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Dr Maurice Fallon

Professor

Maurice Fallon PhD (Cantab)

Royal Society University Research Fellow

Associate Professor

Biography

Maurice Fallon is an Associate Professor and Royal Society University Research Fellowship. He is also a Research Fellow of Wolfson College. He leads the Dynamic Robot Systems Group within Oxford Robotics Institute. DRS develops algorithms for navigating quadrupeds, motion planning algorithms to allow quadrupeds to move more smoothly and accurately.

Prof. Fallon studied Electronic Engineering at University College Dublin. His PhD research in the field of acoustic source tracking was carried out in the Engineering Department of the University of Cambridge.

Immediately after his PhD he moved to MIT as a post-doc and later as a research scientist in the Marine Robotics Group (2008-2012) working in robot mapping. From 2012-2015 he was the perception lead of MIT's team in the DARPA Robotics Challenge – a multi-year competition developing technologies for semi-autonomous humanoid exploration and manipulation in disaster situations.

Recent Developments

The Oxford Robotics Institute are playing a key role in two of the four Robotics Hubs funded by the EPSRC as part of their £44.5 million investment over the next three and a half years into Robotics and Artificial intelligence (AI). More details here.

Researcher from Prof. Fallon's group contributed to Team Cerberus in the DARPA Subterranean Challenge - developing a team of robots to explore mines and caves. The finals of the 'SubT' were held in a huge mine in Louisville in September 2021. Cerberus won the top prize of $2m.  More details here.

Most Recent Publications

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

View all

Research Interests

Prof. Fallon's research is focused on probabilistic methods for localization and mapping. His research focus on state estimation and mapping for dynamic robots (quadrupeds, handheld devices and even drones). He is also interested in dynamic motion planning and control. He focuses on developing methods which are robust in challenging situations (darkness, underground, outdoors) using probabilistic sensor fusion.

Current Projects

THING: Haptic locomotion and sensing for quadrupeds (EU H2020)

MEMMO: Generating complex robot motions with a Memory of Motion (EU H2020)

RAIN: Robotics and AI research for the Nuclear Industry (EPSRC Research Hub)

ORCA: Robotics for the Oil and Gas Industry (EPSRC Research Hub)

SubT: Team Cerberus in the DARPA Subterranean (SubT) Challenge

Most Recent Publications

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

View all

DPhil Opportunities

I am interested in supervising research students in navigation, mapping and motion planning for robots, particularly dynamic and/or legged robots.

Most Recent Publications

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

Extrinsic Calibration of Camera to LIDAR Using a Differentiable Checkerboard Model

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

InstaLoc: one-shot global lidar localisation in indoor environments through instance learning

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

Batch Differentiable Pose Refinement for In-The-Wild Camera/LiDAR Extrinsic Calibration

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

M-LIO: Multi-lidar, multi-IMU odometry with sensor dropout tolerance

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

Factor Graph Fusion of Raw GNSS Sensing with IMU and Lidar for Precise Robot Localization without a Base Station

View all