ISO/DTS 22726-1

FINAL
TECHNICAL ISO/DTS
DRAFT
SPECIFICATION 22726-1
ISO/TC 204
Intelligent transport systems —
Secretariat: ANSI
Dynamic data and map database
Voting begins on:
2023-03-16 specification for connected
and automated driving system
Voting terminates on:
2023-05-11
applications —
Part 1:
Architecture and logical data model
for harmonization of static map data
Systèmes de transport intelligents — Spécification de données
dynamiques et de bases de données cartographiques pour les
applications de système de conduite connectées et automatisées —
Partie 1: Architecture et modèle logique de données pour
l'harmonisation des données cartographiques statiques
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BEING ACCEPTABLE FOR INDUSTRIAL, TECHNO-
ISO/DTS 22726-1:2023(E)
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NATIONAL REGULATIONS. © ISO 2023
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ISO/DTS 22726-1:2023(E)
FINAL
TECHNICAL ISO/DTS
DRAFT
SPECIFICATION 22726-1
ISO/TC 204
Intelligent transport systems —
Secretariat: ANSI
Dynamic data and map database
Voting begins on:
specification for connected
and automated driving system
Voting terminates on:
applications —
Part 1:
Architecture and logical data model
for harmonization of static map data
Systèmes de transport intelligents — Spécification de données
dynamiques et de bases de données cartographiques pour les
applications de système de conduite connectées et automatisées —
Partie 1: Architecture et modèle logique de données pour
l'harmonisation des données cartographiques statiques
COPYRIGHT PROTECTED DOCUMENT
© ISO 2023

All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may

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the internet or an intranet, without prior written permission. Permission can be requested from either ISO at the address below

Foreword ........................................................................................................................................................................................................................................iv

Introduction .................................................................................................................................................................................................................................v

1 Scope ................................................................................................................................................................................................................................. 1

2 Normative references ..................................................................................................................................................................................... 1

3 Terms and definitions .................................................................................................................................................................................... 1

4 Abbreviated terms and symbols .........................................................................................................................................................3

5 Document structure and conformance ........................................................................................................................................ 4

5.1 Document structure .......................................................................................................................................................................... 4

5.2 Conformance ............................................................................................................................................................................................ 4

6 Architecture.............................................................................................................................................................................................................. 4

7 Logical data model of map data ........................................................................................................................................................... 5

7.1 Overall data model of map data............................................................................................................................................... 5

7.2 Transportation package ................................................................................................................................................................. 6

7.3 MHAD package ....................................................................................................................................................................................... 7

7.3.1 General ........................................................................................................................................................................................ 7

7.3.2 RoadBeltNetwork package ..................................................................................................................................... 11

7.3.3 LaneBeltNetwork package ...................................................................................................................................... 45

7.3.4 RoadStructureAndEquipment package ...................................................................................................... 62

7.3.5 CommonPropertyClasses package ...............................................................................................................127

7.4 Relationship to dynamic information ..........................................................................................................................137

7.4.1 General ..................................................................................................................................................................................137

7.4.2 RoadNetworkElement .............................................................................................................................................137

Annex A (normative) Abstract test suite .................................................................................................................................................. 138

Annex B (informative) Basic data types and stereotypes — concepts and definitions ......................... 139

Annex C (informative) Resolution and accuracy of the MHAD ...........................................................................................141

Annex D (informative) Comparison of the road network models of MHAD and existing map

models ...................................................................................................................................................................................................................... 143

Bibliography ......................................................................................................................................................................................................................... 146

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This document was prepared by Technical Committee ISO/TC 204, Intelligent transport systems.

Any feedback or questions on this document should be directed to the user’s national standards body. A

In response to emerging automated driving system (ADS) development, a new requirement for an

intelligent transport system (ITS) map database standard has been raised to define a set of models for

The data used in ADS are categorized into static data (i.e. map for highly automated driving (MHAD) and

traditional map data) and dynamic data (e.g. traffic and travel information). These data are mutually

related and linked to support ADS. The data model for ADS should have a structure specialized for

In the case of static map data used by ITS, ISO 14296 specifies a logical data model applied to vehicle

navigation systems and cooperative ITS (C-ITS). The data model of ISO 14296 is insufficient for ADS

because of limitations to represent detailed or accurate carriageway and road-related features. In

addition, new relationships between new map features and dynamic data are defined.

Even though GDF 5.1 (ISO 20524-2) defines map data used in ADS such as road belts or lane belts as

detailed road map data, it focuses on a data model for exchanging and provisioning map data between

map makers and data centres. The GDF model which is based on three catalogues (Feature, Attribute,

and Relationship) is inefficient not only for storing ITS map data in a database but also to be able to

access that data rapidly in vehicles. Therefore, this document defines a database standard to quickly

The purpose of this document is to define a data model for connected and automated driving systems.

Implementation of this document can potentially lead to cost reductions in maintenance and expansion

of map access libraries, as well as reductions in compilation and maintenance costs of map and map-

related data for data providers for connected and automated driving, and vehicle control applications.

This document specifies the architecture and the logical data model of static map data for connected

The following documents are referred to in the text in such a way that some or all of their content

constitutes requirements of this document. For dated references, only the edition cited applies. For

undated references, the latest edition of the referenced document (including any amendments) applies.

ISO/IEC 19501, Information technology — Open Distributed Processing — Unified Modeling Language

ISO and IEC maintain terminological databases for use in standardization at the following addresses:

configuration concept for specifying an area bounded by side lines and terminal lines, characterized by

Note 1 to entry: The number of skeletonized axes differs depending on the feature class. In the case of a belt

applied to a one-way lane, the number is one. When applied to an intersection, the belt has axes corresponding to

signature of belt, determined by an allowed connection between a pair of terminal lines

two-dimensional Feature, represented by belt concept, bounded by three or more Edges or four or more

directed topological connection between two nodes, composed of an ordered sequence of one or more

data model entity for a topological junction of two or more links or end bounding a link

Note 1 to entry: A link stores the coordinate value of the corresponding GDF junction.

transversal line representing the boundary of a segment set to a road belt element and a lane belt

element, and both terminations are set on the sideline of road belt element or lane belt element

vehicle sensor information formatted as probe data elements and/or probe messages that are processed,

formatted and transmitted to a land-based centre for processing to create a good understanding of the

Note 1 to entry: This is a general term for the roadway, carriageways, intersections and lanes, and does not

[SOURCE: ISO 20524-2:2020, 3.4, modified — The admitted term "side line" has been added.]

type of boundary line constituting a belt feature and designated for determining a direction of a belt

— Annex D (informative) Comparison of the road network models of MHAD and existing map models

Any data structure claiming conformance with this document shall pass the requirements presented in

Throughout this document, the data types and stereotypes as defined in Table B.1 apply.

Automated driving systems (ADSs) and their applications can refer to both static map data and dynamic

information data. In addition, ITS stations in automated driving vehicles, connected vehicles and road

equipment can collect sensing data, such as contradictions between the static map and features of the

real world, traffic data, and travel information, and distribute them as probe data.

Figure 1 depicts the conceptual system architecture of map data in an ITS station for an ADS.

In ITS vehicle stations that correspond to ADSs, the application uses map data (MHAD) and additional

dynamic data. The original data, along with updates of the MHAD data and dynamic data, are intended

to be provided through external transmitted messages received from outside of the station. Automated

driving applications also use data collected from both in-vehicle and roadside mounted sensors and can

also use conventional map data which complements the applications to which the navigation system

The overall map data model for ITS is adopted from the model defined in ISO 14296 which consists of

— AddressLocation: location information based on various types of information both on the Earth and

— Service&POI: information of the services and POI that exist in a fixed location;

— DynamicInformation: external information in association with transportation data for providing

To support ADS, both the Transportation and DynamicInformation packages are expanded.

Following the addition of the MHAD package to the Transportation package, the updated package

— MHAD: data for road belt network, lane belt network, and road structures and equipment for

— TransferZoneNetwork: information concerning place and connected network for transferring with

— PublicTransportationNetwork: static network data for the public transportation system;

The TransferZoneNetwork package and the RoadNetwork package are defined in ISO 14296.

The RoadNetwork package contains features represented by links and nodes, in multiple levels

corresponding to the concept of different map scales. The features in the MHAD package can be related

to road features such as RoadElement, Intersection, IntersectionLink, IntersectionConnectionPoint and

A connected and/or automated driving system requires the road belt network data, the lane belt

network data and the road structures and equipment data related to road features. The MHAD

represents the data model for a static map of the road and consists of the following packages:

— RoadBeltNetwork package — defines belt features and relevant features which compose road-level

— LaneBeltNetwork package — defines belt features and relevant features which compose lane-level

— RoadStructureAndEquipment package — defines road structures and road equipment which are

— CommonPropertyClasses package — defines the data classes commonly used in multiple sub-

The MHAD package contains an MHAD class which is defined as the root class for the entire package.

Figure 5 shows the classes and relationships for expressing the hierarchical model of the MHAD

Roadways and intersections are expressed by lines and points in conventional road network data

models. However, emerging ITS applications (e.g. lane keeping for C-ITS and automated driving systems)

require highly defined information that enables the vehicle to identify where it is driving in a lane, and

To provide such information, road features, such as the roadway, intersections and lanes need to be

expressed by specific area features which have characteristics implying directions and/or trajectories

of moving vehicles. An instance of this specific area feature is transformed into a directed line that

corresponds to a possible directed trajectory of regular vehicle movement when it is degenerated by

A conventional data model enables a vehicle to identify in which road and/or lane it is driving. However,

an area feature in the conventional data model merely expresses a space for free motion and does not

imply any specific directions. Thus, the area feature in the conventional data model does not meet the

The "belt concept" and belt features specified in ISO 20524-2 meet the recommendation that roads,

intersections and lanes should be represented by a specific area feature with the directions defined as

their characteristics. As illustrated in Figure 6, a belt feature is a specific area feature which is bounded

In the case of a road [Figure 6 a)], a belt has at least one directional characteristic, the “direction”.

Additionally, the belt can have other characteristics which include the widths of the belt that are

calculated as the distance between a pair of sidelines for that belt. The value width should be associated

The terminal lines define the characteristics of the belt direction. In the case of an intersection

[Figure 6 b)], a belt has at least two directional characteristics. Widths of a belt are calculated as the

distance between a pair of sidelines which determine both sides of the belt except in an intersection.

In the belt data model, terminal lines are conceptually represented and assumed to function as

"directional control valves" at both ends of a flow. Sidelines are also conceptually represented and can

refer to real road-related objects (e.g. lane markings, flow-markings, kerbs, guardrails, etc.).

In the MHAD package, road features are instantiated as features in a RoadBeltNetwork package and a

7.3.1.3 Relationship between road feature and road structures and equipment feature

In the real world, there are various features located at or along roads such as road markings, traffic

signals, kerbs, manholes, fences, walls, guardrails and poles. These features are referred to as road

structures or road equipment and are instantiated as features in the RoadStructureAndEquipment

As road structures and road equipment are located at or along a road, they can have relationships

with road features such as those defined by the RoadBeltNetwork package and the LaneBeltNetwork

package. When road structures and road equipment are interrelated, it is necessary to define the

specific location on the road feature that relates to the corresponding part of the road structures and

EXAMPLE The outline of a kerb represents the boundary of the kerb itself and at the same time represents a

In the MHAD data model, road features have anchor positions that are used to associate road structures

or pieces of road equipment to the road and indicate the position where the road structures and/or

A projection point is a point positioned on the geometry of the road structures and road equipment

and associated to the anchor position. A projection line is an outline of the road structures or road

equipment, partly specified by a pair of projection points. Both the projection point and project line

of road structures or road equipment are designed to include traffic restrictions due to the physical

properties of the road structures and road equipment, and they can be used as reference positions for

positioning functions. Anchor positions are defined as RoadAnchorPosition, IntersectionAnchorPosition

Figure 7 shows examples of the relationship of anchor positions and projection points between a road

Figure 7 — Example of relationship between a road belt element and a bridge and a guardrail

The MHAD class is the root class of the MHAD package and has three composition relationships.

Dataset representing the static road network map which consists of the datasets of

the road belt network, the lane belt network, and the road structures and equipment.