Robot League

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Rescue Robot League Overview


The RoboCupRescue Robot League is an international league of teams with one objective: Develop and demonstrate advanced robotic capabilities for emergency responders using annual competitions to evaluate, and teaching camps to disseminate, best-in-class robotic solutions. The RoboCupRescue has also a Simulation League.


The league hosts annual competitions to 1) increase awareness of the challenges involved in deploying robots for emergency response applications such as urban search and rescue and bomb disposal, 2) provide objective performance evaluations of mobile robots operating in complex yet repeatable environments, and 3) promote collaboration between researchers. Robot teams demonstrate their capabilities in mobility, sensory perception, localization and mapping, mobile manipulation, practical operator interfaces, and assistive autonomous behaviors to improve remote operator performance and/or robot survivability while searching for simulated victims in a maze of terrains and challenges. Winning teams must reliably perform 7-10 missions of 20-30 minutes each from various start points to find the most victims. As robots continue to demonstrate successes against the obstacles posed in the arenas, the level of difficulty will continually be increased so the arenas provide a stepping-stone from the laboratory to the real world. Meanwhile, the annual competitions provide direct comparison of robotic approaches, objective performance evaluations, and a public proving ground for capable robotic systems that will ultimately be used to save lives.

Competition Vision

When disaster happens, minimize risk to search and rescue personnel while increasing victim survival rates by fielding teams of collaborative mobile robots which enable human rescuers to quickly locate and extract victims. Specific robotic capabilities encouraged in the competition include the following: 

  • Negotiate compromised and collapsed structures
  • Locate victims and ascertain their conditions
  • Produce practical sensor maps of the environment
  • Establish communications with victims
  • Deliver fluids, nourishment, medicines
  • Emplace sensors to identify/monitor hazards
  • Mark or identify best paths to victims
  • Provide structural shoring for responders

These tasks are encouraged through challenges posed in the arena, specific mission tasks, and/or the performance metric. Demonstrations of other enabling robotic capabilities are always welcome.

Search Scenario

A building has partially collapsed due to earthquake. The Incident Commander in charge of rescue operations at the disaster site, fearing secondary collapses from aftershocks, has asked for teams of robots to immediately search the interior of the building for victims. The mission for the robots and their operators is to find victims, determine their situation, state, and location, and then report back their findings in a map of the building with associated victim data. The section near the building entrance appears relatively intact while the interior of the structure exhibits increasing degrees of collapse. Robots must negotiate and map the lightly damaged areas prior to encountering more challenging obstacles and rubble. The robots are considered expendable in case of difficulty.

Field Description

The RoboCupRescue arenas constructed to host these competitions consist of emerging standard test methods for emergency response robots developed by the U.S. National Institute of Standards and Technology through the ASTM International Committee on Homeland Security Applications; Operational Equipment; Robots (E54.08.01). They are repeatable test method apparatuses that anybody can build and practice. The competition field is divided into color-coded arenas that form a continuum of challenges with increasing levels of difficulty for robots and operators and highlight certain robotic capabilities:

  • Simulated Victims: Simulated victims with several signs of life such as form, motion, head, sound and CO2 are distributed throughout the arenas requiring directional viewing through access holes at different elevations.
  • Yellow Arena: For robots capable of fully autonomous navigation and victim identification, this arena consists of random mazes of hallways and rooms with continuous 15° pitch and roll ramp flooring.
  • Orange Arena: For robots capable of autonomous or remote teleoperative navigation and victim identification, this arena consists of moderate terrains with crossing 15° pitch and roll ramps and structured obstacles such as stairs, inclined planes, and others.
  • Red Arena: For robots capable of autonomous or remote teleoperative navigation and victim identification, this arena consists of complex stepfield terrains requiring advanced robot mobility.
  • Blue Arena: For robots capable of mobile manipulation on complex terrains to place simple block or bottle payloads carried in from the start or picked up within the arenas.
  • Black/Yellow Arena (RADIO DROP-OUT ZONE): For robots capable of autonomous navigation with reasonable mobility to operate on complex terrains.
  • Black Arena (Vehicle Collapse Scenario): For robots capable of searching a simulated vehicle collapse scenario accessible on each side from the RED ARENA and the ORANGE ARENA.
  • Aerial Arena (< 2 KG, VTOL sUAS): For small unmanned aerial systems under 2 kg with vertical take-off and landing capabilities that can perform station-keeping, obstacle avoidance, and line following tasks with varying degrees of autonomy.
  • Also new in 2016 will be an outdoor test: The objective here is to transport material (such as lumber for shoring or drilling tools) autonomously to the disaster site. On the way back, bring victims to the paramedics, again autonomously. The area for the task will be about 50 m by 100 m. The transportation has to be done strictly autonomously - no teleoperation is allowed. There will be three different levels of difficulty for the outdoor test:
  1. Line following: A clearly visible line shows the way from the start point to the goal. The robot can use its vision system to follow this line. When it arrives at the end point, the team can manually turn the robot and send it back to the start point. This continuous until the time is up. The winner is the robot that achieved the longest distance.
  2. Dense GPS way points (UTM coordinates, zone 33). The teams are provided with a dense list (approximately every 2 m) of way points that guides the robot from the start point to the target area. When it arrives at the end point, the robot can turn and drive it back to the start point. No manual interaction is allowed. This continuous until the time is up. The winner is the robot that achieved the longest distance.
  3. Sparse GPS way points (UTM coordinates, zone 33). Same as (2.), but way points are only given for important landmarks such as turns and crossings. Objects might block the direct connection between two way points, so the robot must deal with these obstacles and find paths around them.


  • Trustees
    • Adam Jacoff, National Institute of Standards and Technology, USA (Trustee Emeritus)
    • Satoshi Tadokoro, Tohoku University, Japan (Trustee Emeritus)
  • Executive Committee
    • Johannes Pellenz, University of Koblenz-Landau, Germany (Exec 2013-2016)
    • Jafar Chegini,Iran (Exec 2015-2018)
    • Jackrit Suthakorn, Mahidol University, Thailand (Exec 2015-2017)
    • Raymond Sheh, Australia (Exec 2015-2017)
    • Andreas Birk, International University Bremen, Germany (Exec Emeritus)
    • Tetsuya Kimura, Nagaoka Univ. of Technology, Japan (Exec Emeritus)
  • Technical Committee
    • Gerald Steinbauer, Austria (TC 2012-2015)
    • Tetsuya Kimura, Nagaoka Univ. of Technology, Japan (TC 2015-2017)
    • Masayuki Okugawa, Japan (TC 2015-2018)
    • Sören Schwertfeger, Germany (Emeritus)

  • Organizing Committee
    • Local Chair: Masayuki Okugaw (Aichi Institute of Technology, Japan)
    • Adam Jacoff (NIST, USA)
    • Ann Virts (NIST, USA)
    • Ehsan Mihankhah (Singapore)
    • Johannes Pellenz (BAAINBw, Germany)
    • Gerald Steinbauer (TU Graz, Austria)


RoboCup Rescue Complete Rule Book

NEW 2016 Rule Book UPDATED

Hazmat Labels that will be used during the competition.

Qualification Process

The RoboCupRescue Robot League encourages participation by interested organizations from around the world, but limits participation to one team per organization. Regional open competitions are hosted around the world to provide essential practice deployment experience for teams and to support qualification of teams for the World Championship competition each year. The World Championship includes a maximum of 5 teams from each regional open competition, which are typically the three awardees and up to two more teams based on the previous year’s awards, Best-In-Class demonstrations in the current year, and other considerations noted below.

RoboCupRescue Robot League regional open competitions are hosted in Japan, Germany, Iran, Thailand, Mexico, and we are actively trying (but need help from locals) to establish regional open competitions in other areas as well. All teams should use regional open competitions to:

  • Practice your deployment strategies,

  • Familiarize yourselves with the arenas and rules, and

  • Demonstrate your capabilities to the Technical Committee.

Unfortunately, due to the close scheduling of the regional open competitions and the World Championship each year, the qualification process can't be completely sequential because teams sometimes have trouble making it to the World Championship on short notice. So the Technical Committee qualifies an initial set of teams each year for the World Championship based on performance in the previous year’s competition and their updated team description papers. Teams that win a 1st, 2nd, or 3rd place award at any regional open competition and submit a team description paper are qualified for the World Championship competition in that year and the following year.

The Technical Committee usually keeps a few slots open in the World Championship competition to include additional capable teams that emerge from the regional open competitions each year. When there is no regional open competition in the region of the World Championship, the technical committee typically qualifies proportionally more teams from the local region, while encouraging them to try to participate in other regional open competitions as well. At large qualifications may also be granted for teams in regions without a regional open competition. Although it is clear that the best route to participate in a World Championship competition is to perform well in a regional open competition and write a good team description paper. You will find the lessons learned from both are well worth the effort.

Each year the Technical Committee looks at the following criteria to qualify teams for the World Championship:

  • Your TDP which describes improvements to your robot based on lessons learned from the previous year’s competitions that produced a semi-final round appearance in the World Championship, a Best-In-Class award in the World Championship, or a Place award in a regional open.
  • Your TDP describes a particularly interesting or innovative approach that the Technical Committee considers likely to perform well at the World Championship competition even without previous experience at a regional open competition, especially when there is not yet a regional open competition nearby to you. This is especially possible if you can demonstrate your capabilities convincingly within representative arena apparatuses through video of the robot performing any or all of the requisite capabilities:
  • advanced mobility (traversing random stepfields or confined space cubes)
  • navigation (wall following, centering between obstacles or constrictions)
  • localization and mapping (2D/3D maps, SLAM on non-flat-flooring i.e. pitch/roll ramps, low-profile stepfields)
  • directed perception (visual acuity for near/far/dark/light, sensor probing into voids, sometimes with reaching)
  • victim identification (fusion of the various sensory signals to improve confidence and reduce errors)
  • autonomy (assistive features, bounded intervals, or fully autonomous performance of any or all of the above)
  • effective operator interfaces

Finally, some qualifications for the World Championship may be granted by the Technical Committee to include particular countries in the league, encourage technologies that the league should be investigating, or to support other league outreach efforts.



RoboCup 2017 Information

Location: Nagoyo, Japan

  • Dates: 27 July to 31 July, 2017

Important Dates:

  • Mar 26, 2017 Announcement of first round of qualified teams.

RoboCup 2016 Scores

Congratulations All Teams who Competed in RoboCup Rescue 2016 Competition. Looking forward to seeing you all in Japan.





RoboCup Champions

Year Location 1st Place Team 2nd Place Team 3rd Place Team
2015 Hefei,China MRL iRAP_Junior YRA
2014 Joao Pessoa, Brazil Hector Darmstadt MRL BART Lab
2013 Eindhoven, The Netherlands iRAP_Furious Ovec_Soomkor (2nd) STABILIZE (2nd)
2012 Mexico City - Mexico MRL Hector Darmstadt STABILIZE and YRA
2011 Istanbul, Turkey iRAP_Judy MRL STABILIZE
2010 Singapore iRAP_Pro BART LAB Rescue Success (Tied for Second)
2009 Graz, Austria iRAP_Pro Pelican United MRL
2008 Suzhou, China Plasma_RX Resko and Resquake (Jointed Team) MRL
2007 Atlanta, USA Independent Pelican United CEO Mission II
2006 Bremen, Germany Independent Pelican United MRL

Year Best in Autonomy Best in Manipulation Best in Mobility Small UAV Interface Award
2015 Hector Darmstadt UpRobotics iRAP_Junior XX Hector Darmstadt & MRL
2014 Hector Darmstadt YRA MRL YRA TEDUSAR
2013 Hector Darmstadt UP-Robotics iRAP_Furious XXXX XXXX
2012 Hector Darmstadt DML STABILZE XXXX XXXX
2011 CASualty YRA iRAP_Judy XXXX XXXX

Research State of the Art

Other Information

2011 Assembly Guide for RoboCup Elements


Summary of RoboCupRescue Robot League June 2010, Singapore