BS ISO 17572-3:2015
$215.11
Intelligent transport systems (ITS). Location referencing for geographic databases – Dynamic location references (dynamic profile)
| Published By | Publication Date | Number of Pages |
| BSI | 2015 | 116 |
This International Standard specifies location referencing methods (LRMs) that describe locations in the context of geographic databases and will be used to locate transport-related phenomena in an encoder system as well as in the decoder side. This International Standard defines what is meant by such objects and describes the reference in detail, including whether or not components of the reference are mandatory or optional, and their characteristics.
This International Standard specifies two different LRMs:
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pre-coded location references (pre-coded profile);
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dynamic location references (dynamic profile).
This International Standard does not define a physical format for implementing the LRM. However, the requirements for physical formats are defined.
This International Standard does not define details of the location referencing system (LRS), i.e. how the LRMs are to be implemented in software, hardware, or processes.
This part of ISO 17572 specifies the dynamic location referencing method, comprising
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attributes and encoding rules
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logical data modelling
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TPEG physical format specification for dynamic location references,
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coding guidelines for dynamic location references;
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compressed data format specification.
It is consistent with other International Standards developed by ISO/TC 204 such as ISO 14825.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 7 | Foreword |
| 8 | Introduction |
| 11 | 1 Scope 2 Normative references 3 Terms and definitions |
| 14 | 4 Abbreviated terms and attribute codes 4.1 Abbreviated terms |
| 15 | 4.2 Attribute codes |
| 16 | 5 Objectives and requirements for a location referencing method 6 Conceptual data model for location referencing methods 7 Specification of dynamic location references 7.1 General specification |
| 17 | 7.2 Location referencing building blocks 7.2.1 General 7.2.2 Points |
| 18 | 7.2.3 Attributes |
| 25 | 7.2.4 Next-point relationship 7.2.5 Attribute type list 8 Encoding rules 8.1 General |
| 31 | 8.2 General point representation and selection rules 8.3 Location reference core encoding rules 8.3.1 Location selection |
| 32 | 8.3.2 Location reference core point selection 8.3.3 Core point selection — Location points |
| 33 | 8.3.4 Core point selection — Intersection points |
| 35 | 8.3.5 Core point selection — Routing points |
| 37 | 8.3.6 Intersection point attributes |
| 38 | 8.3.7 Routing point attributes |
| 39 | 8.3.8 Location reference core encoding parameters 8.4 Location reference extension encoding rules 8.4.1 General |
| 40 | 8.4.2 Location reference extension necessity rules 8.4.3 Location reference extension point selection rules |
| 41 | 8.4.4 Location reference extension encoding parameters |
| 42 | 8.5 Coding of point locations 8.6 Coding of area locations 8.6.1 Coding of explicit area |
| 44 | 8.6.2 Coding of implicit area |
| 47 | 9 Logical data format specification 9.1 General 9.2 Data model definition 9.2.1 General |
| 48 | 9.2.2 General data model 9.2.3 Linear location data model |
| 49 | 9.2.4 Implicit area data model |
| 50 | 9.2.5 Explicit area data model |
| 51 | Annex A (informative) Dynamic location reference, TPEG2 logical structure |
| 68 | Annex B (normative) Dynamic location reference, TPEG2 binary representation |
| 76 | Annex C (normative) Dynamic location reference, TPEG2 XML representation |
| 83 | Annex D (informative) Coding guidelines for dynamic location references |
| 89 | Annex E (informative) Compressed data format specification |
| 113 | Bibliography |
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