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ROBOTIC RESOURCES

All Together Now: Networked Robotics

by Bennett Brumson, Contributing Editor
Robotic Industries Association

Robot networking, where multiple robots operate together in coordination with controllers, computers, and humans while working toward a common production goal, is a means to ensure efficiency and safety within a work cell. Ethernet connections usually link networked robots together. While networking robots have its benefits, care must be taken to ensure the security of these systems.  "Robots use a real-time Ethernet network to communicate between controllers and to synchronize the robot’s program execution and motion. Networked robots cooperate with each other, perform different tasks, share loads, and operate in the same work space because they can communicate their positions to one another,’‘ says Joseph Kraus, Product Manager at KUKA Robotics Corp., Clinton Township, Michigan.

‘‘Robots for years have been interconnected through their own internal control structure to execute coordinated motion tasks with external axis and other positioning devices,’‘  says Greg Garmann, Software and Controls Technology Leader at Motoman Inc., West Carrollton, Ohio. ‘‘Now with the additional communication, robots have become more intelligent by being able to process more data faster, and then using the data to interact with outside networks and systems.’‘

Network Advantage
Networking robots gives manufacturers the ability to coordinate the motion of several robots to increase production without causing collisions. Anthony Ventura, Applications Development Engineer at Comau Robotics, Southfield, Michigan says ‘‘ Networking is built into robots with a standard data port. Networking robots is similar to networking computers, and is based on similar principles.’‘

In order for networked robots to perform properly, good architecture is a necessary part of the controller. ‘‘Multi-tasking networked robots require a solid control architecture designed for real-time automation operation,’‘ says Jeffery Baird, Director of Engineering at Adept Technology, Inc., Livermore, California. ‘‘Networked systems include multiple robots, kinematics, devices, machine vision, and other peripheral devices.’‘

Baird goes on to give an example of networked robots in a packaging application. ‘‘A system of multiple robots operates on a packaging line with products flowing on a conveyor belt that includes line balancing, yields, and hand-shaking. Networked robots can automate customer orders, orders parts from a warehouse, schedules forklifts, sets production line operations, and palletizes parts for shipping.’‘

Likewise, Claude Dinsmoor, General Manager, Product Development at FANUC Robotics America, Inc., Rochester Hills, Michigan says ‘‘Layout and configuration of network traffic needs to be considered, especially in networks where I/O networking is done via Ethernet. Paying attention to the broadcast domain of devices using managed switches is necessary to prevent unwanted traffic from being seen by every device on the network.’‘

Dinsmoor goes on to say, ‘‘Configuration also involves determining how network and device addressing will be accomplished, such as how Dynamic Host Configuration Protocol (DHCP) will be employed for an Internet protocol address for the various devices deployed in the system.’‘ Dinsmoor maintains, ‘‘Network complexities can be managed by carefully planning and prototyping, and by trying out configurations prior to deployment.’‘ Dinsmoor concludes by saying that integrators need to have a good understanding of Ethernet fundamentals.

For networked robots to perform well, what information is shared among each element and how that information is analyzed is crucial. Philip Baratti, Applications Engineering Manager at EPSON Robots, Carson, California, addresses how information is sorted through a robotic network.

‘‘Deciding exactly what information is most important to the application is necessary. This helps integrators determine the complexity of the network and the amount of bidirectional information that will be on the network,’‘ Baratti says. ‘‘In robotic applications, integrators must understand the difference between system information and application information.

Baratti explains that system information tells the network and other devices on the network the state of the robotic work cell, such as safeguard status, e-stop condition, as well as those tasks that are running and those that are paused. Application information tells the network what is occurring during production, including cycle counts, counts of parts that pass or fail, and pallet status. Application information is passed to other devices in the network to let them know what is happening within a particular work cell.

‘‘If time is taken up front to determine the amount and types of data that will be required, the actual implementation will go much smoother as will maintaining and deciphering the data,’‘ Baratti stresses.

Remote Robots
Networked robots have the ability to remotely diagnose some problems with the system and in some cases, fix them. ‘‘Remote diagnostics is something that people have talked about for a long time. If robots using PC-based controls running Windows XP have a network connection, operators can use the remote connectivity capabilities of Windows XP to remotely see everything that is on the robot controller's user interface,’‘ says Joe Kraus. As a caveat, Kraus points out that, ‘‘Remote diagnostics is easy although fixing hardware problems remotely can be difficult, especially if things need to be taken apart.’‘

Ventura also speaks of the advantages that remote diagnostics bring to robot-based manufacturing. ‘‘Integrators can network robots so a technician in Italy can log into a robot located in the United States to manipulate files, as well as activate and deactivate programs.’‘ Technicians cannot remotely move the robot’s arm, Ventura says, as doing so could cause harm to people and other equipment.

Garmann recalls that a system recently was installed with the ability to communicate production data from North America to Europe through an Internet connection to report to the business unit that another part had been produced and was considered inventory and ready for purchase.

Baratti also refers to remote diagnostics of networked robots. ‘‘Robots use the Internet for remote monitoring of networked systems. A proper firewall is required to ensure that a robot is only accessible to authorized people.’‘

Baratti continues by saying, ‘‘Networked systems have the ability to page technicians when an error occurs and to send full reports to remote supervisors to check system performance. Controlling a system remotely is not advisable without having a person near the machine to ensure that the changes made do not create unsafe conditions.’‘

Baratti also contends that mechanical problems are not repaired remotely. ‘‘Monitoring ongoing errors allow a remote supervisor to make maintenance recommendations, or recommend repairs prior to a complete component failure.’‘

Security is a concern when networked robots are remotely accessed. Walter A. Weisel, Chief Executive Officer of Robotic Workspace Technologies (RWT), Fort Myers Beach, Florida says, ‘‘Networked robots need to have security lock-outs based in the software and a physical key rather than just a software key. Unauthorized people could reprogram a robot to add some items or endanger source code.’‘

Security issues need to be taken into account when performing systems integration of networked robots. Weisel recalls that an end-user who wanted to install America Online (AOL) software on a networked system RWT was integrating. ‘‘We refused to install AOL because if a networked system is truly open, hackers can disrupt the system.’‘

Weisel gives a scenario of what could occur to an unsecured network of robots. ‘‘The cost of having an automotive production line go down for just a minute is tremendous. No one wants to take a chance of someone putting a virus in 200 robots out of 800 robots in an automotive production plant.’‘

In a similar vein, Keith Goodreau, Operations Manager at CIS Technical Solutions, Windsor, Ontario, Canada, states that few manufacturers will have a truly open robotic network. ‘‘Not many companies that will allow robots to be hooked up to a communication link outside the plant where it can be accessed by somebody outside the facility. Companies do not want anyone tampering or hacking into the system, causing a crash and causing bodily injury.’‘

Dinsmoor also has security issues on his mind when it comes to networked robots. ‘‘An obstacle to Internet-based access to robots is maintaining sufficient network security to access the robot. Typical manufacturing facilities do not allow direct access to manufacturing equipment from the Internet,’‘ Dinsmoor says.

‘‘Manufacturing engineers use the factory’s internal network to monitor and maintain the system. Since large facilities may span hundreds of thousands of square feet, knowing what is happening on a downed production system can be a big time saver.’‘ Dinsmoor also states networked robotic systems help minimize the financial impact of production systems when a fault does occur.

Networked Apps
Some applications are more suited for networking than others. Weisel says material handling is one of the easiest applications to implement into a networked robotic system.

‘‘Networking material handling applications have good systems for stacking, but gripper design is important. If a pallet is going to have boxes placed on it, the ability to move boxes close to each other could be a difficult task if the wrong gripper is used.’‘ Weisel adds ‘‘The ‘magic’ come from an applications engineer who knows how to design a gripper and integrate it successfully into a networked system’‘

Conversely, Weisel declares arc welding is among one of the most difficult applications to network successfully. ‘‘Arc welding systems have to cope with smoke, gas, and broken wires. Only a few robot companies network arc welding systems well.’‘

Dinsmoor says ‘‘Applications using standard hypertext transfer (HTTP) or file transfer (FTP) protocols are the easiest to configure since these are typically well integrated into PC applications and tend to be plug-and-play. Real-time applications require more setup since they may require custom protocols and application-specific settings.’‘

For Baratti, robotic applications that use the same programming language are the simplest to network. ‘‘The easiest robot networking applications are those that have a single client and a single server. One machine will control the second machine, while both use the same programming language.’‘

Baratti lays out the benefit of using one programming language in a networked system. ‘‘Using the same language ensures that the information can easily be translated between both client and server, as opposed to having to parse data strings to translate information between client and server,’‘ Baratti notes.

Networked Future
A recent trend toward wireless robotic networks will continue in the next several years, predicts Dinsmoor. ‘‘Standard WiFi wireless networking will become a larger factor in applications where mobility of equipment is required or portable monitoring of the automation system is needed.’‘

Baratti sees networked robotics systems becoming more autonomous. ‘‘The future of networked robotic systems through the Internet can bring manufacturers much closer to the ‘lights out’ concept of manufacturing. Automated systems networked into the Internet will be able to receive orders from point-of-sale locations all over the world, manufacture the product, pack, label, ship, and invoice all within minutes of the order being placed,’‘ Baratti foresees. ‘‘Not only will robotic system be capable of building the products that are ordered, but they will also reorder supplies automatically as well…everything from raw materials to consumables.’‘

Weisel sees improved communication among different makes of robots so that work cells are not ‘‘Islands of Automation.’‘ ‘‘For many years, the robot industry was considered ‘Islands of Automation,’ because different makes of robots did not communicate with each other. Robot manufacturers did not use a standard language and each had a proprietary controller,’‘ Weisel remarks. ‘‘After 30 years, the robotics industry has started to come around and has begun the trend towards a standard programming language.’‘ Weisel asserts now is the time for a common programming language to be used in robots and their controllers and to trend away from proprietary packages. ‘‘The ability to communicate between different makes of robots and controllers is where the robot industry of the future stands.’‘

Editor’s Note:
This article has been reviewed by members of the
RIA Editorial Advisory Group.

For more information, you may contact any of the experts listed in this article or visit Robotics Online, Tech Papers.

Jeffrey Baird, Director of Engineering, Adept Technology, Inc., 925-245-3429, jeff.baird@adept.com

Keith Goodreau, Operations Manager, CIS Technical Solutions, 519-948-6840, kgcisrobotics@charter.net

Anthony Ventura, Applications Development Engineer, Comau Robotics, 248-353-8888, Tony.Ventura@comaupico.com

Philip Baratti, Applications Engineering Manager, EPSON Robots, 562-290-5900 Phil_Baratti@ea.epson.com

Claude Dinsmoor, General Manager for Controller Product Development, FANUC Robotics America, Inc., 248-377-7000, Claude.Dinsmoor@fanucrobotics.com

Joseph Kraus, Product Manager, KUKA Robotics Corp., 586-569-2082, JoeKraus@KUKARobotics.com

Greg Garmann, Software and Controls Technology Leader, Motoman Inc., 937-847-6200, greg.garmann@motoman.com

Walter Weisel, Chief Executive Officer, Robotic Workspace Technologies, Inc., 239- 466-0488, wweisel@innovaroboticsautomation.com

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