Automatic Emergency Brake Systems Market, By Vehicle Type (Passenger Cars and Commercial Vehicles), By Technology Type (Forward Collision Warning, Dynamic Brake Support and Crash Imminent Braking), By Sensor Type (Radar, Lidar, Camera), By Company and By Geography, Forecast & Opportunities, 2028

Published Date: April - 2025 | Publisher: MIR | No of Pages: 320 | Industry: Automotive | Format: Report available in PDF / Excel Format

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Forecast Period 2018-2028
Market Size (2022) USD 32 Billion
CAGR (2023-2028) 13.1%
Fastest Growing Segment Radar
Largest Market North America

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Market Overview

Automatic Emergency Brake Systems Market has valued at USD 32 Billion in 2022 and is anticipated to project robust growth in the forecast period with a CAGR of 13.1%.

The global Automatic Emergency Brake System (AEBS) market is experiencing significant growth and transformation in the automotive sector. AEBS is synonymously referred to as Autonomous Emergency Braking (AEB) or Collision Avoidance System. AEBS is a cutting-edge safety feature for reducing or avoiding collisions by automatically braking on sensing a possible collision. This technology provides a solution for the imperative need for road safety improvement, mitigating the intensity of accidents and preventing deaths. Growth for the market is driven mainly by rising road safety concerns and heightened instances of accidents brought about by human factors. AEBS provides a solution that is proactive as it utilizes sensors, cameras, radar, and in some cases even lidar systems to keep track of the vehicle's environment continuously. When the system detects an imminent collision with another car, pedestrian, or obstacle, it initiates an automatic braking reaction, which greatly minimizes the chances of collision impact. Strict government regulations and safety requirements have also been instrumental in the widespread adoption of AEBS. Most regions have seen the potential of this technology to minimize road accidents and have made it a requirement for inclusion in vehicles. These regulations prompt automobile manufacturers to include AEBS in their vehicles, particularly with regard to passenger security and injury protection. The growing public awareness of advanced driver assistance systems (ADAS) and their safety advantages has caused the demand for AEBS-equipped vehicles to rise. With more consumers now considering safety features in vehicle-buying decisions, automakers find themselves compelled to provide AEBS as a base or optional offering across a wide variety of vehicle models and classes.

Key Market Drivers

Road Safety Improvement
The key propellant of the AEBS market is the imperative to improve road safety and mitigate the severity of accidents. AEBS systems independently sense impending collisions and apply emergency brakes, substantially avoiding the impact or even preventing accidents. Since road accidents remain a worldwide issue, AEBS provides a viable solution to mitigate the risks stemming from human errors, distractions, and unforeseen road scenarios.

Regulatory Mandates and Standards
Government regulatory agencies across different parts of the world are making it mandatory for vehicles to embrace sophisticated safety technologies such as AEBS. These mandates are driven by the hope to save lives as well as mitigate the economic and social impacts of accidents. Through such regulations, authorities are forcing auto manufacturers to include AEBS technology in their cars, thus forcing its mass adoption.

Technological Advancements
The evolution of sensor technology, machine learning, artificial intelligence, and data processing capabilities has equipped AEBS systems with more complex and accurate functionalities. Contemporary AEBS systems implement a mix of radar, cameras, lidar, and other sensors to sense the surroundings of the vehicle and identify possible collision threats. Advances in these technologies make it possible for AEBS to identify pedestrians, cyclists, other vehicles, and road obstructions and offer early warnings as well as execute braking actions.

Consumer Demand for Safety Features
Consumer tastes are moving towards cars with sophisticated safety features that increase overall driving security. As awareness and knowledge of AEBS and its advantages expand, an increasing number of consumers are looking for cars that come with this technology installed. Automotive manufacturers are therefore compelled to incorporate AEBS as a marketing option, particularly in the premium and safety-focused car ranges.

Decreased Insurance Costs and Incentives
Insurance providers are realizing the prospects of AEBS in reducing the risk and severity of accidents. Consequently, several insurance providers reward reduced premiums or incentives to those vehicles that come with AEBS. This also helps motivate buyers to purchase cars with advanced safety features, supporting the general popularity of AEBS systems.

Toward Autonomous Driving
AEBS systems are a steppingstone to higher levels of autonomous driving. The use of AEBS technology is a foundation of autonomous vehicles by enhancing sensor technology, vehicle-to-vehicle communication, and decision-making algorithms. Automakers identify AEBS as a key component of the roadmap towards more autonomous and safer transportation

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Key Market Challenges

Technical Complexity and Reliability

AEBS systems rely on a complex interplay of sensors, cameras, radar, lidar, and sophisticated algorithms to accurately detect potential collisions and initiate emergency braking. Ensuring the reliability of these components under various weather conditions, road surfaces, and driving scenarios is a significant challenge. Robust design, thorough testing, and real-world validation are essential to ensure consistent and dependable system performance.

Pedestrian and Cyclist Detection

Accurately detecting and responding to pedestrians, cyclists, and other vulnerable road users presents a technical challenge. These entities often exhibit unpredictable movements and distinguishing them from the vehicle's surroundings can be intricate. AEBS systems must have the capability to recognize and respond to these diverse road users to effectively prevent collisions.

False Positives and Driver Acceptance

AEBS systems operate based on complex algorithms that analyze sensor data to determine collision risks. However, false positives—instances where the system detects a potential collision that does not exist—can lead to unnecessary braking actions, potentially frustrating or alarming drivers. Ensuring that false positives are minimized is crucial to gain driver acceptance and prevent driver disengagement from the technology.

Integration with Other Technologies

Modern vehicles incorporate a multitude of sensors, cameras, and other technologies for various functions, from adaptive cruise control to lane-keeping assistance. Integrating AEBS seamlessly with these technologies and ensuring their coordinated response to potential collision scenarios can be challenging. A cohesive and harmonized approach to integration is essential to prevent conflicts and optimize system performance.

Harmonization of Regulatory Standards

Different regions and countries have varying regulations and standards for vehicle safety technologies, including AEBS. Achieving global harmonization of these standards is challenging, leading to complexities for automakers who need to design vehicles that comply with diverse regulatory frameworks. Harmonization would promote consistency and facilitate global AEBS adoption.

Human-Machine Interaction

AEBS systems interact closely with the driver, especially in situations where emergency braking is initiated. Ensuring that the system communicates its actions clearly to the driver, provides timely warnings, and allows the driver to regain control when necessary is a challenge. Clear and intuitive human-machine interaction is vital to prevent confusion or overreliance on technology.

Cost and Affordability

Developing and implementing AEBS systems involves substantial costs related to research, development, sensor technology, software, and integration. While AEBS offers significant safety benefits, managing these costs to ensure affordability for both automakers and consumers is a challenge. Striking a balance between safety enhancements and cost considerations is crucial.

Key Market Trends

Advancements in Sensor Technology

AEBS relies on sensor technology such as radar, cameras, lidar, and ultrasonic sensors to perceive the vehicle's surroundings and detect potential collision risks. The trend of continuous improvement in sensor technology is making AEBS systems more accurate and reliable. Sensors with higher resolution, extended range, and better object recognition capabilities contribute to the system's ability to accurately detect and assess potential collision scenarios.

Integration with Advanced Driver Assistance Systems (ADAS)

AEBS is often integrated with other ADAS features such as adaptive cruise control, lane departure warning, and pedestrian detection. This integration creates comprehensive safety packages that work together to prevent accidents and enhance overall driving safety. The trend towards offering holistic ADAS packages underscores the industry's commitment to providing a multi-layered safety net for drivers.

Pedestrian and Cyclist Detection Focus

As road safety concerns expand to include vulnerable road users such as pedestrians and cyclists, AEBS systems are evolving to better detect and respond to these entities. The trend involves enhancing algorithms and sensor technologies to accurately recognize and predict the movements of pedestrians and cyclists, especially in complex urban environments.

Machine Learning and AI Integration

Machine learning and artificial intelligence are being increasingly incorporated into AEBS systems to improve their decision-making capabilities. These technologies enable the system to learn from real-world data, adapt to diverse driving scenarios, and make more precise predictions about potential collisions. The trend towards AI integration enhances the system's ability to differentiate between actual threats and false positives.

Partial to Full Autonomous Driving Pathway

AEBS serves as a foundational technology on the pathway towards more advanced levels of autonomous driving. The trend is towards integrating AEBS technology into the broader autonomous driving ecosystem. AEBS systems refine sensor technology, object recognition, and vehicle-to-vehicle communication, contributing to the development of fully autonomous vehicles.

Regulatory Mandates and Standardization

The global trend towards stricter safety regulations and standards is propelling the adoption of AEBS technology. Regulatory bodies are recognizing the potential of AEBS to reduce accidents and injuries, leading to mandates for its inclusion in vehicles. Additionally, efforts to harmonize global safety standards contribute to standardization in AEBS technology across different regions.

Segmental Insights

Market Analysis

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Vehicle Type

Passenger cars are having the higher market share of the global Automatic Emergency Brake System (AEBS) adoption compared to commercial vehicles. This discrepancy can be attributed to several factors that differentiate the two segments. Passenger cars encompass a broader consumer base, including individual drivers, families, and commuters. The emphasis on safety and comfort is often more pronounced in the passenger car segment due to the diverse range of consumers it caters to. As AEBS technology significantly enhances safety by mitigating collision risks, automakers are more inclined to integrate it into passenger cars to meet the safety expectations of consumers. Moreover, passenger cars are typically used for daily commuting and personal transportation, making their safety features more relevant to individual consumers. AEBS, which helps prevent or mitigate accidents caused by human errors, distractions, or sudden obstacles, aligns with the preferences of passengers looking for enhanced safety measures in their vehicles. Commercial vehicles, on the other hand, include a wide range of vehicles such as trucks, buses, and vans used for transporting goods or passengers. While safety remains important in commercial vehicles, the priorities of this segment may lean more towards factors like cargo capacity, fuel efficiency, and overall cost-effectiveness. Additionally, the integration of advanced safety technologies like AEBS might be influenced by different regulations and requirements that apply to commercial vehicles.

Sensor Type Insights

Radar sensors are having the maximum global market share in the Automatic Emergency Braking System (AEBS) segment. This preference can be attributed to several factors that make radar sensors a popular choice for collision detection and avoidance in AEBS technology. Radar sensors excel in their ability to accurately detect objects and obstacles across various weather conditions, including rain, fog, and low light. Their capability to measure the distance, speed, and relative motion of surrounding objects makes them well-suited for collision avoidance applications. Radar sensors emit radio waves that bounce off objects, allowing the system to create a detailed map of the vehicle's surroundings, enabling reliable detection of both moving and stationary objects. Moreover, radar sensors are effective in identifying objects at longer distances compared to other sensor types. This extended range provides AEBS systems with a longer reaction time, enabling them to detect potential collision risks earlier and initiate braking actions in a timely manner. This early detection is crucial for improving safety and minimizing the severity of collisions.

Regional Insights

North America holds the largest share in the global automatic emergency braking system market. The region's dominance can be attributed to the stringent safety norms and regulations implemented by governments, promoting the incorporation of advanced safety features in vehicles. North America has a thriving automobile industry, with a significant presence of major car manufacturers. These manufacturers are increasingly integrating automatic emergency braking systems into their vehicles to enhance safety and meet consumer demand for technologically advanced features. Moreover, consumer awareness regarding vehicle safety is exceptionally high in this region, which further drives the adoption of automatic emergency braking systems. The infrastructure in North America supports the use and testing of advanced vehicle safety technologies, facilitating their more widespread implementation. In conclusion, regulatory policies, automobile industry trends, and high consumer awareness collectively contribute to North America’s leading position in the global automatic emergency braking system market.

Recent Developments

  • In 2023, the Volvo Construction Equipment has launched Collision Mitigation System for Volvo Wheel Loaders which is an automatic braking feature.
  • In 2021, the Volkswagen group has integrated the ZF brake control system in their MED models.

Key Market Players

 By Vehicle

By Sensor

By Technology

By Region

•       Passenger Cars

•       Commercial Vehicles

•       Radar

•       Lidar

•       Camera

•       Forward collision warning

•       Dynamic brake support

•       Crash imminent braking.

•       Asia-Pacific

•       Europe & CIS

•       North America

•       South America

•       Middle East & Africa

Table of Content

Here’s a suggested Table of Contents (TOC) for a report or research paper on the Automatic Emergency Brake (AEB) Systems Market:


Table of Contents

  1. Executive Summary
    1.1. Key Market Highlights
    1.2. Market Outlook and Trends
    1.3. Analyst Insights

  2. Introduction
    2.1. Definition and Overview of AEB Systems
    2.2. Importance in Automotive Safety
    2.3. Scope of the Report
    2.4. Research Methodology

  3. Market Dynamics
    3.1. Market Drivers
    3.2. Market Restraints
    3.3. Opportunities
    3.4. Challenges
    3.5. Regulatory Landscape

  4. Technology Overview
    4.1. Types of AEB Systems (Low-Speed, High-Speed, Pedestrian)
    4.2. Sensor Technologies (Radar, LiDAR, Camera, Ultrasonic)
    4.3. Integration with ADAS and Autonomous Vehicles

  5. Market Segmentation
    5.1. By Vehicle Type
    - Passenger Cars
    - Commercial Vehicles
    5.2. By Component
    - Sensors
    - ECUs
    - Actuators
    5.3. By Sales Channel
    - OEMs
    - Aftermarket
    5.4. By Region
    - North America
    - Europe
    - Asia-Pacific
    - Latin America
    - Middle East & Africa

  6. Competitive Landscape
    6.1. Market Share Analysis
    6.2. Company Profiles
    - Bosch
    - Continental AG
    - ZF Friedrichshafen
    - Denso Corporation
    - Mobileye (Intel)
    - Others
    6.3. Strategic Developments
    - Mergers & Acquisitions
    - Partnerships & Collaborations
    - Product Launches

  7. Market Forecasts and Projections (2025–2030)
    7.1. Global Market Size and Growth
    7.2. Regional Market Forecasts
    7.3. Segment-Wise Forecast

  8. Impact of Emerging Trends
    8.1. Role of AI and Machine Learning
    8.2. Integration with Connected Vehicles
    8.3. Electrification and AEB Adoption

  9. COVID-19 Impact Analysis
    9.1. Supply Chain Disruptions
    9.2. Shift in Consumer Preferences
    9.3. Recovery Outlook

  10. Conclusion and Strategic Recommendations
    10.1. Key Takeaways
    10.2. Strategic Recommendations for Stakeholders
    10.3. Future Outlook

  11. Appendix
    11.1. Glossary of Terms
    11.2. List of Abbreviations
    11.3. References

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