Special thanks to our demonstration teams and presenters:

ROS/ROS-I Demonstrations:

1. Autonomous Vehicle Test Rides. Chris Mentzer, Kris Kozak, Mark Alban, Ed Venator, SwRI.
2. Large-scale Mobile Robotic Laser Depainting. Clay Flannigan and Michael Rigney, SwRI.
3. Descartes Constrained Cartesian
   Motion Planner. Christina Gomez, SwRI.
4. Dual Arm Mobile Manipulation. Andrew
   Sharp, UT Austin NRG.
5. Euler Mobile Order Fulfillment. Jorge Nicho, SwRI.
6. FlexGUI. Trygve Thomessen, PPM AS.
7. Heavy Equipment Simulator (not ROS,
   but still cool). Susan Porter, SwRI.
8. Human-centered Teleoperation for
   High-precision Tasks aka “Thread the
   Needle”. Karl Kruusamäe, UT Austin
   NRG.
9. Intrinsic Calibration. Chris Lewis, SwRI.
10. Package Singulation. Shaun Edwards,
    SwRI.
11. Ragnar 2D Vision/Replication. Alex
    Goins, SwRI.
12. Ragnar Demonstration. Preben Hjornet,
    Blue WorkForce.
13. Robotic Blending. Jonathan Meyer,
    SwRI.
14. Scan-N-Plan for CAD-Free Painting.
    Michael Blanton, SwRI.
15. STOMP Free-space Motion Planner. Levi
    Armstrong, SwRI.
16. Thunder Motion Planner. Dave
    Coleman, CU Boulder.

Presentations:

• Introduction to SwRI. Paul Evans, SwRI.
• Space Science. Philip Valek, SwRI.
• Large Robots Need Smart Controls. Jeremy Zoss, SwRI.
• Introduction to the ROS-Industrial Consortium. Paul Hvass, SwRI.

Following the announcement made at the last RIC-EU Members Meeting, PPM AS released a significant part of its FlexGui software package as open-source. FlexGui, which is now part of the ROS-Industrial project, is an easy-to-configure interface originally developed for the control panel of Nachi robots. Its latest release runs on any browser-equipped device, including industrial PCs and tablets, making it also suitable for remote supervision. ROS-integration makes it now possible to control through FlexGui the wide range of platforms supported by ROS, and its factory designer functionality makes it appealing for production scenarios rich of sensors and other networked devices, such as those envisioned by the Industrie 4.0 initiative.

In case you missed the FlexGui demo at the last RIC-EU event held at Fraunhofer IPA in January, you can hear the presentation by Laszlo Nagy from PPM AS given during the last Community Meeting. Click here for the recording. PPM AS will be present at the RIC-Americas Annual Meeting.

Cross-Posted from NIST Intelligent Systems Division Press Release

Manufacturers, robot suppliers and researchers, here’s your chance to get in on the ground floor of an upcoming national competition intended to help make robots handier and nimbler performers on the factory floor.

The National Institute of Standards and Technology (NIST) is launching ARIAC—the Agile Robotics for Industrial Automation Competition, a joint effort with the IEEE Conference on Automation Science and Engineering. Now in the planning stages, this first-ever, simulation-based competition aims to inspire applications of the latest advances in artificial intelligence and other technologies to solve the challenge of making robots more capable, versatile and collaborative, as well as easier to program.

Click to continue reading on the NIST website.

Editor's note: We encourage contestants to utilize ROS-Industrial open source software for their development efforts. In particular, the Industrial MoveIt! package may be helpful for motion planning.

Hardware interfaces are particularly important for any future integration of ROS-I with production systems. During 2015, we noted four new repositories emerged that span the range of prominent industrial field busses:

• CANOPEN™: CANOPEN is a fieldbus with origins in automotive applications (CAN), but applied to automation. We are grateful for the efforts of Mathias Lüdtke and Florian Weisshardt from Fraunhofer IPA for the ros_ canopen package.
• EtherNet/IP™: EtherNet/IP is an Ethernet-based real-time communication bus standard that was created by Allen-Bradley (Rockwell Automation). Thank you ClearPath Robotics for developing and releasing a ROS driver for EtherNet/IP.
• EtherCAT™: Probably the first fieldbus supported in ROS for the PR2, EtherCAT is an Ethernet-based realtime communication bus standard that was created by Beckhoff Automation. We appreciate Intermodalics for maintaining the EtherCAT package for ROS.
• PROFINET™: PROFINET, an open automation standard and part of IEC 61158 is fully compatible with all the features of standard Ethernet, and also capable of real-time performance. We recognize the efforts of package developer Frantisek Durovsky from the Technical University of Kosice in Slovakia along with his mentor Shaun Edwards (SwRI), the financial support of Google Summer of Code program, and technical support from Siemens.

For full details visit the event page.

Register now!

Thursday, March 3 (Public):

Friday, March 4 (Members Only):

Thanks to all the participants who made the 2016 RIC-EU tech demo and members meeting a success! On Jan 28-29, Fraunhofer IPA, the managing organization of the ROS-Industrial Consortium Europe, welcomed more than 50 participants to the annual RIC-EU members meeting. ROS technology continues to mature and find its way into commercial products and industrial applications, which was shown during a technology demonstration session.

Participants had the chance to see for themselves what ROS technology can do in terms of easing robot programming; extending the applicability of commercial software platforms through standard interfaces; allowing for hardware-independent intuitive touch interfaces; and powering next-gen robot hardware.

After introductory talks, the attendees enjoyed individual presentations, and were able to interact with the presenters and fellow attendees during an open-floor format. The day ended with a social event.

The members' meeting held Jan 29 is an annual gathering of members for an overview of activities during the previous year and current initiatives. Presentations about efforts similar to ROS-I targeting other domains were given. The SiLA initiative aims at similar standardization efforts, but for lab automation equipment; the Machinekit project, which is undergoing interesting development, can make in the future Machinekit+ROS a full stack covering all of your robotics-related needs, from bare metal up to the user interface. This "sister" project raised considerable interest for its potential, especially for hardware designers in need of a means to interface with ROS. More updates will be available on rosindustrial.org, as integration efforts continue.

Attendees enjoyed presentations from RIC-EU's scientific advisor, Martijn Wisse from TU Delft, and Mirko Bordignon from Fraunhofer IPA on ROS infrastructure further development for industrial use thanks to public funding. Ingo Luetkebohle from Bosch, which recently joined RIC-EU, provided an overview of ROS activities at his organization, while Paul Evans from the Southwest Research Institute briefed the attendees on the North American ROS-I Consortium.

The meeting ended with an open discussion, which provided inputs for the ongoing technology roadmapping activity. This will continue at the upcoming RIC-NA members meeting, and will set the schedule for the technical developments of ROS-I during 2016.

For your reference, the detailed agenda of the whole event can be found here.

According to a ROS users survey that was conducted in 2014, the most popular hardware to integrate with ROS is a camera. Cameras are often used to perceive the environment or to localize robots and are a critical component of the sense-plan-act capability that ROS enables. Over the past two years, the ROS-I team has been working to create an industrial calibration library that supports both intrinsic and extrinsic calibration of vision sensors. What is novel about the library is that is can handle groups of heterogeneous sensors that may be static, or mounted to a robot, or some combination thereof. And it coordinates with MoveIt! to automate calibration procedures in which robot motion is required during calibration. While the extrinsic calibration routines are well in hand, the intrinsic calibration algorithm, which is based on a popular lens distortion model, resulted in higher parameter variance than was expected based on residual errors. This is particularly true for the focal length parameter, which is essential for correctly interpreting the size of objects in the scene. The ROS-I team has developed a novel camera intrinsic calibration technique that is both computationally faster and provides superior results to the methods commonly employed in machine vision.

The optimization procedure outlined by Zhang and automated by both OpenCV/ROS, and Matlab orchestrate the collection of a set of images of a calibration target. Both the extrinsic pose of the camera and the intrinsic parameters themselves are determined by minimizing the re-projection error. Using these methods, the residual re-projection error is on the order of ¼ pixel/observation or less. However, the variances of focal length and optical center are much higher, typically being 20 pixels and 5 pixels respectively. This is due to correlation between parameters of the distortion model with the focal length parameter.

The new procedure developed by the ROS-I team reduces parameter variance to be on par with the residual error. It requires only 10 to 20 images, but each is taken a known distance apart with little or no skew (refer to images). The new procedure estimates the extrinsic pose for the first image, and constrains the optimization to use the known pose relationship for subsequent images. The focal length and optical center are significantly better constrained. Using the resulting intrinsic calibration parameters for a given camera yields significantly better extrinsic calibration or pose estimation accuracy. Try out the Intrinsic Camera Calibration (ICC) tutorial that is posted on the ROS-I wiki.

The recent availability of affordable ROS-compatible 3D sensors has been one of the fortunate coincidences that has accelerated the spread of ROS. Since the popular the ASUS Xtion Pro Live has been intermittently stocked, check out the field of ROS-compatible 3D sensors to review the contenders.

A longstanding need, which will improve the efficiency of setting up a ROS project, is the ability to import model and process data from various CAD systems. In collaboration with TU Delft last year, we proposed a ROS-I Consortium Focused Technical Project to develop a CAD data importer for ROS that could automatically convert from common CAD files to URDFs and SRDFs. While the initiative was met with great interest, the lengthy duration and fixed-price milestone contract arrangement were not sufficiently attractive to garner the investment required to launch the project. However, a strong showing by the developer community led us to believe that much of the software development work would be contributed by collaborating consortium members, if technical leadership was provided to guide and curate the development. Furthermore, we wished to expand the future vision of CAD to ROS by building it into a 3D workbench framework. This will provide a common user experience for importing and configuring sensors, Cartesian process plans, motion plans, and point cloud data in the future. To assure incremental progress, we restructured the CAD to ROS project, reorganizing it into five milestones, each approximately four months:

1. URDF GUI Editor
2. Process Planning
3. Work Cell Planning
4. Sensor Configuration and Calibration Setup
5. 3D Point Cloud Importer

We also restructured the business model. There are now four types of contributors to the project:

• Technical Overseer: TU Delft will set the software architecture design goals and will review pull requests from developers.
• Sponsor: In December 2015, one of the ROS-I Consortium members pledged their support for TU Delft’s efforts.
• Developers: In exchange for helping to write the code, Consortium members will have access to the private project repository.
• Consortium Administrator: SwRI and Fraunhofer IPA will recruit developers from amongst the Consortium membership to help with coding.

For this particular Consortium project, we are implementing a business model in which only contributors from the Consortium have access to the URDF editor tool. This is an opportunity to see how productive the community can be when motivated by a little self-interest.

We need the help of ROS-I Consortium member software developers! Please contact paul.hvass@swri.org, or mirko.bordignon@ipa.fraunhofer.de to gain access to the project and to help complete Milestone 1!

The ROS-Industrial Consortia invite you to attend one of the upcoming annual meetings. Not yet a member? You can always join!

RIC-Europe

The 2016 ROS-Industrial Consortium Europe Annual Members meeting will take place on January 28-29 on the premises of Fraunhofer IPA's main campus in Stuttgart, Germany. The two day schedule is designed to best fit our international attendees, allowing for the inbound travel to Stuttgart to take place on the morning of Thursday January 28, and for the return travel on the afternoon of the following day.

Thursday Afternoon/Evening January 28 (Public): Technology demonstrations session will be held, showcasing the latest commercial developments from ROS-Industrial Consortium members. Participation to this session is open to external entities not affiliated with the consortium and will start with a keynote address on the commercial impact of ROS and continue with short presentation of each technical highlight. The floor will then be open for discussion on an exhibition-like environment, with physical hardware and live demos on display, in order to facilitate the exchange between the presenters and the audience.

Friday January 29 (Members Only): The ROS-Industrial Consortium Europe will gather for its 2016 Annual Members meeting, during which an overview of 2015 activities will be given, followed by invited talks regarding initiatives relevant to the ROS-I community, current and future projects. The meeting will end with a general discussion on the technical roadmap which will set the agenda for the 2016 activities. The meeting will dismiss at 15:30 to allow for travel.

For more details, please refer to the event page.

RIC-Americas

The 2016 ROS-Industrial Consortium Americas Annual Members' meeting will take place on March 3-4 on the premises of SwRI's main campus in San Antonio, Texas. While the detailed agenda is still falling into place, at a high level there are many similarities to the RIC-EU format:

Thursday Afternoon/Evening March 3 (Public):

• ROS-I Technology Demonstrations: Scan-n-Plan for robotic blending and painting, Euler mobile manipulator, Blue WorkForce Ragnar robot, Industrial Calibration Library, mixed parcel handeling, 15kW CO2 laser
• Keynote: Jeremy Zoss, SwRI's chief engineer for the four-story tall Laser Coating Removal mobile robot, will present an overview of the project along with insights about how ROS is being integrated.
• Dinner (Provided): Dine on San Antonio's historic River Walk.

Friday March 4 (Members Only): Some highlights of the annual members meeting include:

• Consortium Updates: learn about the latest ROS-I community developments, and planned Consortium activities for 2016.
• Lunch Keynote: Erik Nieves, CEO of the stealth startup PlusOne Robotics, will present his vision for the future of robotics.
• Focused Technical Projects: We will provide an update on current Consortium projects, and upcoming 2016 projects.
• Roadmapping: The meeting will end with a general discussion on the technical roadmap which will set the agenda for the 2016 activities. The meeting will dismiss at 15:30 to allow for travel.

Additional details including a complete agenda will be added on the event page.

ROS-Industrial software developers at Southwest Research Institute have collaborated with the product development team at Blue WorkForce to create a ROS package for their Ragnar robot. The Ragnar is a 4-legged delta style robot designed to be affordable and reconfigurable for a variety of work volumes and tasks. Special thanks to:

• ROS-I Team: Jonathan Meyer, Alex Goins, and Jeremy Zoss
• Blue WorkForce Team: Michael Frederiksen and Preben Hjørnet

The source code can be found at: https://github.com/Blueworkforce/ROSRagnarEDU