|
US$1389.00 · In stock
Delivery: <= 10 days. True-PDF full-copy in English will be manually translated and delivered via email.
GBZ29619.2-2013: Digital data communication for measurement and control -- Fieldbus for use in industrial control systems -- Type 8: INTERBUS Specification -- Part 2: Physical Layer specification and service definition
Status: Valid
| Standard ID | Contents [version] | USD | STEP2 | [PDF] delivered in | Standard Title (Description) | Status | PDF |
| GB/Z 29619.2-2013 | English | 1389 |
Add to Cart
|
10 days [Need to translate]
|
Digital data communication for measurement and control -- Fieldbus for use in industrial control systems -- Type 8: INTERBUS Specification -- Part 2: Physical Layer specification and service definition
| Valid |
GB/Z 29619.2-2013
|
PDF similar to GBZ29619.2-2013
Basic data | Standard ID | GB/Z 29619.2-2013 (GB/Z29619.2-2013) | | Description (Translated English) | Digital data communication for measurement and control -- Fieldbus for use in industrial control systems -- Type 8: INTERBUS Specification -- Part 2: Physical Layer specification and service definition | | Sector / Industry | National Standard | | Classification of Chinese Standard | N10 | | Classification of International Standard | 25.040 | | Word Count Estimation | 63,688 | | Quoted Standard | GB/T 7424.2-2008; GB/T 9387.1; GB/T 11327.1-1999; GB/T 12269; GB/T 16422.1-2006; GB/T 18015.1-2007; IEC 60754-2; IEC 60811-2-1 - 1998; IEC 60874-2; ANSI TIA/EIA-422-B | | Adopted Standard | IEC 61158-2003, MOD | | Regulation (derived from) | National Standards Bulletin 2013 No. 10 | | Issuing agency(ies) | Ministry of Health of the People's Republic of China | | Summary | This standard specifies: the physical layer components requirements. Also provides media and network configuration requirements, to ensure that: a) the data link layer error before test data integrity, b) interoperable between the physical layer device op | GBZ29619.2-2013: Digital data communication for measurement and control -- Fieldbus for use in industrial control systems -- Type 8: INTERBUS Specification -- Part 2: Physical Layer specification and service definition
---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
Digital data communication for measurement and control. Fieldbus for use in industrial control systems. Type 8. INTERBUS Specification. Part 2. Physical Layer specification and service definition
ICS 25.040
N10
People's Republic of China national standardization of technical guidance documents
Measurement and control of digital data communications industrial control systems
With the fieldbus type 8.INTERBUS specification
Part 2. Physical layer specifications and service definitions
Fieldbus for use in industrial control systems-
Part 2.PhysicalLayerspecificationandservicedefinition
(IEC 61158.2003, MOD)
2013-07-19.2013-12-15 implementation
General Administration of Quality Supervision, Inspection and Quarantine of People's Republic of China
China National Standardization Administration released
Directory
Foreword V.
Introduction Ⅵ
1 Scope 1
2 Normative references 1
3 Terms and definitions 1
4 symbols and abbreviations 5
4.1 symbol 5
4.2 Abbreviations 5
5 DLL-PhL interface 6
5.1 Summary 6
5.2 Necessary Services 7
6 System Management - PhL Interface 15
6.1 PhL Management Function 15
6.2 PhL-PNM1 connector 15
7 Media-independent sub-layer (MIS) 19
7.1 Summary 19
7.2 Functions 19
7.3 Serial Transmission 19
7.4 MDS coupling 20
8 MIS-MDS interface 21
8.1 Overview 21
8.2 Service 21
8.3 Interface Signal 22
8.4 Service Converted to Interface Signals 23
Media Related Sublayer (MDS) 31
9.1 Functions 31
9.2 PhPDU format 31
9.3 Idle status 35
9.4 Reset PhPDU 35
9.5 MAU Coupling 36
10 MDS-MAU interface 37
10.1 Service Overview 37
10.2 Service Description 38
10.3 Response Time 39
10.4 Transmission Methods 39
Media Accessory Unit. Twisted Pair Media
11.1 MAU signal 39
11.2 Transmission bit rate related quantity 40
11.3 Network 40
11.4 Electrical Characteristics 41
11.5 Response Time 41
11.6 Interface to Transmission Medium 41
11.7 Transmission Media Specifications 42
Media Attachment Unit
12.1 Overview 44
12.2 Transmission Bit Rate Correlation 44
12.3 Network Topology 45
12.4 Transmission Circuit Specifications 45
12.5 Receiving Circuit Specifications 47
12.6 Transmission Media Specifications 47
Appendix A (Normative) Connector Specifications 52
References 54
Figure 1 physical layer and other layers relationship Ⅵ
Figure 2 General physical layer model Ⅵ
Figure 3 through the DLL-PhL interface mapping between data units 7
Figure 4 Master data sequence interaction
Figure 5 Master data sequence interaction. Data cycle 10
Figure 6 Slave data sequence interaction
Figure 7 Slave data sequence interaction. Data cycle 12
Figure 8 Master Check Sequence Interaction 13
Figure 9 Slave Check Sequence Interactions 14
Figure 10 Interface between PhL and PNM1 in a layered model 15
Figure 11 Reset, SetValue, GetValuePhL Services 16
Figure 12 EventPhL service 16
Figure 13 Interface Number Assignment 17
Figure 14 Master Configuration 20
Figure 15 Configuration of a Slave with a Transmission Selection Type 20
Figure 16 Configuration of a Bus Coupler with a Transmission Selection Type 21
Figure 17 Status Transition with ID Period Request Service 23
Figure 18 MIS-MDS Interface .Identificationcyclerequest service 24
Figure 19 MIS-MDS Interface .Identificationcyclerequest Service 25
Figure 20 Data Cycle Request State Transition of Service 25
Figure 21 MIS-MDS Interface .DataCycleRequest Service 26
Figure 22 Status Transition with Data Sequence Classification Service 27
Figure 23 MessageTransmission service protocol machine 27
Figure 24 DatasequenceIdentification service protocol machine 29
Figure 25 Messagereceipt Service Protocol Machine
Figure 26 Data Sequence PhPDU 31
Figure 27 Structure of PhPDU Header in Data Sequence 32
Figure 28 Check Sequence PhPDU 32
Figure 29 Structure of Header in Check Sequence PhPDU 33
Figure 30 Structure of state PhPDU 33
Figure 31 Structure of the header in a state PhPDU
Figure 32 Media Activity Status PhPDU 34
Figure 33 Structure of Header in Media Activity Status PhPDU 34
Figure 34 Reset PhPDU 35
Figure 35 Master Configuration 36
Figure 36 Slave Configuration 37
Figure 37 Bus Coupler Configuration 37
Figure 38 Jitter tolerance 39
Figure 39 Outbound Interface MAU 39
Figure 40 Incoming interface MAU 40
Figure 41 Remote Bus Link 41
Figure 42 Interface 41 to the transmission medium
Figure 43 Wiring 43
Figure 44 Termination resistor network 44
Figure 45 Fiber Optic Remote Bus Cable 44
Figure 46 Fiber Optic Remote Bus Link 45
Figure 47 Optical MAU Wave 46
Figure A.1 9 jacks 52 for the subminiature D connector output connector on the device
Figure A.2 9 pins 52 on the subminiature D connector input connector on the device
Figure A.3 Terminal connector on the device
Figure A.4 Optical F-SMA Connector Ferrule of Polymeric Fiber (980/1000 μm)
Table 1 Symbol 5
Table 2 PH-RESET 16
Table 3 Ph-SET-VALUE 17
Table 4 PhL Variables 17
Table 5 Ph-GET-VALUE 18
Table 6 Ph-EVENT 19
Table 7 PhL events 19
Table 8 MDSBusReset 22
Table 9 Signals at MIS-MDS Interface 22
Table 10 SL Bit and TxSL Signal Distribution 32
Table 11 SL Bit and RxSL Signal Distribution 32
Table 12 SL Bit and TxSL Signal Allocation 33
Table 13 SL Bit and RxSL Signal Allocation 33
Table 14 SL Bit and TxSL Signal Allocation 34
Table 15 SL Bit and RxSL Signal Allocation 34
Table 16 Encoding and decoding rules 35
Table 17 Decoding Rules for Idle States 35
Table 18 Reset PhPDU Encoding Rules 36
Table 19 Reset PhPDU decoding rules 36
Table 20 Services for the MDS-MAU Interface
TABLE 21 Bit Rate Correlation for Twisted Pair Media MAU 40
Table 22 Incoming Interface Signal 41
Table 23 Outbound interface signal 42
Table 24 Remote Bus Cable Features 42
TABLE 25 Optical MAU bit rate correlation 45
Table 26 Remote Bus Optical Fiber Cable Length 45
Table 27 coding rules 45
Table 28 Optical MAU Transmission Levels and Spectral Specifications Summary 46
Table 29 Optical MAU Receiver Circuit Specification Summary 47
Table 30 Optical waveguide specifications 48
Table 31 Single Optical Fiber Specification
Table 32 Optical fiber sheathing and optical cable mechanical specifications 48
Table 33 Recommended Properties for Further Characteristics of Cable Materials 49
Table 34 Fiber Optic Waveguide Specifications 49
Table 35 Single Optical Fiber Specification 50
Table 36 Cable sheathing and optical fiber mechanical specifications 50
Table 37 Standard Test Optical Fiber Specifications for Optical MAUs 50
Table A.1 9-pin sub-mini D connector distribution 52
Table A.2 Terminal Connector Pin Assignment 53
Foreword
GB /Z 29619 "Measurement and Control Digital Data Communications Industrial Control Systems Fieldbus Type 8. INTERBUS Specification"
Former divided into 6 parts.
--- Part 1. Overview;
--- 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.
This section GB /Z 29619 Part 2.
This section drafted in accordance with the rules given GB/T 1.1-2009 and GB/T 20000.2-2009.
GB /Z 29619 modified using IEC 61508.2003 "Measurement and Control Digital Data Communications Industrial Control Systems Fieldbus"
Part of the content, no adjustment in the technical content, the structure is divided into 6 parts to meet the needs of different users to use alone.
For ease of use, this section made the following editorial changes.
a) According to the actual use of our country, in accordance with the provisions of GB/T 1.1-2009, the original text was edited editorial changes
The content of surgery is exactly the same
b) reference to the original text of other international standards have been adopted or modified as our standard, this part of our standard number instead
Corresponding to the international standard number, the rest have not been the same or modified to use as our standard international advanced standards, are in this section
Direct reference.
This part is proposed by China Machinery Industry Federation.
This part of the National Industrial Process Measurement and Control Standardization Technical Committee (SAC/TC124) centralized.
This part of the drafting unit. Machinery Industry Instrumentation Technology and Economy Institute, Tsinghua University, Southwest University, Beijing Iron and Steel Design and Research
General Hospital, Shanghai Automation Instrumentation Co., Ltd., Shanghai Institute of Industrial Automation Instrumentation, Nanjing Phoenix Contact Electric Co., Ltd.
The main drafters of this section. Mei Ke, Zheng Xu, Liu Feng, Bao Weihua, Li Baihuang, Liu Zhaohui.
Introduction
INTERBUS is a digital serial communication system used in control systems (such as programmable logic controllers) and industrial sensors and actuators
Communication between field devices. These devices include simple limit switches and valves, as well as measurement sensors, measurement transmitters and actuators, and also
Can include sophisticated high-tech control systems such as controllers that control drive, torque, and process.
This section describes the physical layer specifications and services, which is closely related to GB /Z 29619 other parts. GB /Z 29619 by the Department
Separately define the "three-layer" reference model of the fieldbus that is the basic reference model for system interconnects. For ease of management, both reference models will be interactive
Even the standard range is subdivided into a series of normative layers. The relationship between the different layers shown in Figure 1.
NOTE The system management used in this section is a local mechanism for managing layers of protocols.
Figure 1 physical layer and other layers
The main purpose of this section is to provide a set of communication rules that are expressed by the procedures that peer physical layer entities implement when communicating.
The physical layer receives the data units from the data link layer, encodes them, adds communication frame information if necessary, combines the synthesized physical information
Number to a node on the transmission medium. The other node then receives the signal, decodes it, and passes it to the receiving device if necessary
Before the data link layer, but also delete the communication frame information.
This section contains the physical layer specification, corresponding to the DL-Layer protocol GB /Z 29619.4.
The physical layer of the general model shown in Figure 2.
Figure 2 physical layer generic model
The physical layer allows the transmission of received data units to another device through direct media access; it also allows access through other media
Ask about its transport protocol to transfer data units to another device.
The following types are specified.
--- Twisted pair media, the maximum rate of up to 16Mbit/s;
--- Fiber media, the maximum rate of up to 16Mbit/s.
The general characteristics of these transmission media are.
--- Full duplex transmission;
--- Not zero (NRZ) encoding.
The wire media type offers the following options.
--- Non-bus power supply, non-intrinsically safe;
--- Through the bus and other additional wire power supply, non-intrinsically safe.
Measurement and control of digital data communications industrial control systems
With the fieldbus type 8.INTERBUS specification
Part 2. Physical layer specifications and service definitions
1 Scope
GB /Z 29619 provisions of this part of the requirements of the physical layer components. Also provided for the media and network configuration requirements, to ensure.
a) data integrity before data link layer error checking;
b) Interoperability between physical layer devices.
The fieldbus physical layer complies with the first layer of the OSI 7-layer model of GB/T 9387.1.
2 Normative references
The following documents for the application of this document is essential. For dated references, only the dated version applies to this article
Pieces. For undated references, the latest edition (including all amendments) applies to this document.
GB/T 7424.2-2008 General specifications for optical fiber cables - Part 2. Basic test methods for optical cables (IEC 60794-1-2-2003, MOD)
GB/T 9387.1 Information technology - Open Systems Interconnection Basic Reference Model Part 1. Basic model (GB/T 9397.1-
1998, idtISO /IEC 7498.1.1994)
GB/T 11327.1-1999 PVC insulated PVC sheathed low frequency communications cables and wires Part 1. General test and measurement
Method (neq IEC 60189-1.1986)
GB/T 12269 RF cable general specification (GB/T 12269-1990, idtIEC 60096-1.1986)
GB/T 16422.1-2006 Plastics - Laboratory exposure test methods - Part 1. General (ISO 4892-1.1999, IDT)
Multicore and symmetrical pair/quad cables for digital communications - Part 1. Generic specification (IEC 61156-1).
2002, IDT)
Tests for gas released during combustion of IEC 60754-2 cables - Part 2 Determination of pH and conductivity by measurement
The acidity of the gas released from the burning of the cable material
IEC 60811-2-1.1998 General test methods for insulating and protective materials for electric cables and cables - Part 2-1 - Prescription for the elastomer
Method - Anti-ozone thermal coagulation and mineral oil immersion test
IEC 60874-2 Optical and Fiber Optic Connectors - Part 2. F-SMA Fiber Optic Connector Specifications
Electrical Characteristics of ANSITIA/EIA-422-B Balanced Potential Digital Interface Circuits
3 Terms and definitions
The following terms and definitions apply to this document.
3.1
Activity activity
The phenomenon that the signal or noise level of the fieldbus device input terminal is higher than the signal amplitude threshold of that device receiver.
|