Smart Roads Anemometers Market | Latest Analysis, Demand Trends, Growth Forecast 

Smart Roads Anemometers Market Supply Chain Expands Around MEMS Sensors, ITS Electronics, and Roadside Weather Monitoring Infrastructure

The Smart Roads Anemometers Market is closely tied to intelligent transportation infrastructure spending, roadside environmental sensing deployments, and highway safety modernization programs rather than conventional meteorological equipment demand. By early 2026, the market size is estimated at approximately USD 420–470 million, with ultrasonic and MEMS-integrated systems accounting for more than 58% of deployed smart-road wind sensing units globally.

The supply chain is concentrated across East Asia, North America, and parts of Northern Europe, where sensor fabrication, low-power electronics manufacturing, industrial communication modules, and traffic systems integration are clustered. China alone contributes an estimated 34%–38% of global production volumes for traffic-grade environmental sensing hardware, while Japan, Germany, and the United States dominate higher-precision ultrasonic anemometer assemblies used in expressway automation and connected transport corridors.

The upstream ecosystem supporting the Smart Roads Anemometers Market involves semiconductor MEMS fabs, industrial PCB manufacturers, piezoelectric sensor suppliers, aluminum die-casting vendors, IoT connectivity chipset companies, and roadside ITS integrators. Unlike traditional weather stations, smart-road anemometers are increasingly deployed as part of integrated road weather information systems (RWIS), meaning procurement decisions are frequently linked to broader highway digitalization contracts. This changes supply dynamics significantly because transportation agencies increasingly prioritize interoperable sensor networks instead of standalone wind monitoring devices.

A noticeable shift occurred during 2024 and 2025 as national transport authorities accelerated deployment of climate-adaptive roadway systems. In March 2025, the German Federal Ministry for Digital and Transport expanded funding under its digital road corridor modernization initiative with investments exceeding EUR 1.2 billion for sensorized autobahn infrastructure, including roadside weather sensing nodes and V2X communication systems. Such programs directly increased procurement demand for ultrasonic wind sensing systems capable of supporting dynamic speed control during crosswind events.

Semiconductor and Sensor Fabrication Base Defines Smart Roads Anemometers Market Production Economics

The Smart Roads Anemometers Market depends heavily on industrial sensing semiconductors and low-power edge computing electronics. MEMS-based airflow sensing components used in compact roadway wind sensors are largely fabricated in Taiwan, Japan, South Korea, and China. Taiwan’s semiconductor ecosystem plays a critical role because several traffic sensing OEMs source mixed-signal ICs and sensor controllers from fabs linked to automotive-grade electronics supply chains.

Japan continues to hold a strong position in precision airflow sensing technologies due to its mature industrial instrumentation sector. Japanese manufacturers specializing in ultrasonic transducer modules, ceramic piezoelectric components, and ruggedized sensor housings maintain strong export volumes to North American and European highway automation projects. In 2025, Japanese industrial sensor exports associated with transportation infrastructure systems recorded double-digit shipment growth, supported by expressway modernization projects across Southeast Asia.

China dominates the lower-cost manufacturing segment of the Smart Roads Anemometers Market through integrated production clusters in Guangdong, Zhejiang, and Jiangsu. These regions support large-scale assembly of roadside sensing equipment, industrial IoT gateways, solar-powered monitoring units, and environmental telemetry systems. China’s role became more important after multiple provinces accelerated smart highway construction programs. During September 2024, Zhejiang Province announced expansion of smart expressway infrastructure covering more than 1,600 kilometers, including deployment of distributed environmental monitoring systems. Such projects strengthened domestic procurement of roadside wind and visibility sensors.

The United States maintains a stronger position in high-performance transportation-grade weather intelligence systems rather than mass-volume hardware manufacturing. American companies remain significant suppliers of integrated RWIS software, AI-assisted traffic weather analytics, and federally compliant roadway monitoring systems. State transportation agencies increasingly require predictive hazard analytics alongside physical wind measurements, creating additional demand for advanced sensor fusion architectures.

ITS Infrastructure Spending Changes Procurement Structure for Roadside Wind Monitoring Systems

The procurement structure of the Smart Roads Anemometers Market differs substantially from conventional industrial instrumentation sectors because purchases are increasingly bundled into intelligent transportation system contracts. Instead of transportation agencies acquiring standalone anemometers, systems are now integrated into digital traffic management networks, smart gantries, connected bridges, and autonomous mobility corridors.

This integration trend accelerated after severe weather disruptions affected highway networks across Europe, North America, China, and the Middle East between 2024 and 2025. In January 2025, the U.S. Federal Highway Administration expanded climate resilience funding allocations for state-level transportation monitoring systems under multiple infrastructure modernization programs. Several western states increased deployment of crosswind monitoring systems along elevated bridges and freight corridors where extreme weather events disrupted heavy-vehicle operations.

The Smart Roads Anemometers Market also benefits from growing adoption of automated traffic control systems. Variable speed limit infrastructure increasingly relies on live wind-speed data to regulate truck movement on exposed corridors. Scandinavian countries remain important deployment centers because high crosswind exposure and winter storm conditions require dense roadside weather sensing networks. Norway and Sweden continue upgrading bridge safety systems using ultrasonic anemometers integrated with automated warning displays and connected transport management platforms.

Middle Eastern countries are becoming an emerging demand center due to large-scale smart mobility investments. Saudi Arabia’s smart infrastructure programs associated with NEOM and advanced highway connectivity projects have increased demand for environmental sensing systems capable of operating under high-temperature desert conditions. Wind monitoring requirements in these environments are linked not only to traffic safety but also to dust storm detection and visibility management.

Ultrasonic Technology Gains Share as Mechanical Systems Face Reliability Pressure

Mechanical cup anemometers still exist in some roadway monitoring deployments, but the Smart Roads Anemometers Market is steadily shifting toward ultrasonic sensing architectures because maintenance requirements are lower and operational reliability is higher under harsh environmental conditions. Ultrasonic systems accounted for nearly two-thirds of newly installed smart-road wind sensors during 2025, particularly across Europe and North America.

Transportation authorities increasingly favor solid-state sensing systems because roadside maintenance costs continue rising. Highway operators managing long-distance corridors seek equipment capable of operating continuously with minimal servicing intervals. This is especially important for mountainous regions, bridges, and remote freight routes where maintenance logistics are expensive.

In Canada, provincial transportation agencies expanded deployment of non-mechanical weather sensing infrastructure during late 2024 following repeated winter storm disruptions affecting freight mobility. Several corridor modernization projects across Alberta and British Columbia integrated ultrasonic wind sensors into avalanche warning and traffic hazard systems. Similar adoption patterns are visible in Alpine transport corridors across Austria and Switzerland.

MEMS-assisted compact anemometers are also gaining traction in urban smart-road deployments where municipalities prioritize low-power operation and wireless connectivity. These systems are frequently integrated into multifunction traffic poles alongside air quality sensors, thermal cameras, and adaptive traffic signaling equipment. Urban deployments generally require smaller sensing footprints and edge analytics capability rather than long-range meteorological precision.

Raw Material and Electronics Dependencies Affect Supply Stability Across the Smart Roads Anemometers Market

Material dependency in the Smart Roads Anemometers Market is more electronics-intensive than metal-intensive. Semiconductor availability, industrial microcontrollers, piezoelectric ceramics, wireless communication modules, and ruggedized PCB substrates are more critical than structural raw materials. Aluminum housings and stainless-steel mounting assemblies remain important, but electronic component availability determines production lead times.

During 2024, industrial connectivity chipset shortages affected delivery schedules for several ITS hardware vendors supplying transportation agencies in Europe and North America. Procurement cycles for roadway sensing systems lengthened because integrated communication modules supporting LTE, 5G, LoRaWAN, and DSRC connectivity were prioritized for automotive and industrial automation sectors.

Environmental durability requirements also influence material selection. Roadside wind sensors must withstand corrosion, vibration, road salt exposure, UV radiation, and temperature fluctuations for extended operational periods. As a result, suppliers increasingly use marine-grade aluminum alloys, reinforced polymer composites, and sealed electronics enclosures compliant with IP66 and IP67 standards.

Supply concentration remains moderately high. A limited number of companies control advanced ultrasonic sensing modules suitable for transportation-grade deployment. European and Japanese manufacturers maintain stronger credibility in high-accuracy systems, while Chinese suppliers continue gaining share in cost-sensitive deployments across developing regions. This pricing divergence is influencing procurement strategies, especially in Southeast Asia, Latin America, and parts of Eastern Europe where governments seek lower infrastructure deployment costs without compromising digital connectivity requirements.

The Smart Roads Anemometers Market is therefore evolving less as a standalone instrumentation segment and more as a specialized component category inside the broader intelligent transportation infrastructure ecosystem. Demand patterns increasingly depend on highway digitalization budgets, roadside IoT deployment density, and climate-resilient transportation investments rather than traditional meteorological equipment replacement cycles.

Smart Roads Anemometers Market Segmentation Reflects Shift Toward Intelligent Transportation and Climate-Responsive Infrastructure

The Smart Roads Anemometers Market is no longer limited to conventional roadway weather stations. Deployment patterns now align with broader investments in connected transport systems, climate resilience infrastructure, bridge safety automation, and digital highway management. The downstream application ecosystem has widened considerably because transportation agencies increasingly treat wind sensing as a core operational input for automated traffic regulation rather than a passive environmental monitoring function.

Application concentration remains strongest in highway and expressway infrastructure, but rapid deployment growth is also visible in smart bridges, tunnel networks, urban mobility systems, autonomous freight corridors, and airport-linked roadway systems. Procurement patterns differ substantially across these applications because sensing accuracy, environmental durability, and response latency requirements vary by traffic density and weather exposure.

Segmentation Highlights Across the Smart Roads Anemometers Market

• Highways and expressways account for nearly 46% of total deployment volume in 2026 due to crosswind risk management and dynamic speed control systems.
• Bridge and elevated roadway monitoring contributes approximately 18% of demand, particularly in coastal and mountainous regions.
• Urban smart mobility corridors represent one of the fastest-growing segments with projected deployment growth exceeding 13% annually through 2029.
• Ultrasonic anemometers dominate premium installations, accounting for more than 60% of new smart-road projects.
• MEMS-integrated compact systems are gaining traction in municipal traffic management infrastructure because of lower power consumption and easier wireless integration.
• North America and Europe collectively represent more than half of software-integrated roadway weather monitoring deployments.
• China remains the largest single-country deployment market by unit volume due to extensive smart expressway construction programs.
• Demand from autonomous and connected vehicle corridors is expanding faster than conventional traffic weather applications.

Highway Automation Systems Generate Largest Revenue Share

Expressway and interstate highway operators remain the largest downstream buyers in the Smart Roads Anemometers Market because wind-speed intelligence is increasingly integrated into traffic automation systems. Strong crosswinds remain a major operational concern for freight-heavy transport corridors, suspension bridges, elevated road sections, and open desert highways.

Road operators are deploying anemometers alongside dynamic message signs, adaptive lane management systems, and AI-assisted traffic platforms. Instead of relying on regional meteorological stations, authorities increasingly require localized roadway wind data with sub-minute response intervals.

China’s smart highway expansion continues to influence global deployment volumes. During June 2025, Jiangsu Province expanded its intelligent expressway network with additional sensorized corridors exceeding 500 kilometers, integrating traffic flow monitoring, wind detection, and automated hazard alert infrastructure. Similar projects across Guangdong and Zhejiang accelerated procurement of roadside environmental sensing systems optimized for high-speed transport routes.

In the United States, wind monitoring demand is closely tied to freight logistics reliability. The American Transportation Research Institute has repeatedly highlighted weather-related freight disruption costs exceeding billions of dollars annually across major trucking corridors. As a result, state transportation departments are expanding deployment of real-time roadside environmental intelligence systems, particularly in Wyoming, Texas, Colorado, and the Midwest where crosswind-related truck accidents remain a persistent operational issue.

Smart Bridge Infrastructure Increases Deployment Density of Advanced Wind Sensors

Bridge infrastructure has become a strategically important application area within the Smart Roads Anemometers Market. Wind conditions on long-span bridges fluctuate more rapidly than surrounding road networks, requiring continuous localized monitoring. This has increased demand for high-precision ultrasonic anemometers integrated with automated warning systems.

Japan remains one of the most advanced bridge monitoring markets because of strict operational requirements for typhoon-prone coastal transport infrastructure. Several bridge operators upgraded sensor networks between 2024 and 2025 to improve real-time structural and environmental monitoring capabilities. Wind sensing systems are increasingly linked to automated vehicle restriction systems for heavy trucks and buses.

European deployment patterns also reflect climate adaptation priorities. Scandinavian countries continue investing in smart bridge monitoring because winter storms and high coastal wind exposure affect transport continuity. Norway’s Public Roads Administration expanded digital monitoring systems on multiple fjord crossings during late 2024, increasing deployment of integrated weather intelligence infrastructure.

Bridge applications generally favor premium systems with low maintenance requirements because servicing suspended or remote structures is operationally expensive. This strengthens demand for ultrasonic and hybrid solid-state systems instead of rotating mechanical designs.

Urban Mobility Corridors Push Compact Smart Roads Anemometers Deployment

Urban smart mobility infrastructure is changing product design requirements across the Smart Roads Anemometers Market. Municipal deployments prioritize compact architecture, wireless communication, edge analytics capability, and integration with broader smart-city infrastructure.

Unlike highway applications where sensing range is critical, urban installations focus more on localized environmental intelligence supporting traffic signal optimization, emergency response systems, and pollution monitoring networks. Wind data is increasingly used to model air dispersion patterns around congested intersections and tunnels.

South Korea and Singapore have accelerated deployment of urban roadside sensing infrastructure linked to intelligent traffic management systems. Seoul’s smart mobility investments expanded during 2025 through integrated sensor deployments supporting connected traffic operations and weather-adaptive signaling systems. Singapore’s Land Transport Authority also expanded environmental sensing coverage near major expressway and tunnel systems as part of broader intelligent mobility upgrades.

Urban adoption favors MEMS-assisted anemometers because municipalities require smaller form factors and lower installation costs. Wireless roadside poles equipped with multi-sensor arrays increasingly combine wind detection, particulate monitoring, thermal imaging, and adaptive lighting controls within a single infrastructure node.

Airport-Linked Road Networks and Tunnel Systems Expand Specialized Demand

A smaller but technically significant downstream segment involves airport-linked transportation corridors and tunnel infrastructure. Wind turbulence around airports and enclosed roadway systems can rapidly affect vehicle stability and traffic flow, particularly for buses, freight vehicles, and hazardous material transport.

Middle Eastern countries are increasing investment in this category as large-scale airport expansion projects require integrated roadway weather intelligence systems. Saudi Arabia and the United Arab Emirates expanded intelligent transport infrastructure procurement during 2024 and 2025 alongside airport modernization and logistics corridor development.

Tunnel operators are also deploying smart anemometers to support ventilation optimization and emergency response management. In Europe, tunnel modernization projects increasingly integrate airflow sensing into centralized operational platforms that manage smoke extraction, hazardous weather alerts, and traffic control systems simultaneously.

Demand Trend Across the Smart Roads Anemometers Market

Demand trends in the Smart Roads Anemometers Market are increasingly influenced by climate-related transport disruptions and digital highway modernization budgets rather than conventional weather instrumentation replacement cycles. Governments and transport authorities are prioritizing localized environmental intelligence because severe weather volatility is directly affecting freight efficiency, accident rates, and roadway operational continuity.

Between 2024 and 2026, multiple countries expanded infrastructure budgets specifically targeting resilient transportation systems. India accelerated deployment of intelligent transport systems across national highways under broader digital infrastructure initiatives, increasing procurement of roadway monitoring equipment. In Europe, transport ministries allocated larger budgets toward weather-responsive traffic systems following repeated storm-related disruptions affecting freight corridors and bridge operations.

The market is also benefiting from connected and autonomous vehicle ecosystem development. Vehicle-to-infrastructure communication systems increasingly require real-time environmental data inputs, including roadside wind conditions. This requirement is particularly important for automated freight operations and high-speed transport corridors where localized weather fluctuations can alter braking, lane stability, and traffic management decisions.

Demand growth remains strongest in countries where smart transportation infrastructure spending is supported by centralized public investment programs. Cost-sensitive markets continue favoring lower-priced compact systems, while North America, Northern Europe, Japan, and parts of the Gulf region are shifting toward integrated premium-grade environmental sensing platforms with predictive analytics capability.

Traffic Safety Regulations Continue Supporting Long-Term Deployment Outlook

Regulatory emphasis on traffic safety and operational resilience remains a major downstream demand driver for the Smart Roads Anemometers Market. Transportation authorities increasingly require continuous environmental monitoring for critical infrastructure rather than periodic meteorological observation.

Several regions have tightened operational standards for elevated highways and freight corridors exposed to high wind conditions. This is pushing infrastructure operators to install permanent sensing systems capable of supporting automated decision-making. Wind monitoring is also becoming more integrated into centralized transportation command platforms where weather analytics, traffic density data, and incident response systems operate within unified control environments.

As roadway infrastructure becomes more digitized, smart-road anemometers are evolving into embedded traffic intelligence assets rather than standalone weather instruments. This transition is reshaping product specifications, deployment density, software integration requirements, and long-term procurement strategies across transportation infrastructure networks globally.

Major Manufacturers Competing Through Ultrasonic Accuracy, ITS Compatibility, and Low-Maintenance Architecture

The competitive structure of the Smart Roads Anemometers Market is moderately consolidated at the premium technology level, while regional manufacturers and ITS subsystem suppliers compete aggressively in mid-range deployments. Global market participation is led by companies specializing in ultrasonic wind sensing, road weather information systems (RWIS), intelligent transportation infrastructure, and industrial meteorological instrumentation.

Manufacturers supplying transportation-grade anemometers increasingly compete on long-term operational reliability rather than only measurement precision. Highway agencies and infrastructure operators now prioritize maintenance-free operation, corrosion resistance, remote diagnostics, and integration with centralized traffic management systems. This has shifted competitive advantage toward companies with proven transportation and environmental monitoring portfolios rather than traditional meteorological instrument suppliers alone.

Finland-based Vaisala remains one of the strongest technology participants in the premium roadway weather monitoring segment. The company’s WINDCAP WMT700 ultrasonic wind sensor and WXT530 weather transmitter series are widely deployed across transportation, aviation, and environmental monitoring systems. Vaisala’s transportation-focused offerings benefit from integration capabilities with road weather intelligence platforms and automated traffic safety systems. The WMT700 series is designed for high-durability applications with stainless-steel construction, no moving parts, and compliance with operational standards required for critical infrastructure monitoring.

Vaisala’s broader positioning in transportation weather systems strengthened during 2024 and 2025 as infrastructure authorities increased investments in integrated roadway intelligence systems rather than standalone sensing devices. The company expanded emphasis on environmental intelligence software integration and predictive weather analytics, supporting wider adoption in intelligent transportation infrastructure.

UK-based Gill Instruments is another significant manufacturer within the Smart Roads Anemometers Market, particularly in ultrasonic wind sensing systems for transportation and smart infrastructure applications. Its WindSonic, WindObserver, and WindUltra product families are widely used across transport monitoring, smart-city infrastructure, marine systems, and industrial environmental sensing applications. Gill’s WindSonic platform is positioned as a compact ultrasonic sensor for high-volume deployment environments, while the WindObserver series targets harsher operating conditions requiring anti-icing capability and ruggedized stainless-steel construction.

Gill Instruments has increasingly focused on minimizing total ownership costs and reducing maintenance requirements, aligning closely with transportation authority procurement priorities. Ultrasonic systems without moving parts are becoming more attractive because roadside maintenance operations create traffic disruption and recurring labor expenses. The company has also expanded focus on smart-city and transportation applications where compact environmental sensing systems are integrated into multi-sensor roadside infrastructure.

German environmental sensing specialist Lufft maintains a strong presence in intelligent transportation and RWIS deployments across Europe and North America. The company’s Ventus ultrasonic wind sensor series and V200A-UMB wind sensor products are designed for continuous operation under severe environmental conditions, including icing, vibration exposure, and coastal weather conditions. Lufft sensors are widely integrated into traffic weather stations and highway environmental monitoring systems because of their compatibility with transportation communication protocols and low-maintenance ultrasonic architecture.

Lufft’s competitive strength comes from its concentration on transportation weather infrastructure rather than general-purpose meteorological instrumentation. The company has focused heavily on intelligent transportation applications including bridge monitoring, tunnel systems, and roadway weather networks where environmental durability and remote operation are essential.

In the United States, companies such as Campbell Scientific continue participating in roadway weather sensing through integrated environmental monitoring platforms used by transportation departments and highway operators. Campbell Scientific systems are often deployed as part of broader RWIS infrastructure where wind monitoring is combined with pavement condition sensing, visibility measurement, precipitation detection, and remote telemetry integration.

Japanese manufacturers also maintain technological importance in precision airflow sensing technologies used for transport infrastructure monitoring. Japanese sensor suppliers benefit from expertise in ultrasonic transducers, industrial electronics miniaturization, and ruggedized sensing components suitable for coastal and typhoon-prone transportation networks.

China’s role in the Smart Roads Anemometers Market is increasingly tied to high-volume manufacturing and smart expressway deployment. Domestic ITS equipment manufacturers continue integrating compact ultrasonic wind sensing modules into broader smart-road infrastructure platforms. Chinese suppliers remain highly competitive in price-sensitive projects across Southeast Asia, the Middle East, and developing transportation markets where governments prioritize deployment scale and cost efficiency.

Qualification and Reliability Standards Shape Procurement Decisions

Qualification requirements in the Smart Roads Anemometers Market are significantly stricter than those for standard industrial airflow monitoring equipment. Transportation agencies require continuous operation under severe weather exposure, vibration, pollution, road salt corrosion, and wide temperature fluctuations.

Most premium roadway anemometers are expected to comply with international operational standards covering wind measurement accuracy, environmental durability, ingress protection, and communication reliability. Transportation infrastructure operators increasingly specify protection ratings such as IP66 or IP67 for long-term roadside deployment.

Reliability has become one of the primary purchasing criteria because infrastructure operators seek operational lifetimes extending beyond 8–12 years with minimal servicing intervention. Mechanical cup anemometers continue losing share in critical roadway applications because moving components are vulnerable to freezing, dust accumulation, vibration wear, and calibration drift.

Ultrasonic technology continues gaining acceptance because it eliminates rotating mechanical assemblies while supporting remote diagnostics and predictive maintenance integration. Heated sensor variants are particularly important in Nordic countries, Canada, Alpine transport corridors, and high-altitude highway systems where icing conditions can compromise measurement integrity.

Roadside deployments also require compatibility with intelligent transportation communication systems including RS-485, Modbus, SDI-12, and increasingly IP-based connectivity architectures. Transportation authorities are emphasizing interoperability requirements because wind sensors are now integrated into centralized traffic command systems alongside cameras, pavement sensors, visibility detectors, and automated warning infrastructure.

Manufacturing Economics and Cost Pressures Influence Procurement Strategies

Manufacturing economics within the Smart Roads Anemometers Market remain closely tied to industrial electronics pricing, semiconductor availability, and infrastructure procurement cycles rather than commodity raw-material volatility alone. Sensor-grade semiconductors, ultrasonic transducers, industrial communication modules, and ruggedized PCB assemblies account for a major share of system costs.

Between 2024 and 2025, industrial electronics pricing stabilized compared with earlier supply-chain disruptions, but transportation infrastructure projects continued facing budget pressure because of rising installation and labor costs. This strengthened demand for maintenance-free sensing systems with lower lifecycle servicing requirements.

Manufacturers capable of integrating diagnostics, wireless communication capability, and multi-parameter sensing within a single roadside unit are gaining procurement advantages because transportation agencies increasingly seek to reduce installation density and maintenance complexity. Compact integrated weather stations are therefore competing directly against standalone anemometer deployments in urban smart-road projects.

Cost pressure is also increasing competition between European premium suppliers and Chinese manufacturers. While European and Japanese companies continue dominating high-accuracy and safety-critical applications, Chinese suppliers are rapidly expanding presence in large-scale deployments where procurement decisions are more price-sensitive.

Recent Industry Developments and Market Activity

• During 2025, several European transport infrastructure modernization programs accelerated procurement of integrated roadside weather sensing systems for bridge and expressway safety applications, benefiting manufacturers specializing in ultrasonic transportation-grade sensors.
• Gill Instruments expanded its environmental sensing portfolio in 2025 through additional transportation and smart-city focused monitoring solutions designed for infrastructure resilience applications.
• China continued large-scale smart expressway deployment programs during 2024–2026, increasing demand for compact roadway environmental sensing hardware integrated with intelligent traffic systems.
• North American transportation agencies increased investment in weather-responsive traffic systems during 2025 following repeated climate-related freight disruptions affecting interstate highway operations.
• Scandinavian countries continued deployment of advanced bridge wind monitoring systems during 2024 and 2025 to improve traffic safety across coastal transport infrastructure exposed to high crosswind conditions.
• Middle Eastern smart mobility projects, particularly in Saudi Arabia and the UAE, expanded procurement of intelligent roadside environmental monitoring systems linked to connected transport infrastructure and autonomous mobility initiatives.