• Created by Teun Hendriks less than a minute ago  

...

This box suggests the current best answer

Prior revisions of answers

Proposal 4 (Consolidation item before meeting24 Mar 2026 )

Short Summary Answer

...

...

...

Short Summary Answer

Migrating from TMC

...

TMC relies on static, pre-coded location tables that limit coverage to predetermined road segments and require frequent maintenance. As digital mobility ecosystems evolve and more stakeholders use diverse maps (e.g. from Google, HERE, TomTom, Open Street Map), a map‑agnostic approach becomes essential. OpenLR supports unlimited coverage, map independence, and dynamic location encoding, enabling consistent interpretation of locations across different maps and versions. Its flexibility is better suited for modern traffic services, dynamic updates, and large-scale multi-map environments.

Stakeholder Relevance / Rationale

Relevance and rationale for migrating to OpenLR for various stakeholders can be summarized as follows:

• Public Authorities:  Supports interoperability across national access points and data platforms. Scales to new road networks, and eliminates dependency on pre-coded tables with limited coverage and associated maintenance costs.
• Content Providers: Enables consistent location exchange across different map providers. Simplifies data aggregation from heterogeneous sources. Reduces constraints caused by limited TMC location coverage.
• Service Providers: Facilitates real-time, high-volume traffic message handling. Supports dynamic updates that work across multiple map ecosystems. Avoids reliance on static TMC tables that may lag behind map updates.
• OEMs: Offers a flexible method for in‑vehicle systems where map providers vary. Allows dynamic encoding for real-time routing and ADAS services. Reduces the need for large, pre-installed TMC tables and updates thereof.

Detailed Explanation

Migration means adopting a fundamental change in referencing approach

TMC relies on fixed identifiers that point to pre‑defined entries in a centrally maintained location table. Each identifier refers to a known, pre‑coded location point, linear segment, or area, which guarantees deterministic and lightweight matching on the receiver side. However, this approach inherently restricts flexibility: only locations that have been coded in advance can be referenced, coverage is limited by the size and maintenance of the location table, and extending to new roads or regions requires coordinated updates across the ecosystem.

OpenLR works fundamentally differently. Instead of static identifiers, it generates dynamic location references derived from the actual geometry, topology, and attributes of the road network. Encoding a location therefore requires access to a routable digital map, as the encoder must understand how road segments connect, how paths are formed, and where decision points such as junctions and merges occur. While OpenLR is map‑agnostic in the sense that it is not tied to a specific vendor or map version, it nevertheless requires access to a suitable routable road network at encoding time.

(Traffic Message Channel) to OpenLR involves a shift from fixed, pre‑coded location tables to a dynamic, map‑agnostic location‑referencing approach. OpenLR enables significantly greater flexibility, supports virtually unlimited coverage of road networks and locations of interest, and improves interoperability across different digital map providers. At the same time, this transition introduces new technical, operational, and performance considerations. Whereas TMC encoding did not require access to a routable digital road network, now OpenLR encoding does depend on the availability of a suitable digital map with a routable road network. Successful adoption therefore requires careful attention to encoding accuracy, as well as verifying cross‑map interoperability of OpenLR encoders.

Why the Need for Migrating from TMC to OpenLR?

TMC relies on static, pre-coded location tables that limit coverage to predetermined road segments and require frequent maintenance. As digital mobility ecosystems evolve and more stakeholders use diverse maps (e.g. from Google, HERE, TomTom, Open Street Map), a map‑agnostic approach becomes essential. OpenLR supports unlimited coverage, map independence, and dynamic location encoding, enabling consistent interpretation of locations across different maps and versions. Its flexibility is better suited for modern traffic services, dynamic updates, and large-scale multi-map environments.

Stakeholder Relevance / Rationale

Relevance and rationale for migrating to OpenLR for various stakeholders can be summarized as follows:

• Public Authorities:  Supports interoperability across national access points and data platforms. Scales to new road networks, and eliminates dependency on pre-coded tables with limited coverage and associated maintenance costs.
• Content Providers: Enables consistent location exchange across different map providers. Simplifies data aggregation from heterogeneous sources. Reduces constraints caused by limited TMC location coverage.
• Service Providers: Facilitates real-time, high-volume traffic message handling. Supports dynamic updates that work across multiple map ecosystems. Avoids reliance on static TMC tables that may lag behind map updates.
• OEMs: Offers a flexible method for in‑vehicle systems where map providers vary. Allows dynamic encoding for real-time routing and ADAS services. Reduces the need for large, pre-installed TMC tables and updates thereof.

Detailed Explanation

Migration means adopting a fundamental change in referencing approach

TMC relies on fixed identifiers that point to pre‑defined entries in a centrally maintained location table. Each identifier refers to a known, pre‑coded location point, linear segment, or area, which guarantees deterministic and lightweight matching on the receiver side. However, this approach inherently restricts flexibility: only locations that have been coded in advance can be referenced, coverage is limited by the size and maintenance of the location table, and extending to new roads or regions requires coordinated updates across the ecosystem.

OpenLR works fundamentally differently. Instead of static identifiers, it generates dynamic location references derived from the actual geometry, topology, and attributes of the road network. Encoding a location therefore requires access to a routable digital map, as the encoder must understand how road segments connect, how paths are formed, and where decision points such as junctions and merges occur. While OpenLR is map‑agnostic in the sense that it is not tied to a specific vendor or map version, it nevertheless requires access to a suitable routable road network at encoding time. OpenLR requires source and target maps to meet "navigable map" standards.

Encoding/decoding TMC location references versus OpenLR location references

This section compares encoding and decoding of TMC location references with encoding and decoding of OpenLRLocation References, highlighting how each approach represents locations, constructs location references, and reconstructs them at the receiver side. By contrasting the table‑driven, point‑based nature of TMC with the map‑based, path‑oriented design of OpenLR, the following text

Encoding/decoding TMC location references versus OpenLR location references

This section compares encoding and decoding of TMC location references with encoding and decoding of OpenLRLocation References, highlighting how each approach represents locations, constructs location references, and reconstructs them at the receiver side. By contrasting the table‑driven, point‑based nature of TMC with the map‑based, path‑oriented design of OpenLR, the following text illustrates how these two mechanisms differ in terms of map dependency, flexibility, robustness, and suitability for various traffic and travel information ecosystems.

In summary, TMC and OpenLR represent two fundamentally different approaches to location referencing. TMC is table‑driven and map‑agnostic at encoding time, relying on predefined point locations and logical linkages rather than on a routable digital maps. Decoding TMC references requires TMC‑enabled maps that explicitly link road segments to TMC locations. OpenLR, by contrast, is fully map‑based: both encoding and decoding depend on routable digital maps, with location references defined as paths between Location Referencing Points enriched with line and path attributes. These attributes enable robust matching and route reconstruction, making OpenLR highly resilient to map differences across vendors and vintages. As a result, OpenLR offers greater flexibility, scalability, and interoperability for modern digital map ecosystems, while TMC reflects an earlier, compact, but more static approach to traffic location referencing.

Migrating from TMC to OpenLR: impact on Location Referencing Workflows

Migrating from TMC to OpenLR (has a direct impact on how locations are defined, encoded, transmitted, and decoded throughout the traffic information workflow. While TMC is based on pre‑coded, table‑driven location references with relatively simple encoding and decoding logic, OpenLR introduces a fully map‑based, dynamic approach that relies on routable digital maps and algorithmic matching. The table below compares the key workflow steps for TMC and OpenLR, highlighting how responsibilities, dependencies, and computational complexity shift when moving from a static to a dynamic location referencing paradigm.

Further migration considerations

• Performance and Bandwidth Considerations: The shift from TMC to OpenLR also introduces changes in message size and computational workload. TMC messages are extremely compact—typically only a few bytes—because they reference predefined IDs. OpenLR messages are larger, although size is rarely a limiting factor today. More important is the computational load: while encoding can be handled efficiently on central servers, decoding is significantly more demanding and must be performed on the end-user device. This is especially evident in major metropolitan areas such as London or Paris, where devices may need to decode large volumes of traffic messages within short timeframes. In such environments, CPU load may increase noticeably, potentially delaying the processing of subsequent message batches
• Legacy System Integration: TMC has been deeply embedded in navigation devices, broadcast protocols, and traffic‑management workflows for many years. As a result, migration to OpenLR typically requires transitional measures. These often include dual support for both formats, bidirectional conversion between TMC and OpenLR, and updates to broadcast or distribution systems. Maintaining continuity for existing services is an important operational requirement, making careful planning and phased migration essential.
• Quality Assurance: The transition to OpenLR requires thorough verification to ensure that encoded locations correspond correctly to their intended positions. This includes validating accuracy across different map versions, detecting mismatches caused by attribute or topology differences, and ensuring resilience as underlying maps evolve. Achieving this level of reliability requires automated QA infrastructure, consistent regression testing, and ongoing monitoring to verify that references continue to behave correctly as maps are updated.

• Governance and Standardization: TMC benefits from a long-standing standardized framework, although maintaining location tables is resource‑intensive. OpenLR is open and broadly adopted, but the ecosystem includes several variants—such as the TomTom formats, the ISO TPEG2‑OLR standard, and the XML‑based adaptations used in DATEX II and TN‑ITS. This diversity provides flexibility but introduces complexity when interoperability across stakeholders is required. Ensuring encoder–decoder compatibility across these variants is therefore an important aspect of system design and governance.

Decision Guide

• Requisite skills and Investment: Migrating from TMC to OpenLR is not merely a change in location referencing format, but a transition that requires dedicated development effort and specialized expertise. Implementing a functional OpenLR encoder/decoder typically involves knowledge in geographic information systems (GIS), routing algorithms, and map-matching techniques. Available reference implementations should not be considered “plug‑and‑play” solutions. Integrating OpenLR into a specific deployment context could require substantial customization, performance optimization, and validation effort.

Decision Guide

Implementation Notes

• Provide dual TMC/OpenLR output during transition to ensure backward compatibility.
• Pre-deployment testing must account for all major map vendors used by end users.
• Measure decoder performance under realistic, high‑volume scenarios.
• Establish automated QA and monitoring for geometric mismatches.

References & Tools

For understanding OpenLR as a method the following references are useful:

• OpenLR White Paper (PDF) 

• OpenLR_Decoding_bits_and_bytes v1.0,1 (PDF)

• ISO 21219-22 – TPEG2-OLR Standard

• TISA Github 

• GitHub Reference Implementation

• HOWTO.md Guide

• OpenLR Python Documentation

Comments

...

Proposal 3 (Consolidation item after meeting21 Jan 2026 )

Short Summary Answer

Migrating from TMC (Traffic Message Channel) to OpenLR means shifting from fixed, pre‑coded location tables to a dynamic, map‑agnostic referencing method. OpenLR offers greater flexibility, unlimited road network coverage of locations of interest, and cross-map interoperability.
Nonetheless, the migration introduces technical, operational, and performance considerations. Successful adoption requires careful planning around encoding accuracy, interoperability across digital map providers, decoder performance on end devices, and the integration of legacy systems.

Why the Need for Migrating from TMC to OpenLR?

TMC relies on static, pre-coded location tables that limit coverage to predetermined road segments and require frequent maintenance. As digital mobility ecosystems evolve and more stakeholders use diverse maps (e.g. from Google, HERE, TomTom, OSM), a map‑agnostic approach becomes essential. OpenLR supports unlimited coverage, map independence, and dynamic location encoding, enabling consistent interpretation of locations across different maps and versions. Its flexibility is better suited for modern traffic services, dynamic updates, and large-scale multi-map environments.

Stakeholder Relevance / Rationale

Relevance and rationale for migrating to OpenLR for various stakeholders can be summarized as follows:

• Public Authorities:  Supports interoperability across national access points and data platforms. Scales to new road networks, and eliminates dependency on pre-coded tables with limited coverage and associated maintenance costs.
• Content Providers: Enables consistent location exchange across different map providers. Simplifies data aggregation from heterogeneous sources. Reduces constraints caused by limited TMC location coverage.
• Service Providers: Facilitates real-time, high-volume traffic message handling. Supports dynamic updates that work across multiple map ecosystems. Avoids reliance on static TMC tables that may lag behind map updates.
• OEMs: Offers a flexible method for in‑vehicle systems where map providers vary. Allows dynamic encoding for real-time routing and ADAS services. Reduces the need for large, pre-installed TMC tables and updates thereof.

Detailed Explanation

Migration means adopting a fundamental change in referencing approach

TMC relies on fixed identifiers that point to pre‑defined entries in a location table. This approach guarantees deterministic matching, but it also restricts flexibility and limits coverage to only those locations that have been coded in advance.

OpenLR works fundamentally differently. Instead of static IDs, it generates dynamic encodings based on the actual geometry and attributes of the road network. Because it does not depend on a specific map version or vendor, it functions as a fully map‑agnostic method that can be used consistently across different maps and updates.

Migrating from TMC to OpenLR: impact on Location Referencing Workflows

Further migration considerations

• Performance and Bandwidth Considerations: The shift from TMC to OpenLR also introduces changes in message size and computational workload. TMC messages are extremely compact—typically only a few bytes—because they reference predefined IDs. OpenLR messages are larger, although size is rarely a limiting factor today. More important is the computational load: while encoding can be handled efficiently on central servers, decoding is significantly more demanding and must be performed on the end-user device. This is especially evident in major metropolitan areas such as London or Paris, where devices may need to decode large volumes of traffic messages within short timeframes. In such environments, CPU load may increase noticeably, potentially delaying the processing of subsequent message batches
• Legacy System Integration: TMC has been deeply embedded in navigation devices, broadcast protocols, and traffic‑management workflows for many years. As a result, migration to OpenLR typically requires transitional measures. These often include dual support for both formats, bidirectional conversion between TMC and OpenLR, and updates to broadcast or distribution systems. Maintaining continuity for existing services is an important operational requirement, making careful planning and phased migration essential.
• Quality Assurance: The transition to OpenLR requires thorough verification to ensure that encoded locations correspond correctly to their intended positions. This includes validating accuracy across different map versions, detecting mismatches caused by attribute or topology differences, and ensuring resilience as underlying maps evolve. Achieving this level of reliability requires automated QA infrastructure, consistent regression testing, and ongoing monitoring to verify that references continue to behave correctly as maps are updated.

• Governance and Standardization: TMC benefits from a long-standing standardized framework, although maintaining location tables is resource‑intensive. OpenLR is open and broadly adopted, but the ecosystem includes several variants—such as the TomTom formats, the ISO TPEG2‑OLR standard, and the XML‑based adaptations used in DATEX II and TN‑ITS. This diversity provides flexibility but introduces complexity when interoperability across stakeholders is required. Ensuring encoder–decoder compatibility across these variants is therefore an important aspect of system design and governance.

Decision Guide

Implementation Notes

• Provide dual TMC/OpenLR output during transition to ensure backward compatibility.
• Pre-deployment testing must account for all major map vendors used by end users.
• Measure decoder performance under realistic, high‑volume scenarios.
• Establish automated QA and monitoring for geometric mismatches.

References & Tools

For understanding OpenLR as a method the following references are useful:

• OpenLR White Paper (PDF) 

• OpenLR_Decoding_bits_and_bytes v1.0,1 (PDF)

• ISO 21219-22 – TPEG2-OLR Standard

• TISA Github 

• GitHub Reference Implementation

• HOWTO.md Guide

• OpenLR Python Documentation

Comments

...

Nevertheless, the large majority of modern in‑vehicle and backend systems are capable of handling OpenLR decoding for traffic updates without practical issues.

Agreed rewording: Notwithstanding the higher workload, millions of in‑vehicle and backend systems use OpenLR decoding for traffic updates without practical issues.

...

DS: I did not receive any confirmation from the car industry that this is the case

VW does not use OpenLR

Mercedes Audi, Stellantis, BMW, Kia use it. 

...

Need a example, TMC location codes, TMC labeling of road segments, and a generated OpenLR code.

TH: Let's see whether an example on USA maps can be generated. 

...

Explain this. Make workflow recommendation, with migration start from digital map, and parallel generate both TMC and OpenLR location reference, not first TMC LR then TMC decoding on map, then OpenLR encoding.  

...

• OpenLR supports various encoding formats: see [TISA-LR-OpenLR-FAQ2] - Different versions/types of OpenLR: What are they each good/bad at? What should be used for a given situation?. 
• Provide dual TMC/OpenLR output during transition to ensure backward compatibility.
  In TPEG feeds, using the TPEG2-LRC (Location Referencing Container) allows simultaneous transmission of both TMC and OpenLR location references within a single TPEG message.
• Pre-deployment testing must account for all major map vendors used by end users.
• Measure decoder performance under realistic, high‑volume scenarios.
• Establish automated QA and monitoring for geometric mismatches.

References & Tools

For understanding OpenLR as a method the following references are useful:

• OpenLR White Paper (PDF) 

• OpenLR_Decoding_bits_and_bytes v1.0,1 (PDF)

• ISO 21219-22 – TPEG2-OLR Standard

• TISA Github 

• GitHub Reference Implementation

• HOWTO.md Guide

• OpenLR Python Documentation

Proposal 2 (discussion item21 Jan 2026 )

Short Summary Answer

Migrating from TMC (Traffic Message Channel) to OpenLR means shifting from fixed, pre‑coded location tables to a dynamic, map‑agnostic referencing method. OpenLR offers greater flexibility, unlimited road network coverage of locations of interest, and cross-map interoperability.
Nonetheless, the migration introduces technical, operational, and performance considerations. Successful adoption requires careful planning around encoding accuracy, interoperability across map providers, decoder performance on end devices, and the integration of legacy systems.

Why the Need for Migrating from TMC to OpenLR?

TMC relies on static, pre-coded location tables that limit coverage to predetermined road segments and require frequent maintenance. As digital mobility ecosystems evolve and more stakeholders use diverse maps (e.g. from Google, HERE, TomTom, OSM), a map‑agnostic approach becomes essential. OpenLR supports unlimited coverage, map independence, and dynamic location encoding, enabling consistent interpretation of locations across different maps and versions. Its flexibility is better suited for modern traffic services, dynamic updates, and large-scale multi-map environments.

Stakeholder Relevance / Rationale

Relevance and rationale for migrating to OpenLR for various stakeholders can be summarized as follows:

• Public Authorities:  Supports interoperability across national access points and data platforms. Scales to new road networks, and eliminates dependency on pre-coded tables with limited coverage and associated maintenance costs.
• Content Providers: Enables consistent location exchange across different map providers. Simplifies data aggregation from heterogeneous sources. Reduces constraints caused by limited TMC location coverage.
• Service Providers: Facilitates real-time, high-volume traffic message handling. Supports dynamic updates that work across multiple map ecosystems. Avoids reliance on static TMC tables that may lag behind map updates.
• OEMs: Offers a flexible method for in‑vehicle systems where map providers vary. Allows dynamic encoding for real-time routing and ADAS services. Reduces the need for large, pre-installed TMC tables and updates thereof.

Detailed Explanation

Migration means adopting a fundamental change in referencing approach

TMC relies on fixed identifiers that point to pre‑defined entries in a location table. This approach guarantees deterministic matching, but it also restricts flexibility and limits coverage to only those locations that have been coded in advance.

OpenLR works fundamentally differently. Instead of static IDs, it generates dynamic encodings based on the actual geometry and attributes of the road network. Because it does not depend on a specific map version or vendor, it functions as a fully map‑agnostic method that can be used consistently across different maps and updates.

Migrating from TMC to OpenLR: impact on Location Referencing Workflows

Further migration considerations

• Performance and Bandwidth Considerations: The shift from TMC to OpenLR also introduces changes in message size and computational workload. TMC messages are extremely compact—typically only a few bytes—because they reference predefined IDs. OpenLR messages are larger, although size is rarely a limiting factor today. More important is the computational load: while encoding can be handled efficiently on central servers, decoding is significantly more demanding and must be performed on the end-user device. This is especially evident in major metropolitan areas such as London or Paris, where devices may need to decode large volumes of traffic messages within short timeframes. In such environments, CPU load may increase noticeably, potentially delaying the processing of subsequent message batches
• Legacy System Integration: TMC has been deeply embedded in navigation devices, broadcast protocols, and traffic‑management workflows for many years. As a result, migration to OpenLR typically requires transitional measures. These often include dual support for both formats, bidirectional conversion between TMC and OpenLR, and updates to broadcast or distribution systems. Maintaining continuity for existing services is an important operational requirement, making careful planning and phased migration essential.
• Quality Assurance: The transition to OpenLR requires thorough verification to ensure that encoded locations correspond correctly to their intended positions. This includes validating accuracy across different map versions, detecting mismatches caused by attribute or topology differences, and ensuring resilience as underlying maps evolve. Achieving this level of reliability requires automated QA infrastructure, consistent regression testing, and ongoing monitoring to verify that references continue to behave correctly as maps are updated.

• Governance and Standardization: TMC benefits from a long-standing standardized framework, although maintaining location tables is resource‑intensive. OpenLR is open and broadly adopted, but the ecosystem includes several variants—such as the TomTom formats, the ISO TPEG2‑OLR standard, and the XML‑based adaptations used in DATEX II and TN‑ITS. This diversity provides flexibility but introduces complexity when interoperability across stakeholders is required. Ensuring encoder–decoder compatibility across these variants is therefore an important aspect of system design and governance.

Decision Guide

Implementation Notes

• Provide dual TMC/OpenLR output during transition to ensure backward compatibility.
• Pre-deployment testing must account for all major map vendors used by end users.
• Measure decoder performance under realistic, high‑volume scenarios.
• Establish automated QA and monitoring for geometric mismatches.

References & Tools

For understanding OpenLR as a method the following references are useful:

• OpenLR White Paper (PDF) 

• OpenLR_Decoding_bits_and_bytes v1.0,1 (PDF)

• ISO 21219-22 – TPEG2-OLR Standard

• TISA Github 

• GitHub Reference Implementation

• HOWTO.md Guide

• OpenLR Python Documentation

Comments

...

Proposal 1 (discussion item26 Nov 2025 )

Migrating from TMC to OLR: what are typical issues:

CoPilot input

Great question! Migrating from TMC (Traffic Message Channel) location referencing—which uses pre-coded locations—to an on-the-fly method like OpenLR introduces several technical and operational challenges. Here are the key issues:

First present fundamental reasons to migrate:

Benefits

Opposite argument: TMC coverage is limited to pre-coded locations, OpenLR is unlimited

1. Fundamental Differences in Referencing Approach

• TMC: Uses a fixed, pre-defined location table (with IDs for road segments, junctions, etc.). This ensures consistency but limits flexibility.
• OpenLR: Encodes locations dynamically based on geometry and attributes, making it map-agnostic and more scalable.

Implication: Migration requires rethinking how locations are identified and transmitted—no more reliance on static IDs.

2. Map Provider Variability

• Different providers (Google, HERE, TomTom) have different network topologies, segment definitions, and attribute sets.
• OpenLR is designed to be map-independent, but accuracy depends on how well the encoding matches the target map.

Challenge: Ensuring interoperability and consistent decoding across providers.

3. Accuracy and Ambiguity

• TMC guarantees exact matches because of pre-coded IDs.
• OpenLR uses shortest-path algorithms and attribute matching, which can lead to:
  • Ambiguity in dense urban areas.
  • Errors if road attributes differ between source and target maps.

Mitigation: Fine-tuning encoding parameters and implementing robust fallback strategies.

Opposite argument: TMC coverage is limited to pre-coded locations, OpenLR is unlimited

4. Performance and Bandwidth

• TMC: Compact messages (just IDs).
• OpenLR: Larger payloads (geometry, attributes), which can impact bandwidth and processing time.

Consideration: Efficient encoding and compression are critical for real-time systems.

Size: Less of an issue now going from ~2-4 bytes to ~20-30 bytes per location reference

Encoding / decoding time and processing impact: 

• Encoding is more compute-intensive, but most often done on large server
• Decoding on user devices is much more compute intensive, and especially in large urban areas with lots of traffic messages (e.g. London, Paris) may strain a CPU and take a long time to process, which is a risk if the next batch of traffic messages. 

5. Legacy System Integration

• Many traffic systems, navigation devices, and broadcast protocols are built around TMC.
• Migration requires:
  • Dual support during transition.
  • Conversion tools (TMC ↔ OpenLR) for backward compatibility.

6. Quality Assurance

• Need to validate that OpenLR-referenced locations match intended real-world positions in a map-agnostic way ( handling multiple map versions from same map vendors, as well as maps from different vendors).
• Requires thorough testing and needs SW and data infrastructure for automatic machine-based error detection.
• Variations in maps and map updates could impact accuracy, and re-validation is advice. 

7. Governance and Standardization

• TMC is standardized and widely adopted, but supporting various versions of TMC location tables presents large overhead at the server side/encoding side.
• OpenLR is open source, also widely adopted, but less regulated, so encoder/decoder compatibility may require attention.

Comments

...