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Project
Description:
In our contemporary
world, the large-scale coordination of numerous tasks in hazardous,
uncertain, and time stressed environments is becoming increasing
difficult, yet vital. In natural and man-made disasters, de-mining
situatons, environmental cleanup operations, civilian and military
crisis responses, for example, different organizations such as
fire fighters, police, and medical assistance personnel need to
cooperate in order to save lives, protect structural infrastructure
and property, and evacuate victims to safety.
In such environments,
human rescuers must make quick decisions under stress, and get
victims to safety (often at their own risk). They must have timely
and accurate information on the status of the infrastructure--real-time
information regarding other parts of the disaster area, expected
arrival times for additional resources, such as medical supplies
and additional firefighters--and they must coordinate the allocation
of resources and other rescue activities.
Today, disaster
relief is performed mostly by humans and trained dogs. The rescue
workers communicate face to face, via telephones or walkie-talkies;
the gathering of needed information (e.g. telephone numbers of
physicians in the area) is performed manually or through searches
in known databases. Such manual operations are inadequate to meet
the daunting challenges of large-scale emergency response. First,
humans could make sub-optimal or even wrong decisions under the
emotional burden of the situation and the cognitive overload caused
by large amount of information that comes in. Second, human rescuers
have to risk their lives to get victims to safety. Third, relevant
information may not get accessed, integrated and distributed rapidly
enough.
One solution
to addressing the limitations of current manual operations is
to introduce enhanced automation. There are a multitude of characteristics
in large-scale disaster relief environments that appropriate design
of automation should address. These environments are inherently
distributed; the infrastructure, the victims, and the rescuers
are distributed across extended locations. The environments change
unpredictably; buildings and other infrastructure elements could
collapse, occluding entrances; fires may start, etc. Communications
may be intermittent or non-existent, hence partial and incomplete
information is the norm rather than the exception. Making timely
decisions and actions as quickly as possible is crucial for saving
lives.
To address these challenges requires fundamental research advances
in the design of distributed systems that would effectively coordinate
with dispersed humans. Our proposed research is founded on three
key advances/technical ideas. We propose Hybrid Teams of Autonomous
Agents: Cyber Agents, Robots and People (CARPs) consisting
of large number of these entities that are distributed in space,
time, capability, and roles. We move away from the traditional
human-controlled design of automation, where automated systems
are subordinate to their human controllers who give them their
goals and tasks and manage task execution. Instead, we advocate
a cooperative control (adjustable autonomy) paradigm where current
notions of organizational control and system interactions are
extended based on adaptive sharing.
The various
members of CARP groups, be they human, robots or cyber-agents
could share common goals, share initiative for communication and
action, share responsibility for coherent group activity, share
information on the environment, mission, situation and share in
helping each other in overcoming barriers to achievement of common
goals. Ad hoc interoperability across different agents, teams
and organizations are brought together "as is", and co-adaptation
to each other addresses the challenges present in such large-scale,
uncertain coordination domains.
Team Members: usar-list at cs.cmu.edu
Katia Sycara sycara at cs.cmu.edu
Illah Nourbakhsh illah at cs.cmu.edu
Mike Lewis ml at sis.pitt.edu
Anton Chechetka antonc at andrew.cmu.edu
Mary Koes mberna at cs.cmu.edu
Jay Kim jayeonk at andrew.cmu.edu
Jijun Wang jiw1+ at pitt.edu
Alumni
Steve Burion
Jeff Gennari
Tomek Loboda
Joe Manojlovich
Kevin Oishi
Shambhavi Patel
Jumo Polvichai
Steve Shamlian
Mark Yong
Josh Young
News
- Simulated
rubble field tests search and rescue robots, by Byron
Spice, Pittsburgh Post-Gazette Science Editor. Nourbakhsh
and his CMU colleague Katia Sycara, along with Michael Weiss,
an information technology scientist at the University of Pittsburgh,
have received a $1.4 million, four-year grant from the National
Science Foundation to examine how robots, humans and intelligent
agents can best work together.
Presentations
Publications
I. Nourbakhsh,
M. Lewis, K. Sycara, M. Koes, M. Yong, and S. Burion, "Human-Robot
Teaming for Search and Rescue," in IEEE Pervasive
Computing Vol. 4, No. 1, Jan-Mar. 2005.
M. Berna-Koes,
I. Nourbakhsh, and K. Sycara. "Communication
Efficiency in Multi-agent Systems," in Proceedings of ICRA
2004. New Orleans, LA. April 26-May 1, 2004.
If
you are not in our group and wish receive access to USAR software
download, please print the the CMU License Agreement:
- Read
carefully and if you agree to the terms, complete the bottom
portion of the Agreement. Include your name, institutional affiliation
and address, a url for the website that describes your group's
or your own research activities, your email address, and, if
you are a student, the name, position, url and email address
of your advisor. Please sign and date the agreement.
- Send
the completed agreement to us by mail at:
Joseph
Giampapa
The Robotics Institute
5000 Forbes Avenue
PIttsburgh, PA 15213
- We
will send qualified users a user name and password via email,
so that you can access the executable by downloading Communicator
Library v1.4.1_Apr2003 (Jar) from the downloads page, here.
Related
Links
Robotics Institute Project Page
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