Experience based navigation : theory, practice and implementation

Churchill, W. S.

January 2012

For robotic systems to realise lifelong autonomy they must be able to navigate accurately in changing environments. In this thesis we describe, implement and validate a new approach to the problem of long-term navigation. To begin, we present our stereo visual odometry system which provides highly accurate pose estimation. Our approach combines several techniques found in existing implementations and a recently published image descriptor that simplifies the solution architecture. The performance and versatility of our system is demonstrated through testing on multiple datasets. Equipped with our visual odometry system, we describe a new approach to the problem of lifelong navigation. We learn a model whose complexity varies naturally in accordance with the variation of scene appearance. As the robot repeatedly traverses its workspace, it accumulates distinct visual experiences that, in concert, implicitly represent the scene variation - each experience captures a visual mode. When operating in a previously visited area, we continually try to localise in these previous experiences while simultaneously running the visual odometry. Failure to localise in a sufficient number of prior experiences indicates an insufficient model of the workspace and instigates the laying down of the live image sequence as a new distinct experience. In this way, over time we can capture the typical temporally varying appearance of an environment and the number of experiences required tends to a constant. Although we focus on vision as a primary sensor, the ideas we present here are equally applicable to other sensor modalities. We demonstrate our approach working on a road vehicle operating over a three month period at different times of day, in different weather and lighting conditions.

629.8

Řízení mobilního robota / Mobile robot control

Franěk, Dominik

January 2011

The goal of this work is design and realization of an autonomous mobile robot, capable of navigation and map creation, using stereoscopic camera and robotic operation system ROS. ** This is an added text for reaching minimal length needed for uploading into information system. **

Integrity Monitoring for Multiple Errors in Vision Navigation Systems

Baine, Nicholas Allen

29 May 2013

No description available.

Electrical Engineering

Vision Navigation

Integrity Monitoring

Navigation

Optical

Parity Space

GPS-denied multi-agent localization and terrain classification for autonomous parafoil systems

Chiel, Benjamin S.

05 November 2016

Guided airdrop parafoil systems depend on GPS for localization and landing. In some scenarios, GPS may be unreliable (jammed, spoofed, or disabled), or unavailable (indoor, or extraterrestrial environments). In the context of guided parafoils, landing locations for each system must be pre-programmed manually with global coordinates, which may be inaccurate or outdated, and offer no in-flight adaptability. Parafoil systems in particular have constrained motion, communication, and on-board computation and storage capabilities, and must operate in harsh conditions. These constraints necessitate a comprehensive approach to address the fundamental limitations of these systems when GPS cannot be used reliably. A novel and minimalist approach to visual navigation and multi-agent communication using semantic machine learning classification and geometric constraints is introduced. This approach enables localization and landing site identification for multiple communicating parafoil systems deployed in GPS-denied environments.

Mechanical engineering

Localization

Lost robot

Machine learning

Multi-agent

Semantic navigation

Vision navigation

Deep Learning Approach for Vision Navigation in Flight

McNally, Branden Timothy

January 2018

No description available.

Engineering

Deep Learning

Alternative Navigation

Vision Navigation

Image Based Navigation

Flight Navigation

Convolutional Neural Networks

Dense 3D Point Cloud Representation of a Scene Using Uncalibrated Monocular Vision

Diskin, Yakov

23 May 2013

No description available.

Electrical Engineering

Engineering

monocular vision

3D Scene Reconstruction

Dense Point-cloud Representation

Point Cloud Model

DPR

Super Resolutoin

Vision Lab

University of Dayton

Computer Vision

Vision Navigation

UAV

UAS

UGV

RAIDER

Yakov Diskin

Depth Resolution Enhancement