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OpenRTM-aist

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OpenRTM-aist
Developer(s)National Institute of Advanced Industrial Science and Technology
Stable release
1.2.1 / November 25, 2019; 5 years ago (2019-11-25)
Written inC++, Java, Python
PlatformWindows, Linux, macOS, VxWorks, TOPPERS(ITRON), QNX
TypeLibrary
LicenseLGPL
Websitewww.openrtm.org

OpenRTM-aist is a software platform developed on the basis of the RT middleware standard.[1] OpenRTM-aist is developed by National Institute of Advanced Industrial Science and Technology which also contributes to definition of the RT-middleware standard.

Abstract

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In RT middleware, all robotic technological elements, such as actuators and sensors, are regarded as RT-components (RTC). Each RTC provides ports to communicate with other RTCs, and developers can implement their own robotics technology (RT) systems as RTCs. The RT-middleware can thus be considered as a distributed control architecture.[2]

RT-middleware is originally a platform independent model (PIM). Implementations of this model include CORBA, Enterprise JavaBean (EJB), and .NET Framework. OpenRTM-aist is based on the CORBA technology and implements the extended RTC specification. Experiences with OpenRTM-aist will be fed back to the RT-middleware standardization process.

Characteristics

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OpenRTM-aist implements some extended RTC features, and it also includes a Manager component to help manipulating RTCs. RTCs in OpenRTM-aist can be implemented using many programming languages, and RTCs programmed in different languages can communicate with each other. A lot of tools to ease RTC manipulations are also released by the National Institute of Advanced Industrial Science and Technology and their co-workers (in a strict sense, OpenRTM-aist itself is a library and does not include these tools).

RT-component

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The RT-component is a functional unit which conforms to the RT-component specification defined by OMG. In OpenRTM-aist, RTCs have data ports, service ports, and execution context which controls the RTC's state.

State Machine

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In standards of RT-component, RTC must have 4 states such as CREATED, INACTIVE, ACTIVE, and ERROR. When the state changes, corresponding event-handlers are called by the execution context which manages the RTCs' state machine.

For example, "on_activated" callback function is called when the RTC is activated (from INACTIVE to ACTIVE state). In on_activated callback, initialization codes are implemented.

On the other hand, "on_deactivated" callback function is called when the RTC is deactivated (from ACTIVE to INACTIVE state). In this callback, finalization codes are implemented.

"on_execute" is periodically called when the RTC is in ACTIVE state. Here, controlling or some device management (ex., polling) functions are called.

These callbacks are called by the "execution context" object. If the special execution context is attached to the RTCs, calling method or policy is modified (see execution context section).

Data port

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A data port is an endpoint to communicate with other RTCs. The data ports have their types. Ports with the same type can be connected to each other.

In OpenRTM-aist, primitive data types (like "TimedLong", "TimedDouble", and so on) are implemented. Moreover, from OpenRTM-aist version 1.0, extra data types which are expected to be used commonly in robotic systems were released as ExtendedDataType (like "TimedVelocity2D", "TimedPose2D", and so on)[3]

Developers can define their own data types by describing IDL file. Tools can parse the IDL file and automatically generate the skeleton and stub file of the original data types.

Service port

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The service port allows communicating much more flexibly than the data ports. Developers should define service port interfaces by making their IDL files.

Execution contexts

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Execution contexts handle the state-machine operations of RT-components. In OpenRTM-aist, several kinds of execution contexts are provided. For example:

  • the periodic execution context, one of the most commonly used, provides periodic calls of the "on_execute" event-handler (sensor acquisition or actuator control are usually implemented there);
  • the real-time execution context, which uses Linux's pre-emptive kernel function, supports real-time operation of the RTC;[4]
  • the extra trigger execution context is an important characteristic of OpenRTM-aist. It provides the synchronization capability with dynamics simulators like OpenHRP-3.

Configuration

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Configuration is a function which dynamically changes the parameters of the RTCs during run-time. Configuration can be numeric and string.

Supported operating systems

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OpenRTM-aist runs on Windows, Linux and macOS.[5] Furthermore, VxWorks is supported experimentally.[6]

Supported programming languages

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Since OpenRTM-aist is based on the CORBA technology, it supports several programming languages, including: C++, Java, Python, and Erlang (unofficial).

Tools

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RTC Builder

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RTC Builder

RTC Builder is a tool for skeleton-code generation. It is launched in the eclipse developmental environment. OpenRTM-aist also supports RTC-template which is a command-line type skeleton-code generation tool.

RT System Editor

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RT System Editor

RT System Editor is a tool for handling RTCs. RT system editor provides following services:

  • Referring RTCs' states
  • Connecting RTCs' ports
  • Configuring RTCs
  • Activate/deactivate/reset RTCs
  • Save/restore the RT-system

rtshell

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rtshell is a command-line tool which provides following services:[7]

  • Referring RTCs' states
  • Connecting RTCs' ports
  • Configuring RTCs
  • Activate/deactivate/reset RTCs
  • Restore the RT-system
  • Log output of DataPorts
  • Replay the log of the DataPorts

RTC debugger

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RTC debugger is a debugging tool for RTCs. RTC debugger is an Eclipse plug-in.[8]

License

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OpenRTM-aist is licensed under the GNU Lesser General Public License (LGPL).

See also

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References

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  1. ^ OpenRTM-aist official website, http://www.openrtm.org
  2. ^ Robotics Technology Component Specification version 1.0, Object Management Group (OMG)
  3. ^ "OpenRTM-aist official site: Interface guidelines". Retrieved 23 April 2011.
  4. ^ National Institute of Advanced Industrial Science and Technology, press release, Development of HRP-4, a Research and Development Platform for Working Humanoid Robots, http://www.aist.go.jp/aist_e/latest_research/2010/20101108/20101108.html
  5. ^ OpenRTM-aist official website --supported platforms, http://www.openrtm.org/openrtm/en/content/supported-platforms-0
  6. ^ Akihiro Ikezoe, Hiroyuki Nakamoto, Masayuki Nagase, "OpenRT Platform / RT-middleware for VxWorks", ROBOMEC2010 [in Japanese]
  7. ^ OpenRTM-aist Official Site: [rtshell http://www.openrtm.org/openrtm/en/content/rtshell-download]
  8. ^ Sec Co., LTD., [RTC debugger http://www.sec.co.jp/robot/download_tool.html]
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