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Variable-message sign

A variable-message sign (VMS), also known as a changeable message sign or dynamic message sign, is an electronic traffic control device used on roadways to display real-time, programmable s informing drivers of incidents, , roadwork, travel times, detours, speed limits, and special events. These signs are typically remotely operated from centers and adhere to standards for legibility, such as minimum 18-inch character height for visibility up to 800 feet at highway speeds. First deployed in the United States in the mid-1950s, with early examples at the by 1957 using scroll and rotating drum mechanisms, VMS have become integral to intelligent transportation systems for enhancing and mobility. VMS employ technologies such as light-emitting diodes (LEDs) for or full-color displays—as increasingly adopted in recent years for better visibility and graphics—fiber optics, or flip-disc mechanisms to convey text, symbols, and graphics, with messages limited to concise formats like 3-4 units (groups of words) to ensure quick comprehension by motorists traveling at 35-70 . They come in permanent installations mounted above or beside highways and portable versions on trailers for temporary use in zones or incidents, both designed to withstand environmental factors like rain, fog, and glare while prioritizing verified, relevant information. Over the decades, advancements in LED efficiency and integration with sensors have expanded their role beyond basic warnings to include dynamic lane assignments, queue detection, and variable speed advisories, as outlined in federal guidelines like the Manual on Uniform Traffic Control Devices (MUTCD). Globally, are deployed on major highways, urban arterials, and tunnels to manage and reduce delays, with operations emphasizing message prioritization—such as major accidents over minor roadwork—and coordination with services for timely updates. In the U.S., departments of like those in and use within broader active strategies to inform route choices and mitigate , supported by research showing improved and outcomes when messages are clear and credible.

Overview

Definition

A variable-message sign (VMS), also referred to as a changeable message sign (CMS) or dynamic message sign (DMS), is an electronic traffic control device capable of displaying one or more alternative messages to inform road users of real-time conditions such as traffic incidents, weather events, or roadway hazards. These signs function by electronically altering the displayed content to deliver timely, context-specific information that enhances driver awareness and decision-making on roadways. Key characteristics of VMS include the ability to remotely update messages via electronic control systems, allowing operators to modify content in response to changing conditions without physical intervention. They are typically mounted on overhead gantries, poles, or portable trailers along roadways to ensure broad visibility for approaching traffic. Designed for outdoor durability, VMS incorporate features such as automatic brightness adjustment to maintain legibility under diverse lighting and weather conditions, including direct sunlight or low-light scenarios. VMS differ from static signs, which feature fixed, unchanging text or symbols that cannot be altered remotely or in real time. Vehicle speed feedback signs, a specific type of CMS that provide interactive, vehicle-specific displays of detected speeds to encourage compliance, differ from general VMS, which focus on broadcasting non-interactive, variable informational content to all users.

Purpose and Benefits

Variable-message signs (VMS) serve as dynamic communication tools in transportation systems, delivering real-time information to drivers about traffic congestion, incidents, variable speed limits, roadwork schedules, and emergency alerts to guide behavioral adjustments such as route changes or speed reductions. By providing timely updates on these conditions, VMS enable motorists to make informed decisions, thereby mitigating risks associated with unexpected disruptions and promoting smoother traffic progression. The primary benefits of VMS include enhanced through proactive warnings that reduce collision risks; for instance, variable speed limits displayed via VMS have been shown to achieve 20-30% reductions in overall crash rates, particularly for rear-end and lane-change incidents, by harmonizing traffic speeds during adverse conditions. These signs also improve by encouraging diversion to alternate routes, with studies indicating 5-20% shifts in traffic volumes during incidents, which helps alleviate bottlenecks and decrease average delays. In incident management, VMS support rapid response by alerting drivers upstream of hazards, leading to observed speed reductions of up to 3 mph in affected areas and fewer secondary accidents. As integral components of Intelligent Transportation Systems (ITS), VMS facilitate real-time data dissemination from sensors and traffic centers, enabling coordinated strategies for congestion control across networks. Their deployment yields substantial economic advantages, such as annual user cost savings exceeding $100 million in major urban reconstructions through delay reductions of up to 36%, demonstrating high benefit-to-cost ratios for congestion mitigation efforts.

History

Early Developments

The earliest precursors to modern variable-message signs (VMS) emerged in the mid-20th century, primarily as systems designed for basic traffic information display. , initial deployments occurred in the , with signs using rotating drums or panels to convey simple messages such as toll rates, parking availability, or entry warnings. For instance, by 1957, the approaches in and employed rotating drum mechanisms on the New Jersey side to display "DO NOT ENTER" alerts and scroll-based three-line messages on the New York side for traffic control. , similar approaches, including solenoid-actuated flip mechanisms for rudimentary variable displays, were experimented with during the , though widespread adoption lagged behind U.S. applications. These systems relied on manual or semi-automated operation, marking the transition from static to dynamic information provision amid growing postwar traffic volumes. The and saw the introduction of electronic signs, shifting from purely designs to electrically controlled displays capable of forming alphanumeric characters. In the U.S., deployed its first in the , using incandescent matrices to show conditions and incident warnings, setting a precedent for urban freeway management. Early experiments with fiber optic technology also began during this period, with initial tests in the exploring light-conducting bundles for brighter, more reliable displays, though full deployments awaited refinements in the early . These innovations addressed limitations of signs, such as slower message changes and weather vulnerability, by enabling and updates via basic . Pioneering efforts in electronic traffic control, including , were advanced by traffic engineers at the (FHWA), which supported research into changeable message technologies through the 1970s. A seminal 1977 FHWA report reviewed operational experiences with early electronic systems, emphasizing their role in freeway . Key patents from this era, such as U.S. 3,509,652 (1970) for an illuminated vehicle adaptable to use and U.S. 4,040,194 (1977) for a magnetic flip-disc changeable message construction, credited inventors like those in firms for foundational designs that influenced FHWA guidelines. These contributions laid the groundwork for integrating into national standards, prioritizing safety and efficiency in early intelligent transportation systems.

Modern Adoption and Expansion

The adoption of variable-message signs (VMS) accelerated in the 1990s and 2000s, driven by legislative mandates in key regions. In the United States, the (ISTEA) of 1991 established the foundation for the (ITS) program, which funded and promoted the deployment of VMS as part of broader efforts to enhance and efficiency. This led to significant growth, with VMS coverage on freeways expanding from 15% of miles in 1999 to 28% by 2004 across 78 large metropolitan areas, resulting in thousands of installations nationwide by the mid-2000s. In , directives such as the 2008/96/EC on road infrastructure safety management included variable message signs as part of intelligent transport systems equipment for , spurring widespread installations; for instance, over 200 VMS were deployed on Paris's ring freeways alone by the early 2000s, contributing to thousands across the continent. From the onward, VMS proliferation surged in the region, particularly in , where deployments supported dynamic road traffic information systems amid rapid . This expansion aligned with initiatives that prioritize connected . In , the 's fastest-growing market, VMS deployments emphasized real-time road connectivity to handle increasing mobility demands. Policy drivers for VMS adoption have centered on addressing escalating urban congestion and major events, with systems enabling dynamic messaging to optimize . During the 2008 Beijing Olympics, were extensively used for real-time traffic guidance, effectively managing event-related congestion and demonstrating their role in large-scale operations. Such implementations have become standard in response to global trends, where VMS help mitigate delays and enhance safety without requiring extensive physical infrastructure changes. As of 2025, ongoing integrations with advanced sensors and continue to expand VMS capabilities in intelligent transportation systems.

Technologies

Display and Hardware Types

Variable message signs (VMS) predominantly employ (LED) matrices as their core display technology, enabling full-color rendering and high brightness levels essential for visibility in diverse outdoor environments. These LED systems consist of pixel arrays that illuminate to form text, symbols, and graphics, with modern implementations favoring full-matrix configurations where the entire sign face comprises individually addressable pixels for maximum flexibility in message design. In contrast, legacy systems utilized fiber optic displays, which routed light through bundles of optical fibers from a central source to individual pixels, and displays (LCDs), which modulated light via liquid crystals sandwiched between polarizing filters, though these have largely been phased out due to limitations in brightness and durability under sunlight exposure. Key hardware components of VMS displays include the pixel pitch, typically ranging from 16 to 25 in LED matrices, which determines and ; for instance, a 20 pitch supports clear viewing from up to 400 under optimal conditions, suitable for applications where drivers approach at speeds requiring rapid comprehension from 200-500 . Enclosures housing these displays are engineered for rugged outdoor deployment, featuring weatherproof ratings of IP65 or higher to safeguard against ingress, jets, and extreme temperatures, often incorporating aluminum or materials with ventilation systems to prevent . Power sources vary by installation type, with fixed roadside VMS drawing from grid and remote or portable units integrating solar panels paired with battery banks to ensure continuous operation in off-grid locations. LED-based VMS offer significant advantages over earlier incandescent or fiber optic variants, consuming up to 70% less power while delivering superior sunlight readability through automatic dimming and high exceeding nits. Full-matrix LED displays provide greater versatility than character-based variants, which limit output to predefined fonts and fixed positions per line, allowing only basic text messages; full-matrix systems, however, support dynamic graphics and multi-line layouts for enhanced information conveyance. This evolution from mechanical flip-disc and early electronic types to LED dominance has improved reliability and in modern deployments.

Control and Communication Systems

Control systems for , also known as , are typically centralized within centers (TMCs) that employ supervisory control and (SCADA)-like software to oversee operations. These systems enable operators to messages based on predefined timelines, durations, and priorities, while allowing manual overrides for urgent situations, such as traffic incidents, to ensure timely dissemination of critical information. The software supports multi-user access with role-based permissions, facilitating coordinated management across networks of signs and arbitrating competing requests on a first-come-first-served basis. Communication protocols ensure between central control systems and field devices, with the National Transportation Communications for ITS Protocol (NTCIP) serving as the primary standard in the United States. NTCIP 1203 specifically defines data elements and object types using the (SNMP) to control and monitor , including message formatting in MULTI syntax for complex text and graphics. Transmission options include hardwired fiber optic connections for reliable, high-bandwidth transfer from sensors, as well as wireless technologies like /LTE or emerging networks to support remote deployments and dynamic updates in areas without fixed infrastructure. Key features of these systems include automated algorithms for message prioritization, where incident-related alerts (e.g., accidents or closures) take precedence over general information like travel times, using predefined priority levels to optimize display sequences. with sources such as cameras, GPS-enabled detectors, and environmental sensors allows for automated content generation, where real-time inputs trigger tailored messages to enhance and safety without constant manual intervention.

Standards and Specifications

International and Regional Standards

Variable-message signs (VMS) are governed by a range of international and regional standards that ensure interoperability, safety, and effective communication in intelligent transportation systems (ITS). The (ISO) standard ISO 14823 establishes a graphic for ITS, providing standardized codes for road traffic signs and pictograms used in messaging, including interfaces for VMS to support efficient encoding and display of traffic information. Complementing this, the (CEN) Technical Committee 226 (CEN/TC 226) develops guidelines on message content for VMS, focusing on road equipment standards that promote consistent and clear information delivery to road users. In the United States, the Federal Highway Administration (FHWA) Manual on Uniform Traffic Control Devices (MUTCD), 11th Edition (effective January 18, 2024), specifies requirements for VMS, specifying yellow or amber backgrounds with black legend for standard displays, though full-color options are permitted for certain messages to enhance visibility and legibility under varying light conditions, along with minimum character sizes such as 18 inches for expressways to ensure readability at highway speeds. Additionally, the National Transportation Communications for ITS Protocol (NTCIP) 1201 standard defines global object definitions for ITS devices, including protocols for monitoring and controlling dynamic message signs (a subset of VMS), enabling seamless integration across transportation management systems. European regulations emphasize performance criteria through EN 12966, which outlines optical and electrical properties for , covering aspects such as luminance, , and power supply requirements for both continuous and discontinuous sign types to withstand environmental stresses and ensure reliable operation. In , the Indian Roads Congress (IRC) Special Publication 85 (IRC:SP:85-2023, first revision) provides guidelines tailored for deployment on highways and urban roads, incorporating adaptations for tropical climates like high and extremes to maintain display durability and message clarity.

Design and Legibility Requirements

Variable-message signs (VMS) must meet stringent standards to ensure drivers can read messages quickly and accurately under varying conditions. According to (FHWA) human factors guidelines, character heights should subtend a minimum of 20 arc minutes for dynamic elements, corresponding to legibility distances of approximately 750 feet for 18-inch characters on highways with speeds of 55 mph or greater. The Manual on Uniform Traffic Control Devices (MUTCD) specifies that VMS must be legible from at least 800 feet during daylight and 600 feet at night, with minimum letter heights of 18 inches for roads at or above 45 mph. contrast ratios are required to be between 8:1 and 12:1, with a preference for positive contrast (luminous characters on a dark background) to enhance ; minimum ratios as low as 3:1 may suffice in low ambient light but are not recommended for highway use. Brightness levels typically range from 500 to 1,000 cd/, adjustable automatically to ambient conditions, ensuring visibility in overcast daylight (up to 1,000 cd/ for older drivers) while dimming to around 30 cd/ at night to prevent glare. Message design prioritizes simplicity and rapid comprehension to minimize driver distraction. The FHWA recommends using the Standard Alphabets series (e.g., Series E Modified) for fonts, with a width-to-height of 0.7 to 1.0 and stroke width-to-height of 1:6 to 1:10, ensuring clear, uppercase lettering without serifs. Messages are limited to a maximum of three lines per , with line spacing at 50-75% of letter height, to fit within typical VMS panel dimensions while allowing drivers 1-2 seconds to process each of . Dwell times per should be at least 2 seconds or 1 second per word (whichever is greater), with full message cycles not exceeding 8 seconds for two- displays; transitions between phases must blank for no more than 0.3 seconds to avoid confusion. These parameters align with NTCIP protocols for consistent implementation across systems. Durability requirements ensure withstand environmental stresses without compromising performance. Under European Standard EN 12966, must resist wind loads up to 1.6 kN/m², equivalent to gusts of 180 km/h (112 mph), while U.S. specifications like those from AASHTO and state DOTs often require resistance to 145 km/h (90 mph) with a 30% gust factor. ranges are typically -40°C to +60°C, with enclosures rated for IP65 or higher to protect against moisture, dust, and thermal cycling. For sunlight readability, anti-glare coatings or protective screens are mandatory, reducing reflections by diffusing ambient light while maintaining high (over 90%) to preserve message clarity in direct sun.

Applications and Usage

Fixed Roadway Installations

Fixed variable-message signs (), also known as dynamic message signs (), are permanently integrated into roadway infrastructure to deliver information on highways and major arterials. These installations typically feature overhead gantry-mounted units spanning multiple lanes for optimal visibility, or roadside pole-mounted configurations for targeted coverage in areas with fewer lanes or space constraints. According to (FHWA) guidelines, permanent are positioned 20 to 25 feet above the roadway surface, with display panels capable of showing three lines of up to 20 characters each to accommodate essential messaging under varying light conditions. Operationally, fixed VMS provide continuous updates on critical roadway conditions, including variable speed limits to adapt to or , dynamic toll pricing on managed lanes, and alerts for , incidents, or lane closures. On the US Interstate system, these signs support traveler guidance by displaying messages such as expected travel times or recommendations, managed centrally from centers to optimize flow during peak periods or disruptions. FHWA documentation emphasizes their role in addressing non-recurrent events like crashes and roadwork, as well as environmental hazards such as or snow, ensuring messages are limited to 3-5 units of information based on prevailing speeds for driver comprehension. Maintenance practices for fixed VMS focus on reliability through remote diagnostics, which allow central monitoring of sign controllers for faults and performance issues, alongside scheduled on-site cleaning to prevent dust or debris from reducing legibility. FHWA recommends routine field inspections and to achieve at least 90% uptime for devices, including VMS, thereby minimizing downtime and preserving operational effectiveness across deployments.

Portable and Temporary Deployments

Portable variable message signs (VMS), also known as portable changeable message signs (PCMS), are typically trailer-mounted or truck-based units designed for rapid deployment in non-permanent settings. These systems often rely on solar panels combined with battery backups to ensure operation in remote or off-grid locations, allowing setup in as little as a few hours for work zones or incident sites. For instance, models like the Ver-Mac PCMS-320 feature a trailer-mounted with , providing a 64 x 105 inch suitable for urban and temporary applications. In construction zones, portable VMS are widely used to warn of lane closures, speed reductions, and detours, adhering to standards such as the U.S. Manual on Uniform Traffic Control Devices (MUTCD), which specifies their role in temporary traffic control for roadway, lane, or ramp closures. The (FHWA) guidelines emphasize their deployment to inform motorists of unusual conditions, with components including a message display, , power source, and mounting equipment on trailers or vehicles. For events like sports stadium gatherings, these signs manage traffic flow by directing drivers to parking areas, designating ride-share zones, and notifying of road closures, as implemented by systems from All Traffic Solutions to prevent backups and enhance guest experience. Globally, portable support disaster efforts, such as during floods or hurricanes, by displaying real-time warnings and evacuation guidance to protect public safety. Manufacturers like PhotonPlay offer battery-backed units with up to six days of autonomy and weather-resistant designs (IP65 rating) for such emergencies, enabling quick information dissemination in affected areas. Their advantages include high flexibility for non-fixed sites, allowing repositioning as conditions change, and integration of GPS tracking for optimal placement and real-time monitoring, as seen in OPTRAFFIC systems that support group management of multiple devices. This mobility contrasts with fixed installations by enabling swift adaptation to temporary needs without permanent infrastructure.

Regional Variations

North America

In the United States, variable message signs (VMS), commonly referred to as changeable message signs (CMS), dominate regional deployment, with oversight provided by the (FHWA) through national policies and coordination with state departments of transportation (DOTs). The FHWA's Manual on Uniform Traffic Control Devices (MUTCD) sets standards for their use, emphasizing traffic operational and guidance information without advertising. California exemplifies this leadership, with operating over 800 permanent CMS as of 2015 to deliver real-time alerts on incidents, congestion, and events, integrated into statewide traffic management systems. A 2015 national survey of state DOTs and toll agencies reported approximately 3,800 CMS in operation as of that year; the number has grown with infrastructure investments such as the Bipartisan Infrastructure Law, though no comprehensive national total is available as of 2025 due to decentralized state management. In , VMS implementations vary by province but emphasize bilingual capabilities in regions like to serve English- and French-speaking drivers. 's Ministry of Transportation has upgraded its VMS since 2009 to full-color electronic displays with pictogram support for clearer multilingual messaging on conditions and hazards. Mexico's usage focuses on its extensive network, which expanded significantly after the 1994 () to facilitate cross-border commerce and improve safety. Deployments include (ITS) integrations on major routes, such as the six VMS installed in 2025 along the Palmillas-Apaseo Highway for real-time traffic and weather advisories. North American VMS uniquely support emergency public safety efforts, including the nationwide system, where FHWA policy permits to display details to aid rapid response. In hurricane-prone areas, they provide critical evacuation guidance, such as contraflow directions and shelter locations, as outlined in federal evacuation planning resources. The MUTCD's 11th Edition, published in 2023 with compliance updates through 2025, enhances LED uniformity for by mandating white digits, standardized backgrounds, and consistent sizing to improve legibility across deployments.

Europe and Asia-Pacific

In Europe, variable-message signs (VMS) are governed by the EN 12966 standard, which establishes uniform requirements for product performance, including visibility, durability, and power efficiency, ensuring compliance across the for all public road deployments. This harmonized framework facilitates interoperability and safety on the (TEN-T). In the , extensively deploys VMS on smart motorways to deliver dynamic speed limits, incident warnings, and congestion updates, enhancing traffic flow on major routes like the M25 and M6. Multilingual support is incorporated in border regions through the use of standardized pictograms, which convey information like hazards or lane closures without relying on text, promoting comprehension for cross-border drivers in areas such as the along France-Germany or Belgium-Netherlands frontiers. In the region, VMS deployment emphasizes scalability to address urban density, with leading through widespread installation in smart cities. , for instance, integrates VMS into its advanced systems to provide real-time advisories on and diversions, drawing from empirical studies showing driver response rates exceeding 70% to variable messaging. These often link with broader networks, including traffic cameras, to monitor and manage violations or hazards in high- zones. In , a 2025 trial in is testing solar-powered VMS for autonomous operation on remote highways, enabling adaptive signage for weather, wildlife, or road conditions in areas with limited grid access. Key regional differences highlight Europe's emphasis on environmental integration, with VMS designs prioritizing low-power LED displays to minimize and in line with sustainability directives. In contrast, focuses on massive scale in megacities, where China's expansion to 19 such urban centers by 2025 drives proliferation to manage populations over 10 million, supporting intelligent transportation in hubs like and .

Effectiveness and Research

Safety and Behavioral Impacts

Variable message signs (VMS) significantly influence behavior by encouraging speed adjustments in response to warnings, such as alerts or notifications. Studies on dynamic speed signs, a type of VMS, demonstrate reductions in mean speeds of about 4 for passenger vehicles and 2-4 mph across all vehicle types in work zones and urban areas. Additionally, VMS with concise messaging minimize by facilitating rapid information processing, as overly complex displays can increase glance times and impair ; research recommends brief, easy-to-recognize formats to enhance road network efficiency without diverting attention from driving tasks. In terms of safety metrics, play a key role in preventing secondary crashes by alerting drivers to incidents ahead, allowing them to slow down and avoid queues. analyses indicate that changeable message signs can achieve up to a 10% reduction in injury crashes through improved speed management and harmonization. In work zones, the 11th Edition of the Manual on Uniform Traffic Control Devices (effective January 18, 2024) underscores the importance of portable changeable message signs for enhancing worker and road user safety, recommending their use to provide advance warnings of lane closures, hazards, and delays in temporary traffic control areas. Despite these benefits, effectiveness can be limited by message overload, where frequent or excessive displays lead drivers to ignore subsequent information. Field experiments and literature reviews identify as a critical , resulting from too many phases or irrelevant messages that cause overload and diminish perceived reliability, particularly at high approach speeds or short reading distances.

Operational and Economic Studies

Operational studies on (VMS) have demonstrated their role in enhancing traffic throughput, particularly in congested urban . Field trials across nine European cities, conducted as part of EU-sponsored projects, showed that VMS providing dynamic time information and route guidance induced driver diversions, resulting in improved network times and modest reductions in overall . Similarly, analyses of VMS deployments in the indicate that real-time messaging can increase traffic diversion rates by 5-20% during incidents, thereby boosting throughput in affected corridors by optimizing route choices and reducing bottlenecks. Reliability metrics for VMS systems in US deployments, leveraging modern LED , typically achieve uptime rates exceeding 99%, ensuring consistent information delivery even in adverse weather conditions. Economic evaluations highlight substantial returns from VMS investments through reduced delays and operational efficiencies. Benefit-to-cost ratios for dynamic message signs on US freeways have ranged from 1.38:1 to 16.95:1, primarily driven by fewer crashes and shorter travel times, equating to savings of $1.38 to $16.95 per dollar invested. A assessment of intelligent transportation systems, including VMS-based traveler information, identifies these as high-ROI interventions in developing countries, with benefits accruing from immediate congestion relief and long-term network optimization. The global VMS market is projected to grow from USD 2.54 billion in 2025 to USD 4.5 billion by 2035, reflecting increasing adoption for amid rising . Despite these advantages, VMS implementations face challenges related to upfront and ongoing costs. Installation costs for fixed VMS units typically range from $50,000 to $200,000 per sign, encompassing hardware, mounting, and integration with centers, as seen in state DOT projects for dynamic warning systems. Maintenance in remote or harsh environments adds further expense, with issues like degradation in portable units and failures potentially reducing system availability if not addressed through regular servicing. These factors underscore the need for strategic deployment to maximize economic viability.

Future Developments

Emerging Technologies

Recent advancements in variable-message sign (VMS) technology are incorporating (AI) for dynamic content generation, particularly through (ML) algorithms that forecast and generate predictive messages in . These systems analyze data from sensors, cameras, and historical patterns to anticipate delays, accidents, or weather impacts, allowing VMS to display tailored warnings or rerouting advice before issues escalate, thereby improving and driver response times. For instance, AI-powered platforms can optimize signal timing and update VMS messages autonomously, helping to reduce congestion in urban settings based on . Complementing these software innovations, hardware developments include organic light-emitting diode () displays, which enable thinner and lighter signs with improved display quality for urban deployment. Sustainability efforts in are advancing through solar-integrated units that eliminate reliance on grid power for remote or off-grid locations, significantly lowering operational costs and environmental impact by harnessing for continuous operation. These systems, often combined with battery storage, provide high reliability with backup for several days of operation in areas without electrical , reducing carbon emissions associated with traditional power sources and supporting goals in transportation networks. Additionally, integration allows for localized data processing at the VMS level, minimizing latency in message updates and usage by handling on-site rather than relying on central servers, which enhances responsiveness during peak traffic events. As of 2025, notable pilots have demonstrated -enabled within vehicle-to-everything () frameworks, facilitating direct communication between signs, vehicles, and infrastructure for enhanced safety and efficiency. In , trials such as the NTU Smart Campus testbed have integrated for safety applications like , paving the way for broader adoption. These developments underscore evolution toward interconnected, proactive systems amid global rollout.

Integration with Intelligent Transportation Systems

Variable-message signs (VMS) play a pivotal role in Intelligent Transportation Systems (ITS) by facilitating real-time data exchange with traffic sensors, such as and inductive loops, to detect incidents like crashes or and automatically update signage for traffic diversion and alerts. This integration enables VMS to receive inputs from vehicle detection systems, processing sensor data to display dynamic messages that inform drivers of hazards, travel times, or route changes, thereby enhancing overall . Additionally, VMS connect with Advanced Driver Assistance Systems (ADAS) through Vehicle-to-Infrastructure (V2I) communication protocols, broadcasting safety warnings—such as wrong-way driving detections or work zone notifications—to equipped , which can then trigger automated responses like speed adjustments. Cloud platforms further unify these elements by aggregating sensor and ADAS data via AI-driven analytics, allowing VMS to issue coordinated alerts across networks for predictive incident and reduced response times. In future Cooperative ITS (C-ITS) scenarios, are envisioned to synchronize seamlessly with vehicle apps and onboard systems, enabling bidirectional data flow for enhanced ; for instance, the C-ROADS project tests such across borders, where relay status to vehicles while receiving real-time feedback from connected apps to optimize message relevance. This framework supports broader connected mobility, with projections indicating full compatibility with autonomous vehicles by 2030 through standardized digital interfaces that address current challenges like LED readability for in . As of 2025, integration with emerging standards continues to evolve, including considerations for cybersecurity and ethics in message generation. Addressing integration challenges, cybersecurity protocols like ISO/SAE 21434 are essential for securing V2I exchanges in VMS-ITS ecosystems, providing a lifecycle framework for risk assessment and threat mitigation to prevent unauthorized access or message tampering. These measures, extended from vehicle to infrastructure applications, ensure resilient data flows amid growing connectivity. Ultimately, such advancements position VMS as key contributors to zero-fatality road goals under initiatives, where real-time alerts from integrated ITS reduce speed-related incidents and severe crashes by informing behavioral adjustments.

References

  1. [1]
    Variable message signs - TSMO | WSDOT
    Variable message signs (VMS) are electronic roadside signs used to post traveler information messages to inform drivers of incidents, travel times, detours, ...
  2. [2]
    [PDF] Variable Message Sign Operations Manual - NJ.gov
    This Variable Message Sign Operations Manual was written for use by New Jersey Department of Transportation. (NJDOT) personnel who have responsibility for ...<|control11|><|separator|>
  3. [3]
    Changeable Message Signs for Highway Construction Areas
    Apr 11, 2022 · The introduction and use of changeable message signs on highways in the United States can be traced to the mid-1950s. By 1957, such signs were ...
  4. [4]
    Portable Changeable Message Sign Handbook - Pcms
    May 18, 2020 · A PCMS is a traffic control device that is capable of displaying a variety of messages to inform motorists of unusual driving conditions.
  5. [5]
    2009 Edition Chapter 2L. Changeable Message Signs - MUTCD
    A changeable message sign (CMS) is a traffic control device that is capable of displaying one or more alternative messages.Missing: definition | Show results with:definition
  6. [6]
    https://mutcd.fhwa.dot.gov/pdfs/11th_Edition/part2l.pdf
  7. [7]
    [PDF] MUTCD 11th Edition - 2023
    Dec 1, 2023 · ... Speed Feedback Sign and Plaque (W13-20 and W13-20aP) ... Changeable Message Sign—a sign that is capable of displaying more than one ...Missing: distinction | Show results with:distinction
  8. [8]
    ATMS Information Variable Message Signs (VMS)
    BENEFITS: · Travelers can be warned of scheduled closures for road work, maintenance activities and encouraged to take alternative routes · Alerts drivers to ...
  9. [9]
    [PDF] Evaluation of Dynamic Message Signs and Their Potential Impact on ...
    Knowledge of rapidly changing traffic conditions gives drivers the option to modify their behavior in order to avoid delays and dangerous situations. Highway ...
  10. [10]
    Synthesis of Variable Speed Limit Signs - FHWA Operations
    Apr 22, 2020 · The VSL system along US 27, a two-lane, divided, rural roadway in Florida, was installed to control high vehicular speeds surrounding a school zone.
  11. [11]
    [PDF] MITIGATING TRAFFIC CONGESTION - FHWA Office of Operations
    Demand-side strategies, like managing travel demand and using real-time information, are critical for mitigating traffic congestion.
  12. [12]
    Mixed Signals | Roads.org.uk
    Feb 2, 2015 · During the 1960s the UK developed some of the most sophisticated - and strange - electronic variable message signs anywhere in the world.Missing: pre- | Show results with:pre-
  13. [13]
    (PDF) Effectiveness of Variable Message Signs - ResearchGate
    Aug 7, 2025 · The effectiveness of Variable Messages Signs (VMS) on route guidance is assessed by a discrete probit choice model that estimates the proportion of vehicles ...Missing: collisions | Show results with:collisions
  14. [14]
    Dynamic Message Signs: Differences between Europe and North ...
    In the early 80's, the first versions of Dynamic Message Signs (DMS) used fiber optic technology which has since been improved and upgraded to incorporate ...Missing: mechanical pre- 1960s
  15. [15]
    [PDF] MESSAGE SIGN TECHNOLOGY - ROSA P
    Changeable Message Signs (CMSs) have been used on urban highways for more than. 20 years. A 1977 FHWA/RD-77/98 state-of-the-art reportl extensively examined.
  16. [16]
    US3509652A - Vehicle traffic sign - Google Patents
    A further object of the invention is to provide a vehicle traflic sign which is designed for ease and economy of manufacture. A still further object of the ...<|separator|>
  17. [17]
    Changeable message sign construction - Justia Patents
    Jul 28, 1976 · This invention relates to a changeable message sign construction and more particularly, to such a sign construction making use of a magnet or ...
  18. [18]
    [PDF] Tracking the Deployment of the Integrated Metropolitan Intelligent ...
    Jul 6, 2005 · Traveler information systems are also projected to increase through 2005, with the rate of growth for variable message signs exceeding that for ...
  19. [19]
    [PDF] B DIRECTIVE 2008/96/EC OF THE EUROPEAN PARLIAMENT AND ...
    Dec 16, 2019 · DIRECTIVE 2008/96/EC OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL ... (f) appropriate information in ITS equipment (e.g. variable message signs);.
  20. [20]
    [PDF] Innovative Traffic Control - Technology and Practice in Europe
    Variable message signs have been installed at 204 locations on the Paris ring freeway, its ramps, and the inner city ring freeway. Figure 99 illustrates one ...
  21. [21]
    China Railway High-speed Beijing South Station Signage System
    China High-Speed Railway Signage System Design was put into use in 2009, it had guided millions of people to get to their destinations effectively and ...Signage Distribution &... · Signage Appearance & Form · Graphic Design
  22. [22]
    LED Variable Message Signs Soars to 781 million , witnessing a ...
    Rating 4.8 (1,980) Jun 27, 2025 · The global LED Variable Message Sign (VMS) market is experiencing robust growth, projected to reach a value of $781 million in 2025, ...Missing: 2010s 2020s
  23. [23]
    Asia Pacific Variable Message Traffic Signs Market Size 2026
    Sep 15, 2025 · The Asia Pacific Variable Message Traffic Signs (VMTS) market is witnessing significant growth, driven by several key global trends.
  24. [24]
    EVERYTHING YOU NEED TO KNOW ABOUT VARIABLE MESSAGE ...
    Variable Message Sign (VMS) · Variable Speed Limit Sign (VSLS) · Portable ... As such, VMS is a critical component of effective traffic management, enabling ...Missing: definition | Show results with:definition
  25. [25]
    VMS Release of Traffic Guide Information in Beijing Olympics
    The paper mainly discussed VMS traffic information release based on traffic flow real-time detecting. It introduced the logical structure of the Olympic traffic ...Missing: event messaging
  26. [26]
    United States Variable Message Signs for Intelligent Transportation ...
    Oct 31, 2025 · Urbanization and Traffic Congestion: Rapid urban growth in major metropolitan areas increases demand for real-time information dissemination to ...
  27. [27]
    [PDF] Use of Color Changeable Message Signs - FHWA Operations
    Two overarching objectives of the Use of Color Changeable Message Signs (CMSs) – Current. Practice and Research project are (1) to understand how agencies are ...Missing: history | Show results with:history
  28. [28]
    https://www.photonplayinc.com/blog/variable-message-signs-an-ultimate-innovation-to-get-a-control-over-the-traffic
  29. [29]
    The Technology Behind the Portable Variable Message Sign
    Sep 24, 2024 · PVMS display real-time messages about road closures, detours, speed limits, and upcoming hazards. These signs enhance road safety and regulate traffic flow.Missing: fiber optic legacy<|separator|>
  30. [30]
    [PDF] Report on VMS readability - DiVA portal
    The use of more pixels to form the strokes of characters lead to better ratings of the readability at short to medium distances, but not at distances close to ...
  31. [31]
    [PDF] product overview - vanguard® vs-5360 variable speed limit signs
    › Built-in pixel diagnostics monitor LED operation. › Automatic brightness control using integrated light sensor. › 20mm or 16mm pixel pitch available. Static ...Missing: VMS readability
  32. [32]
    IP65 vs. Other IP Ratings: the Difference and Why It Matters - Optraffic
    Aug 15, 2024 · The IP65 rating signifies complete protection against dust. The first digit, “6,” indicates that no dust particles can penetrate the enclosure. ...
  33. [33]
    Portable Solar-Powered VMS Trailer with 5-Color LED Display
    These VMS trailers are equipped with solar panels and a large-capacity battery (7200AH). Even in areas without a power grid, it ensures stable power supply ...
  34. [34]
    Future of Energy-Saving in LED Displays - Absen
    The black screen energy-saving technology for LED displays is a technique that reduces power consumption and achieves energy savings when the screen is in a ...Missing: VMS 70%<|separator|>
  35. [35]
    LED Lighting | Department of Energy
    Residential LEDs -- especially ENERGY STAR rated products -- use at least 75% less energy, and last up to 25 times longer, than incandescent lighting.
  36. [36]
    [PDF] Model Systems Engineering Document for Dynamic Message Signs ...
    CFR. Code of Federal Regulations. CMS Changeable Message Sign - A sign that is capable of displaying one of two or more predefined messages, or a blank message ...
  37. [37]
    [PDF] NTCIP 1203 version v03
    While AASHTO, ITE, and NEMA administer the process and establish rules to promote fairness in the development of consensus, they do not write the document and ...
  38. [38]
    Dynamic Message Sign (DMS) Working Group - NTCIP
    NTCIP 1203 v03 provides definitions of data elements for use with dynamic message signs. The data is defined using the Simple Network Management Protocol ...
  39. [39]
    Fiber Optics – The Golden Threads of CDOT Operations
    Mar 1, 2024 · Fiber enables smart roadways​​ One example is the variable speed limit signs on I-70, which automatically adapt to traffic volume, weather ...
  40. [40]
    [PDF] FHWA-HRT-20-064: Detailed Concept of Operations
    Feb 9, 2021 · Long-range communications: long-distance communications, such as 3G, 4G/LTE, 5G, or cellular vehicle-to-everything, which support wide area ...
  41. [41]
    [PDF] Incident Management: Detection, Verification, and Traffic Management
    cameras, Variable Message Signs (VMS), and weather information stations. Thus, Smart Call. Box tested a technology that supports the deployment of incident ...
  42. [42]
    ISO 14823-1:2024 - Intelligent transport systems — Graphic data ...
    In stockThis document specifies a graphic data dictionary (GDD), a system of standardized codes for existing road traffic signs and pictograms used to deliver traffic ...
  43. [43]
    https://standards.iteh.ai/catalog/tc/cen/70120d40-23bf-449e-9b6b-903b7b17d477/cen-tc-226
  44. [44]
    [PDF] NTCIP 1201 version v03
    NTCIP 1201 v03 is a joint standard for National Transportation Communications for ITS Protocol Global Object (GO) Definitions, a major revision of v02.32.
  45. [45]
    https://standards.iteh.ai/catalog/standards/cen/e1ca2f41-d234-450e-b158-f0104ff1ad82/en-12966-2014a1-2018
  46. [46]
    [PDF] IRC SP 085: Guidelines for Variable Message Signs
    This document covers guidelines for design of Variable Message Sign for highways and urban roads. The intent of this document is to implement Intelligent ...Missing: tropical | Show results with:tropical
  47. [47]
    Human Factors Design Guidelines for Advanced Traveler ...
    Considered as a whole, the data from these studies indicate: (1) that symbols should subtend at least 20 arcminutes if they are associated with dynamic or ...
  48. [48]
    [PDF] European Standard for Variable Message Traffic Signs EN12966
    electrical performance,. ▫ resistance against impacts,. ▫ resistance against vibration,. ▫ resistances against corrosion,. ▫ electromagnetic compatibility,. ▫ ...
  49. [49]
    [PDF] item 645.45080025‒ variable message sign – color - nysdot
    The VMS housing, structural framing, face covering, and mounting members shall be designed to withstand a wind velocity of 90 mph with a 30 percent gust factor ...
  50. [50]
    Current VMS Technologies and Applications - Access-Board.gov
    Fiber optic (FO) Matrix FO VMS(also called Light Conductor Technology - Bendekovics and Zelisko, 1996) work by running fiber optic cable from a light source ...
  51. [51]
    [PDF] Changeable Message Sign Operation and Messaging Handbook
    The Changeable Message Sign Operation and Messaging Handbook is written for personnel in state, regional, and local transportation agencies that have ...
  52. [52]
    [PDF] Synthesis of Variable Speed Limit Signs - FHWA Operations
    SYNTHESIS OF VARIABLE SPEED LIMIT SIGNS. HISTORY AND PREVIOUS RESEARCH ... management techniques (e.g. variable message signs (VMS), dynamic shoulder lanes, ramp.
  53. [53]
    [PDF] intelligent transportation systems assets - FHWA Office of Operations
    Jun 24, 2024 · Several examples of the TMS include CCTV cameras, ramp meters, variable message signs, vehicle detectors, traffic signals, and highway advisory ...
  54. [54]
    PCMS-320 - Portable Changeable Message Signs - Ver-Mac
    The PCMS-320 is a medium-sized, trailer-mounted, solar-powered changeable message sign for urban areas, with a 64 x 105 inch display.
  55. [55]
    2009 Edition Chapter 6F. Temporary Traffic Control Zone Devices
    03 Portable changeable message signs have a wide variety of applications in TTC zones including: roadway, lane, or ramp closures; incident management; width ...
  56. [56]
    Sports and Entertainment Venues | All Traffic Solutions
    Portable Variable Message. and Speed Signs for Sports. & Entertainment Venues. Share information, manage traffic flow, and improve. guests' experience with ...
  57. [57]
    Variable Message Signs | PhotonPlayInc
    ### Summary of Variable Message Signs (VMS) for Natural Calamities like Floods and Disaster Response
  58. [58]
    Shop Top-Quality VMS Signs & Portable Traffic Message ... - Optraffic
    200+ predefined traffic control messages; Group message feature to manage multiple devices simultaneously; GPS location and real-time device monitoring; Anti ...Missing: positioning | Show results with:positioning
  59. [59]
    Policy for Messages on Dynamic Message Signs (DMS)
    Jun 26, 2025 · The memorandum notes that dynamic message signs shall display pertinent traffic operational and guidance information only, not advertising.Missing: gantry spacing
  60. [60]
    Manual on Uniform Traffic Control Devices (MUTCD) - FHWA
    The MUTCD defines the standards used by road managers nationwide to install and maintain traffic control devices on all streets, highways, pedestrian and ...State MUTCDs & TCD Info · MUTCD News Feed · 11th Edition · Overview
  61. [61]
    Changeable Message Sign - Caltrans - CA.gov
    A changeable message sign (CMS) is primarily used to give motorists real-time traffic safety and guidance information about planned and unplanned events.Missing: variable | Show results with:variable<|separator|>
  62. [62]
    Placement Design of Changeable Message Signs on Curved ...
    In the California Department of Transportation (Caltrans), there are more than 815 permanent CMS signs as of July 31, 2015. Additional portable CMS signs are ...<|separator|>
  63. [63]
    Appendix B - Summary of Traffic Management Centers and Number ...
    Read chapter Appendix B - Summary of Traffic Management Centers and Number of Changeable Message Signs Operated by State DOTs and Agencies Operating Toll .
  64. [64]
    Ontario's Bilingual Electronic Highway Signs Going Colour
    Jan 20, 2015 · Ontario is introducing bilingual, full-colour electronic highway signs that include images to help keep drivers safe and manage traffic conditions.
  65. [65]
    [PDF] Bilingual Pictogram Messages on Ontario Variable ... - ITS Canada
    Almost 500 Variable Message Signs (VMS) in Ontario. Page 5. Bilingual Signing ... • Bilingual versions of every VMS message in Ontario. • Pictogram ...
  66. [66]
    Mexico highway ITS deployment for Kapsch | ITS International
    Aug 7, 2025 · Twenty-one traffic cameras, six variable message signs, one weather station, two Weigh in Motion (WiM) stations and five traffic counting points ...
  67. [67]
    [PDF] Border-Wide Assessment of Intelligent Transportation System (ITS ...
    Jul 1, 2012 · The Mexican government agency that owns most of the toll roads in Mexico is called Banco ... variable message signs. The system leveraged the ...
  68. [68]
    AMBER Alert - Use of Changeable Message Sign, August 16, 2002
    The purpose of this memorandum is to clarify the FHWA policy on the use of CMS for displaying AMBER Alert child abduction-related messages.
  69. [69]
    Federal, State, and Local Roles in Evacuations
    Variable message signs can be deployed quickly to guide evacuees. Through emergency radio broadcasts, State and local transportation agencies can provide real- ...
  70. [70]
    MUTCD 11th Edition Impacts Speed Display Signs in 2025 - Optraffic
    May 27, 2025 · The MUTCD 11th Edition changes speed signs by categorizing them as CMS, mandating white LED digits, standardized background colors, and size ...
  71. [71]
    [PDF] Manual on Uniform Traffic Control Devices - MUTCD
    Dec 1, 2023 · CHAPTER 1B. LEGAL REQUIREMENTS FOR TRAFFIC CONTROL DEVICES. Section 1B.01. National Standard .
  72. [72]
    BS EN 12966:2014+A1:2018 | 30 Apr 2021 | BSI Knowledge
    Apr 30, 2021 · BS EN 12966 provides specifications for two types of variable message signs (VMS); ie, continuous, and discontinuous.
  73. [73]
    Motorway signs, signals and road markings - GOV.UK
    Dec 5, 2023 · Signals and variable message signs may apply to individual lanes when mounted overhead or, when located on the central reservation or at the ...
  74. [74]
    Comprehension of pictograms for variable message signs
    Aug 6, 2025 · The search is on for pictograms which can be easily understood throughout Europe regardless of the language of the driver.
  75. [75]
    Australian state to trial solar-powered 'smart' highways - CarExpert
    Jan 14, 2025 · Regional highways will gain self-adaptive electronic signage with machine learning capability as part of a $5 million technology trial in New South Wales.
  76. [76]
    Variable Message Signs, Dynamic Message Signs | Telegra
    DMS are electronic LED sign with full matrix or line matrix of pixels, in full color (Red/Green/Blue - RGB) or monochromatic (amber or white). Matrix is a ...
  77. [77]
    China to Lead the World Ranking with 19 Megacities by 2025
    Sep 8, 2022 · Urban Expansion: China to Lead the World Ranking with 19 Megacities by 2025 · Asian megacities overtaking countries in terms of economic size.Missing: VMS scale
  78. [78]
    [PDF] Effectiveness of Dynamic Speed Feedback Signs, Volume I - ROSA P
    DSFSs are effective in reducing mean speeds, with an estimated 4 mph reduction for passenger vehicles and 2-4 mph across all vehicle types.
  79. [79]
    Effects of urban road variable message signs on driving behavior
    Apr 9, 2019 · Drivers who occasionally pay attention to variable message signs prefer to reduce speed to read the information on variable message signs.
  80. [80]
    [PDF] Safe System Approach for Speed Management
    Evidence of overall reductions in speed. 8% reduction in casualty crashes. Changeable Message Signs. 1 mph reduction in mean speed. 10% reduction in injury ...
  81. [81]
    [PDF] Literature review on variable message signs (VMS) 2006–2009
    Drivers' En Route Diversion Decisions Under. Influence of Variable Message Sign Information: Empirical Analysis. Paper presented at the Transportation ...
  82. [82]
    Reliability of variable message signs information: A field experiment ...
    In this study, field tests were conducted to assess the reliability of VMS information in terms of the visual perception characteristics of drivers.
  83. [83]
    Evidence from field trails in European cities: Transport Reviews
    Abstract. Variable message signs (VMS) can provide up‐to‐date traffic information and guidance to drivers through electronic signs at the roadside.
  84. [84]
    [PDF] Quantifying Effectiveness and Impacts of Digital Message Signs on ...
    Mar 31, 2022 · Therefore, this research intended to develop a data driven methodology to assess the effectiveness of different DMS, message types and.
  85. [85]
    VMS - Variable Message Signs - ITS Research - 12 Gate Technology
    Aug 18, 2025 · Portable variable message signs can be deployed rapidly. Truck-mounted units can reposition as traffic patterns shift.Missing: GPS | Show results with:GPS
  86. [86]
    Benefit-to-cost ratios for six dynamic message signs on two freeways ...
    Overall, safety improved after the DMS system was installed at each site; however, researchers concluded that the system was not effective at reducing the ...Missing: variable collisions
  87. [87]
    [PDF] World Bank Document
    Jul 22, 2004 · systems based on variable message signs (VMS). As expected, systems that provide a high rate of return on investment have the greatest ...
  88. [88]
    Variable Message Traffic Signs Market Growth and Analysis 2032
    Sep 20, 2025 · The Variable Message Traffic Signs Market is expected to grow from 2,538.9 USD Million in 2025 to 4,500 USD Million by 2035. The Variable ...Missing: economic | Show results with:economic
  89. [89]
    [PDF] Potential Safety Effects of Dynamic Signing at Rural Horizontal Curves
    If purchased new, the package would cost about $50,000; however, an agency could deploy the components necessary to perform dynamic curve warning (a changeable ...
  90. [90]
    Capital costs to install temporary Variable Speed Limit (VSL ...
    Capital costs to install temporary Variable Speed Limit (VSL) systems in Texas ranged from $91K to $180K. Experience planning, installing, and evaluating pilot ...Missing: per | Show results with:per
  91. [91]
    Common Mechanical Failures in Variable Messaging Signs - Optraffic
    Feb 5, 2025 · Battery degradation reduces the uptime of portable variable message signs. Aging batteries lose their ability to hold a charge, leading to ...
  92. [92]
    Predictive Traffic Management Systems | AI Traffic Control - Econolite
    Leveraging AI-powered predictive and forecasting capabilities, a traffic management system can continually optimize signal timing, update dynamic message signs, ...
  93. [93]
    Solar Powered Variable Message Signs for Remote Locations
    Oct 8, 2025 · You can choose between mobile and fixed units based on your needs. Mobile signs offer flexibility for temporary events or changing work zones.
  94. [94]
    How IoT Technology Empowers Mobile VMS (Variable Message Sign)
    The implementation of IoT-enabled Mobile VMS resulted in a significant reduction in traffic congestion and improved overall traffic flow in Shanghai. Smart ...
  95. [95]
    V2X Development Projects Around the World - AUTOCRYPT
    Jun 20, 2024 · V2X projects include UK's V2G, US's ATTAIN, Singapore's 5G testbed, and China's Tianjin pilot area, aiming to enhance safety and efficiency.Global V2x Development... · United States · Singapore<|separator|>
  96. [96]
    Exploring Traffic Variable Message Signs (VMS) Trends 2025-2033
    Rating 4.8 (1,980) May 29, 2025 · Emerging Trends in Traffic Variable Message Signs (VMS) Market · Increased use of AI and machine learning for real-time traffic management.
  97. [97]
    Intelligent Transportation Systems (ITS) Use Cases for SS4A
    Apr 25, 2025 · The following are examples of intelligent transportation systems (ITS) use cases. These examples are potential operational and/or technology-focused activities.
  98. [98]
    [PDF] Impacts of Automated Vehicles on Highway Infrastructure
    From an ITS standpoint, there are still significant challenges for ADSs in reading light-emitting diode (LED) signs (including variable speed limit and variable ...
  99. [99]
    Automotive cybersecurity: ISO/SAE 21434 - Applied Intuition
    Oct 23, 2025 · ISO/SAE 21434 defines how the OEMs, Tier 1 suppliers, and automotive software providers should engineer cybersecurity across the entire ...
  100. [100]
    Zero Deaths and Safe System | FHWA - Department of Transportation
    Aug 6, 2025 · The zero deaths vision acknowledges that even one death on our transportation system is unacceptable and focuses on safe mobility for all road users.Vision Zero Community of... · Safety Culture · Funding · Resources