrial engineering & automation, 0202 electrical engineering, electronic engineering, information engineering, State (computer science), Artificial intelligence, Focus (optics), business

Abstract

Simultaneously and accurately forecasting the behavior of many interacting agents is imperative for computer vision applications to be widely deployed (e.g., autonomous vehicles, security, surveillance, sports). In this paper, we present a technique using conditional variational autoencoder which learns a model that “personalizes” prediction to individual agent behavior within a group representation. Given the volume of data available and its adversarial nature, we focus on the sport of basketball and show that our approach efficiently predicts context-specific agent motions. We find that our model generates results that are three times as accurate as previous state of the art approaches (5.74 ft vs. 17.95 ft).

Published

2018