Your search keyword '"Butler Hine"' showing total 4 results

1. Bioinspired Engineering of Exploration Systems: A Horizon Sensor/Attitude Reference System Based on the Dragonfly Ocelli for Mars Exploration Applications

Author

Sarita Thakoor, Naig Le Bouffant, Javaan Chahl, Mandyam V. Srinivasan, Gert Stange, Steven Zornetzer, and Butler Hine

Subjects

Attitude control, Engineering, Control and Systems Engineering, business.industry, Systems engineering, Control engineering, Robotics, Artificial intelligence, Exploration of Mars, business, Position control

Abstract

The intent of Bio-inspired Engineering of Exploration Systems (BEES) is to distill the principles found in successful, nature-tested mechanisms of specific crucial functions that are hard to accomplish by conventional methods, but accomplished rather deftly in nature by biological oganisms.

Published

2003

2. Bioinspired Engineering of Exploration Systems (BEES) - Its Impact on Future Missions

Author

Sarita Thakoor, Steven Zornetzer, and Butler Hine

Subjects

Engineering, Operability, business.industry, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Terrain, Mars Exploration Program, Exploration of Mars, Project team, Space exploration, Software deployment, Range (aeronautics), Systems engineering, business, Simulation

Abstract

This paper describes an overview of our "Bioinspired Engineering of Exploration Systems for Mars" ( "BEES for Mars") project. The BEES approach distills selected biologically inspired strategies utilizing motion cues/optic flow, bioinspired pattern recognition, biological visual and neural control systems, bioinspired sensing and communication techniques, and birds of prey inspired search and track algorithmic systems. Unique capabilities so enabled, provide potential solutions to future autonomous robotic space and planetary mission applications. With the first series of tests performed in September 2003, August 2004 and September 2004, we have demonstrated the BEES technologies at the El Mirage Dry Lakebed site in the Mojave Desert using Delta Wing experimental prototypes. We call these test flyers the "BEES flyer", since we are developing them as dedicated test platform for the newly developed bioinspired sensors, processors and algorithmic strategies. The Delta Wing offers a robust airframe that can sustain high G launches and offers ease of compact stowability and packaging along with scaling to small size and low ReynOld's number performance for a potential Mars deployment. Our approach to developing light weight, low power autonomous flight systems using concepts distilled from biology promises to enable new applications, of dual use to NASA and DoD needs. Small in size (0.5 -5 Kg) BEES Flyers are demonstrating capabilities for autonomous flight and sensor operability in Mars analog conditions. The BEES project team spans JPL, NASA Ames, Australian National University (ANU), Brigham Young University(BYU), DC Berkeiey, Analogic Computers Inc. and other institutions. The highlights from our recent flight demonstrations exhibiting new Mission enabling capabilities are described. Further, this paper describes two classes of potential new missions for Mars exploration: (1) the long range exploration missions, and (2) observation missions, for real time imaging of critical ephemeral phenomena, that can be enabled by use of BEES flyers. For example, such flyers can serve as a powerful black-box for critical descent and landing data and enablers for improved science missions complementing and supplementing the existing assets like landers and rovers by providing valuable exploration and quick extended low-altitude aerial coverage of the sites of interest by imaging them and distributing instruments to them. Imaging done by orbiters allows broad surface coverage at limited spatial resolution. Low altitude air-borne exploration of Mars offers a means for imaging large areas, perhaps up to several hundred kilometers, quickly and efficiently, providing a close-up birds-eye view of the planetary terrain and close-up approach to constrained difficult areas like canyons and craters. A novel approach to low-mass yet highly capable flyers is enabled by small aircraft equipped using sensors and processors and algorithms developed using BEES technology. This project is focused towards showing the direct impact of blending the best of artificial intelligence attributes and bioinspiration to create a leap beyond existing capability for our future Missions.

Published

2004

3. VEVI: A Virtual Environment Teleoperations Interface for Planetary Exploration

Author

Phil Hontalas, Erik Nygren, Laurent Piguet, Butler Hine, Terrence Fong, and Aaron Kline

Subjects

Engineering, Philosophy of design, business.industry, Interface (Java), Virtual reality, computer.software_genre, Human–computer interaction, Virtual machine, Robot, Architecture, business, Actuator, computer, Research center

Abstract

Remotely operating complex robotic mechanisms in unstructured natural environments is difficult at best. When the communications time delay is large, as for a Mars exploration rover operated from Earth, the difficulties become enormous. Conventional approaches, such as rate control of the rover actuators, are too inefficient and risky. The Intelligent Mechanisms Laboratory at the NASA Ames Research Center has developed over the past four years an architecture for operating science exploration robots in the presence of large communications time delays. The operator interface of this system is called the Virtual Environment Vehicle Interface (VEVI), and draws heavily on Virtual Environment (or Virtual Reality) technology. This paper describes the current operational version of VEVI, which we refer to as version 2.0. In this paper we will describe the VEVI design philosophy and implementation, and will describe some past examples of its use in field science exploration missions.

Published

1995

4. Operator Interfaces and Network-Based Participation for Dante II

Author

Henning Pangels, Terrence Fong, David Wettergreen, Phil Hontalas, Butler Hine, Christopher Fedor, and Erik Nygren

Subjects

Engineering, Operator (computer programming), Virtual machine, business.industry, Human–computer interaction, Communications satellite, Robot, Supervised control, computer.software_genre, business, computer, Mount

Abstract

Dante II, an eight-legged walking robot developed by the Dante project, explored the active volcanic crater of Mount Spurr in July 1994. In this paper, we describe the operator interfaces and the network-based participation methods used during the Dante II mission. Both virtual environment and multi-modal operator interfaces provided mission support for supervised control of Dante II. Network-based participation methods including message communications, satellite transmission, and a WorldWideWeb server enabled remote science and public interaction. We believe that these human-machine interfaces represent a significant advance in robotic technologies for exploration.

Published

1995