Fieldbus
Fieldbus is the name of a family of industrial computer network protocols used for real-time distributed control, standardized as IEC 61158.
A complex automated industrial system — such as manufacturing assembly line — usually needs a distributed control system—an organized hierarchy of controller systems—to function. In this hierarchy, there is usually a Human Machine Interface (HMI) at the top, where an operator can monitor or operate the system. This is typically linked to a middle layer of programmable logic controllers (PLC) via a non-time-critical communications system (e.g. Ethernet). At the bottom of the control chain is the fieldbus that links the PLCs to the components that actually do the work, such as sensors, actuators, electric motors, console lights, switches, valves and contactors.
Description
Fieldbus is an industrial network system for real-time distributed control. It is a way to connect instruments in a manufacturing plant. Fieldbus works on a network structure which typically allows daisy-chain, star, ring, branch, and tree network topologies. Previously, computers were connected using RS-232 (serial connections) by which only two devices could communicate. This would be the equivalent of the currently used 4-20 mA communication scheme which requires that each device have its own communication point at the controller level, while the fieldbus is the equivalent of the current LAN-type connections, which require only one communication point at the controller level and allow multiple (hundreds) of analog and digital points to be connected at the same time. This reduces both the length of the cable required and the number of cables required. Furthermore, since devices that communicate through fieldbus require a microprocessor, multiple points are typically provided by the same device. Some fieldbus devices now support control schemes such as PID control on the device side instead of forcing the controller to do the processing.
History
Arguably the precursor field bus technology is HP-IB as described in IEEE 488 / 1975. http://www.hp9845.net/9845/tutorials/hpib/ "It became known as the General Purpose Interface Bus (GPIB), and became a de facto standard for automated and industrial instrument control." See IEEE-488
Bitbus
The oldest commonly used field bus technology is Bitbus. Bitbus was created by Intel Corporation to enhance use of Multibus systems in industrial systems by separating slow i/o functions from faster memory access. In 1983, Intel created the 8044 Bitbus microcontroller by adding field bus firmware to its existing 8051 microcontroller. Bitbus uses EIA-485 at the physical layer, with two twisted pairs - one for data and the other for clocking and signals. Use of SDLC at the data link layer permits 250 nodes on one segment with a total distance of 13.2 km. Bitbus has one master node and multiple slaves, with slaves only responding to requests from the master. Bitbus does not define routing at the network layer. The 8044 permits only a relatively small data packet (13 bytes), but embeds an efficient set of RAC (remote access and control) tasks and the ability to develop custom RAC tasks. In 1990, the IEEE adopted Bitbus as the Microcontroller System Serial Control Bus (IEEE-1118).[1][2]
Today BITBUS is maintained by the BEUG - BITBUS European Users Group.[3]
Standardization
Although fieldbus technology has been around since 1988, with the completion of the ISA S50.02 standard, the development of the international standard took many years. In 1999, the IEC SC65C/WG6 standards committee met to resolve difference in the draft IEC fieldbus standard. The result of this meeting was the initial form of the IEC 61158 standard with eight different protocol sets called "Types" as follows:
- Type 1: FOUNDATION Fieldbus H1
- Type 2: ControlNet
- Type 3: PROFIBUS
- Type 4: P-NET
- Type 5: FOUNDATION fieldbus HSE (High-Speed Ethernet)
- Type 6: SwiftNet (a protocol developed for Boeing, since withdrawn)
- Type 7: WorldFIP
- Type 8: INTERBUS-S
This form of standard was first developed for the European Common Market, concentrates less on commonality, and achieves its primary purpose—elimination of restraint of trade between nations. Issues of commonality are now left to the international consortia that support each of the fieldbus standard types. Almost as soon as it was approved, the IEC standards development work ceased and the committee was dissolved. A new IEC committee SC65C/MT-9 was formed to resolve the conflicts in form and substance within the more than 4000 pages of IEC 61158. The work on the above protocol types is substantially complete. New protocols, such as for safety fieldbuses or real-time Ethernet fieldbuses are being accepted into the definition of the international fieldbus standard during a typical 5-year maintenance cycle. In the 2008 version of the standard, the fieldbus types are reorganized into Communication Profile Families (CPFs):
- CPF 1: FOUNDATION Fieldbus
- CPF 2: CIP
- CPF 3: PROFIBUS
- CPF 4: P-NET
- CPF 5: WorldFIP
- CPF 6: INTERBUS
- CPF 7: SwiftNet (withdrawn)
- CPF 8: CC-Link
- CPF 9: HART
- CPF 10: Vnet/IP
- CPF 11: TCnet
- CPF 12: EtherCAT
- CPF 13: Ethernet Powerlink
- CPF 14: EPA
- CPF 15: MODBUS-RTPS
- CPF 16: SERCOS[4][5]
Both Foundation Fieldbus and Profibus technologies are now commonly implemented within the process control field, both for new developments and major refits. In 2006, China saw the largest FF (Foundation Fieldbus) systems installations at NanHai and SECCO, each with around 15000 fieldbus devices connected.
IEC 61158 specification
There were many competing technologies for fieldbus and the original hope for one single unified communications mechanism has not been realized. This should not be unexpected since fieldbus technology needs to be implemented differently in different applications; automotive fieldbus is functionally different from process plant control. The final edition of IEC standard IEC 61158 allows 8 technologies. This are the some hierarchic layer of the automation protocols.
IEC 61158 consists of the following parts, under the general title Digital data communications for measurement and control – Fieldbus for use in industrial control systems:
- Part 1: Overview and guidance for the IEC 61158 series
- Part 2: Physical Layer specification and service definition
- Part 3: Data Link Service definition
- Part 4: Data Link Protocol specification
- Part 5: Application Layer Service definition
- Part 6: Application Layer Protocol specification
Standards
There are a wide variety of competing fieldbus standards. Some of the most widely used ones include:
- AS-Interface
- CAN
- EtherCAT
- FOUNDATION fieldbus
- Interbus
- LonWorks
- Modbus
- Profibus
- BITBUS
- CompoNet
- SafetyBUS p
- RAPIEnet
See List of automation protocols for more examples.
Cost advantage
The amount of cabling required is much lower in Fieldbus than in 4-20 mA installations. This is because many devices share the same set of cables in a multi-dropped fashion rather than requiring a dedicated set of cables per device as in the case of 4-20 mA devices. Moreover, several parameters can be communicated per device in a Fieldbus network whereas only one parameter can be transmitted on a 4-20 mA connection. Fieldbus also provides a good foundation for the creation of a predictive and proactive maintenance strategy. The diagnostics available from fieldbus devices can be used to address issues with devices before they become critical problems.[6]
Networking
With the exception of ARCNET, which was conceived as early as 1975 for office connectivity and later found uses in industry, the majority of fieldbus standards were developed in the 1980s and became fully established in the marketplace during the mid-1990s. In the United States, Allen-Bradley developed standards that eventually grew into DeviceNet and ControlNet; in Europe, Siemens and other manufacturers developed a protocol which evolved into PROFIBUS.
During the 1980s, to solve communication problems between different control systems in cars, the German company Robert Bosch GmbH first developed the Controller Area Network (CAN). The concept of CAN was that every device can be connected by a single set of wires, and every device that is connected can freely exchange data with any other device. CAN soon migrated into the factory automation marketplace (with many others).
Despite each technology sharing the generic name of fieldbus the various fieldbus are not readily interchangeable. The differences between them are so profound that they cannot be easily connected to each other.[7] To understand the differences among fieldbus standards, it is necessary to understand how fieldbus networks are designed. With reference to the OSI model, fieldbus standards are determined by the physical media of the cabling, and layers one, two and seven of the reference model.
For each technology the physical medium and the physical layer standards fully describe, in detail, the implementation of bit timing, synchronization, encoding/decoding, band rate, bus length and the physical connection of the transceiver to the communication wires. The data link layer standard is responsible for fully specifying how messages are assembled ready for transmission by the physical layer, error handling, message-filtering and bus arbitration and how these standards are to be implemented in hardware. The application layer standard, in general defines how the data communication layers are interfaced to the application that wishes to communicate. It describes message specifications, network management implementations and response to the request from the application of services. Layers three to six are not described in fieldbus standards.[8]
Features
Different fieldbuses offer different sets of features and performance. It is difficult to make a general comparison of fieldbus performance because of fundamental differences in data transfer methodology. In the comparison table below it is simply noted if the fieldbus in question typically supports data update cycles of 1 millisecond or faster.
Fieldbus | Bus power | Cabling redundancy | Max devices | Synchronisation | Sub millisecond cycle |
---|---|---|---|---|---|
AFDX | No | Yes | Almost unlimited | No | Yes |
AS-Interface | Yes | No | 62 | No | No |
CANopen | No | No | 127 | Yes | No |
CompoNet | Yes | No | 384 | No | Yes |
ControlNet | No | Yes | 99 | No | No |
CC-Link | No | No | 64 | No | No |
DeviceNet | Yes | No | 64 | No | No |
EtherCAT | No | Yes | 65,536 | Yes | Yes |
Ethernet Powerlink | No | Optional | 240 | Yes | Yes |
EtherNet/IP | No | Optional | Almost unlimited | Yes | Yes |
Interbus | No | No | 511 | No | No |
LonWorks | No | No | 32,000 | No | No |
Modbus | No | No | 246 | No | No |
PROFIBUS DP | No | Optional | 126 | Yes | No |
PROFIBUS PA | Yes | No | 126 | No | No |
PROFINET IO | No | Optional | Almost unlimited | No | No |
PROFINET IRT | No | Optional | Almost unlimited | Yes | Yes |
SERCOS III | No | Yes | 511 | Yes | Yes |
SERCOS interface | No | No | 254 | Yes | Yes |
Foundation Fieldbus H1 | Yes | No | 240 | Yes | No |
Foundation Fieldbus HSE | No | Yes | Almost unlimited | Yes | No |
RAPIEnet | No | Yes | 256 | Under Development | Conditional |
Fieldbus | Bus power | Cabling redundancy | Max devices | Synchronisation | Sub millisecond cycle |
Process Fieldbus vs. Device Networks
It should be noted that requirements of fieldbus networks for process automation applications (flowmeters, pressure transmitters, and other measurement devices and control valves in industries such as hydrocarbon processing and power generation) are different from the requirements of fieldbus networks found in discrete manufacturing applications such as automotive manufacturing, where large numbers of discrete sensors are used including motion sensors, position sensors, and so on. Discrete fieldbus networks are often referred to as "device networks".[9]
Ethernet and Fieldbus
Recently a number of Ethernet-based industrial communication systems have been established, most of them with extensions for real-time communication. These have the potential to replace the traditional fieldbuses in the long term.
Here is a partial list of the new Ethernet-based industrial communication systems:
- AFDX
- EtherCAT
- EtherNet/IP
- Ethernet Powerlink
- FOUNDATION HSE
- BACnet
- PROFINET IO
- PROFINET IRT
- SafetyNET p
- SERCOS III
- TTEthernet
- VARAN
- RAPIEnet
For details, see the article on Industrial Ethernet.
Safety
Fieldbus can be used for systems which must meet safety-relevant standards like IEC 61508 or EN 954-1. Depending on the actual protocol, fieldbus can provide measures like counters, CRCs, echo, timeout, unique sender and receiver IDs or cross check. Ethernet/IP and SERCOS III both use the CIP Safety protocol,[10] Ethernet Powerlink uses openSAFETY, while FOUNDATION Fieldbus and Profibus (PROFIsafe) can address SIL 2 and SIL 3 process safety applications.
In January 2006, the Fieldbus Foundation announced that TÜV Rheinland Industrie Service GmbH, Automation, Software and Information Technology, a global, independent and accredited testing agency, had granted Protocol Type Approval for its Safety Specifications. The Foundation Technical Specifications - Safety Instrumented Functions are in compliance with International Electrotechnical Commission (IEC) 61508 standard (functional safety of electrical/electronic/programmable electronic safety-related systems) requirements up to, and including, Safety Integrity Level 3 (SIL 3).[11]
Market
In process control systems, the market is dominated by FOUNDATION fieldbus and PROFIBUS PA.[12] Both technologies use the same physical layer (2-wire manchester-encoded current modulation at 31.25 kHz) but are not interchangeable. As a general guide, applications which are controlled and monitored by PLCs (programmable logic controllers) tend towards PROFIBUS, and applications which are controlled and monitored by a DCS (digital/distributed control system) tend towards FOUNDATION Fieldbus. PROFIBUS technology is made available through Profibus International with headquarters in Karlsruhe, Germany. FOUNDATION Fieldbus technology is owned and distributed by the Fieldbus Foundation of Austin, Texas.
See also
Notes
- ↑ Hunziker, Robin; Schreier, Paul G. (August 1993). "Field buses compete for engineers' attention, start gaining commercial support". Personal Engineering & Instrumentation News. Rye, NH: PEC Inc. 10 (8): 35–37. ISSN 0748-0016.
- ↑ Zurawski, Richard, ed. (2005). Industrial Communication Technology Handbook. Industrial Technology Series. 1. Boca Raton, FL: CRC Press. pp. 7–10. ISBN 0849330777. LCCN 2004057922. Retrieved 4 Feb 2013.
- ↑ Bitbus/fieldbus community site.
- ↑ Fieldbus, Inc. (May 2, 2017). "IEC 61158 Technology Comparison" (PDF). Fieldbus, Inc.
- ↑ Felser, Max. "The Fieldbus Standards: History and Structures". citeseerx.ist.psu.edu. Retrieved 2017-05-02.
- ↑ http://www.controlglobal.com/articles/2007/217.html
- ↑ Bury (1999)
- ↑ Farsi & Barbosa 2000
- ↑ http://www.isadenver.org/docs/fieldbus.pps
- ↑ "CIP Safety on SERCOS Specification". Retrieved 2010-02-05.
- ↑ http://www.fieldbus.org/images/stories/enduserresources/technicalreferences/documents/wp_arc_ff-sif_908.pdf
- ↑ http://www.fieldbus.org/images/stories/fieldbus_report/FieldbusReport_Apr08.pdf
References
- Chatha, Andrew. (1994). Fieldbus: The Foundation for Field Control Systems Control Engineering, May, 47–50.
- Furness, Harry. (1994). Digital Communications Provides... Control Engineering, January, 23–25.
- Furness, Harry. (1994). Fieldbus: The Differences Start From the Bottom Up Control Engineering, March, 49–51.
- Fouhy, Ken. (1993). Fieldbus Hits The Road Chemical Engineering, September, 37–41.
- Johnson, Dick. (1994). The Future of Fieldbus At Milestone 1995 Control Engineering, December, 49–52.
- Loose, Graham. (1994). When Can The Process Industry Use Fieldbus? Control and Instrumentation, May, 63–65.
- Spear, Mike. (1993). Fieldbus Faces Up To First Trials Process Engineering, March, p36.
- Lasher, Richard J. (1994). Fieldbus Advancements and Their Implications Control Engineering, July, 33–35.
- Pierson, Lynda L. (1994). Broader Fieldbus Standards Will Improve System Functionality Control Engineering, November, 38–39.
- Powell, James and Henry Vandelinde (2009), 'Catching the Process Fieldbus - An introduction to PROFIBUS for Process Automation' www.measuremax.ca.
- O'Neill, Mike (2007). Advances in Fieldbus, Process Industry Informer, January, 36–37.
- N.P. Mahalik; P.R. Moore (1997) Fieldbus technology based, distributed control in process industries: a case study with LonWorks Technology
- ARC Advisory Group (2008) Foundation Fieldbus Safety Instrumented Functions Forge the Future of Process Safety
Bibliography
- Babb, Michael. (1994). Will Maintenance Learn To Love Fieldbus? Control Engineering, January, 19.
- Babb, Michael. (1994). Summer, 1994: Another Fieldbus Delay, Schneider's DPV, and Open Systems Control Engineering, July, 29.
- Gokorsch, Steve. (1994). Another Scenario: Maintenance Will Learn to Love Fieldbus Control Engineering, June, 112–114.
- Gunnel, Jeff. (1994). Analyser Links Can Use Fieldbus Control and Instrumentation, March, 33–35.
- Hodgkinson, Geoff. (1994). Communications Are We Listening? Process Engineering, Instrumentation Supplement 1994, s19–s21.
- Jones, Jeremy. (1992). Can Fieldbus Survive? Control and Instrumentation, August, 25–26.
- Kerridge, Brian. (1994). Network Vendors Aganize Over Fieldbus StandardEDN, April 28, 45–46.
- Rathje, J. (1994). Namur Says Yes To Fieldbus Technology and the Promise of Reduces Costs Control and Instrumentation, September, 33–34.
- Reeve, Alan. (1993). Fieldbus — Are Users Involved? Control and Instrumentation, August, 25–26.
- Spear, Mike. (1994). A Plant View of Fieldbus In Use Process Engineering, April, 38–39.
- Spear, Mike. (1994). Fieldbus Ready To Start The Last Lap? Process Engineering, April, 37.
External links
- USA: Fieldbus Foundation
- Foundation Fieldbus End User Councils
- Middle East: Foundation Fieldbus End User Council - Middle East
- Australia: Foundation Fieldbus End User Council Australia Inc