 |
|
Underwater robots work together without human input
August 02, 2006This August in Monterey Bay, Calif., an entire fleet of undersea robots will for the first time work together without the aid of humans to make detailed and efficient observations of the ocean.
The oceanographic test bed in Monterey is expected to yield rich information in particular about a periodic upwelling of cold water that occurs at this time of year near Point Año Nuevo, northwest of Monterey Bay.
But the project has potentially larger implications. It may lead to the development of robot fleets that forecast ocean conditions and better protect endangered marine animals, track oil spills, and guide military operations at sea. Moreover, the mathematical system that allows the undersea robots to self-choreograph their movements in response to their environment might one day power other robotic teams that - without human supervision - could explore not just oceans, but deserts, rain forests and even other planets.
In addition, the ability to coordinate autonomous vehicles - a challenge inspired by the grace of bird flocks and fish schools - may give biologists greater insight into the highly efficient behaviors of animals.
The August field experiment is the centerpiece of a three-year program known as Adaptive Sampling and Prediction (ASAP), which is funded by the Office of Naval Research. The two co-leaders of ASAP are Naomi Ehrich Leonard of Princeton University and Steven Ramp of the Naval Postgraduate School.
The multidisciplinary team of ASAP investigators - who come together from more than a dozen prestigious research institutions - consists of physical oceanographers, marine biologists and researchers in control and dynamics.
During the experiment, the ASAP system will determine what paths the underwater robots should follow to take the most information-rich samples, or measurements, of ocean activity. As the ocean changes, automated computer programs will update the sampling strategy under the supervision of the ASAP team. Most of the scientists will not be on site during the actual field experiment. The team will collaborate while the experiment is ongoing through a virtual control room, something like a chat room for the ASAP scientists. The researchers will gather online in the virtual control room to share observations and make important decisions about necessary changes to the field operation as it is under way.
The underwater robots, known as gliders, will take the ocean's temperature, measure its salinity (salt content), estimate the currents and track the upwelling. Two types of gliders will be deployed - Spray gliders and Slocum gliders. The Slocum gliders belong to David Fratantoni of the Woods Hole Oceanographic Institution; the Spray gliders to Russ Davis of the Scripps Institution of Oceanography.
The numerical ocean modeling will be performed independently by Pierre Lermusiaux of Harvard, Yi Chao of NASA's Jet Propulsion Laboratory, Igor Shulman of the U.S. Naval Research Laboratory, and Sharan Majumdar of the University of Miami. Using powerful supercomputers, the oceanographic modelers collect and evaluate all of the ocean measurements to predict future ocean conditions.
In contrast to typical ocean-observing systems, which are static, the mobility of the gliders allows them to capture the dynamic nature of the ocean, which is always shifting in time and space. Furthermore, the gliders will be coordinated onto patterns to ensure that as they move, the measurements they take are as information-rich as possible.
Inspired by the behavior of schools of fish, Naomi Ehrich Leonard's group at Princeton has created algorithms that allow the gliders to self-choreograph their movements in a series of rectangular patterns. The patterns span a large volume that the scientists have mapped in Monterey Bay (imagine a giant aquarium with porous walls that is 20 kilometers wide, 40 kilometers long, and roughly 400 meters deep).
On a day-to-day basis the control algorithms allow the gliders to make decisions independently about how to alter their course - without any input from humans. This day-to-day autonomy enables the gliders to move according to the organized patterns, even as they are buffeted by strong currents.
As the ocean changes and new features are detected in the measurements and the forecasts, the ASAP team will reorganize the patterns to help guide the gliders toward ocean features of interest such as eddies and thermal fronts. This process, called "adaptive sampling," is expected to dramatically improve our knowledge of the ocean and our ability to predict its chaotic behavior.
In addition to gliders, the ASAP ocean-observing network also includes research ships, surveillance aircraft, propeller-driven vehicles, fixed buoy sensors and coastal radar mapping. The ASAP field operation is one of four marine research initiatives taking place during the summer in Monterey Bay. Collectively known as MB 2006, these four programs are hosted by the Monterey Bay Aquarium Research Institute (MBARI) in Moss Landing, Calif. MBARI will host a media day Aug. 23 featuring scientists showcasing the results of these projects.
Princeton University
In addition, the ability to coordinate autonomous vehicles - a challenge inspired by the grace of bird flocks and fish schools - may give biologists greater insight into the highly efficient behaviors of animals.
The August field experiment is the centerpiece of a three-year program known as Adaptive Sampling and Prediction (ASAP), which is funded by the Office of Naval Research. The two co-leaders of ASAP are Naomi Ehrich Leonard of Princeton University and Steven Ramp of the Naval Postgraduate School.
The multidisciplinary team of ASAP investigators - who come together from more than a dozen prestigious research institutions - consists of physical oceanographers, marine biologists and researchers in control and dynamics.
During the experiment, the ASAP system will determine what paths the underwater robots should follow to take the most information-rich samples, or measurements, of ocean activity. As the ocean changes, automated computer programs will update the sampling strategy under the supervision of the ASAP team. Most of the scientists will not be on site during the actual field experiment. The team will collaborate while the experiment is ongoing through a virtual control room, something like a chat room for the ASAP scientists. The researchers will gather online in the virtual control room to share observations and make important decisions about necessary changes to the field operation as it is under way.
The underwater robots, known as gliders, will take the ocean's temperature, measure its salinity (salt content), estimate the currents and track the upwelling. Two types of gliders will be deployed - Spray gliders and Slocum gliders. The Slocum gliders belong to David Fratantoni of the Woods Hole Oceanographic Institution; the Spray gliders to Russ Davis of the Scripps Institution of Oceanography.
The numerical ocean modeling will be performed independently by Pierre Lermusiaux of Harvard, Yi Chao of NASA's Jet Propulsion Laboratory, Igor Shulman of the U.S. Naval Research Laboratory, and Sharan Majumdar of the University of Miami. Using powerful supercomputers, the oceanographic modelers collect and evaluate all of the ocean measurements to predict future ocean conditions.
In contrast to typical ocean-observing systems, which are static, the mobility of the gliders allows them to capture the dynamic nature of the ocean, which is always shifting in time and space. Furthermore, the gliders will be coordinated onto patterns to ensure that as they move, the measurements they take are as information-rich as possible.
Inspired by the behavior of schools of fish, Naomi Ehrich Leonard's group at Princeton has created algorithms that allow the gliders to self-choreograph their movements in a series of rectangular patterns. The patterns span a large volume that the scientists have mapped in Monterey Bay (imagine a giant aquarium with porous walls that is 20 kilometers wide, 40 kilometers long, and roughly 400 meters deep).
On a day-to-day basis the control algorithms allow the gliders to make decisions independently about how to alter their course - without any input from humans. This day-to-day autonomy enables the gliders to move according to the organized patterns, even as they are buffeted by strong currents.
As the ocean changes and new features are detected in the measurements and the forecasts, the ASAP team will reorganize the patterns to help guide the gliders toward ocean features of interest such as eddies and thermal fronts. This process, called "adaptive sampling," is expected to dramatically improve our knowledge of the ocean and our ability to predict its chaotic behavior.
In addition to gliders, the ASAP ocean-observing network also includes research ships, surveillance aircraft, propeller-driven vehicles, fixed buoy sensors and coastal radar mapping. The ASAP field operation is one of four marine research initiatives taking place during the summer in Monterey Bay. Collectively known as MB 2006, these four programs are hosted by the Monterey Bay Aquarium Research Institute (MBARI) in Moss Landing, Calif. MBARI will host a media day Aug. 23 featuring scientists showcasing the results of these projects.
Princeton University
Rensselaer Researcher To Showcase New Solar Underwater Robot Technology at Exhibition on State-of-the-Art U.S. Robotic Vehicles
A new solar-powered underwater robot technology developed for undersea observation and water monitoring will be showcased at a Sept. 16 workshop on leading-edge robotics to be held at the National Science Foundation (NSF) in Arlington, Va.
Bermuda 'rectangle' beckons for UK's leading unmanned underwater vehicle
Next week (2-3 September), marine technologists from around the world will gather in Southampton to take part in the largest ever Unmanned Underwater Vehicle Showcase (UUVS 98).
More Underwater Robots News Articles
| Build Your Own Underwater Robot and Other Wet Projects by Harry Bohm | |
 | Underwater Robots: Motion and Force Control of Vehicle-Manipulator Systems (Springer Tracts in Advanced Robotics) by Gianluca Antonelli This book deals with the main control aspects in underwater manipulation tasks. The mathematical model with significant impact on the control strategy is discussed. The problem of controlling a 6-degrees-of-freedoms autonomous underwater vehicle is deeply investigated and a survey of fault detection/tolerant strategies for unmanned underwater vehicles is provided; experimental results obtained... |
| Underwater robots.(Navy Adjusts Course for): An article from: National Defense by Sandra I. Erwin This digital document is an article from National Defense, published by National Defense Industrial Association on May 1, 2004. The length of the article is 1141 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation... | |
 | A Visual Servoing System for an Amphibious Legged Robot: Vision-based Robotics and Control in Natural Underwater Environments by Junaed Sattar We present a visual servoing system for an amphibious legged robot. This is a monocular-vision based servoing mechanism that enables the robot to track and follow a target both underwater and on the ground. We use three different tracking algorithms to track and localize the target in the image, with color being the tracked feature. Tracking is performed based on the color of the target object,... |
| Underwater Robots Underwater Robots reports on the latest progress in underwater robotics. In spite of its importance, the ocean is generally overlooked, since we focus more of our attention on land and atmospheric issues. We have not yet been able to explore the full depths of the ocean and its resources. The deep oceans range between 19000 to 36000 feet. At a mere 33-foot depth, the pressure is twice the... | |
| Build Your Own Underwater Robot by Harry Bohm | |
| Advances in grasping and vehicle contact identification: Analysis, design and testing of robust methods for underwater robot manipulation (MIT/WHOI) by Edward Ramsey Snow |
| © 2008 BrightSurf.com |