Global Automotive Angular Positions Sensors Market Growth, Share, Size, Trends and Forecast (2025 - 2031)

The global market for position sensors is segmented by type into linear type, rotary position sensors, and other sensors, each serving distinct functions and applications across various industries. Linear type position sensors provide accurate measurement of linear displacement or position along a straight path. These sensors are commonly used in applications such as machine tools, robotics, and motion systems, where precise positioning is essential for optimal performance. Rotary position sensors, on the other hand, measure rotational displacement or position around a fixed axis. These sensors are widely employed in applications such as automotive throttle position sensing, steering angle measurement, and industrial automation, where rotational motion needs to be monitored and controlled. Additionally, the category of other sensors includes specialized position sensing technologies such as tilt sensors, magnetic position sensors, and optical encoders, which cater to specific industry requirements and niche applications.

Moving on to applications, position sensors find diverse usage across industries such as machine tools, robotics, motion systems, material handling, test equipment, and others. In machine tools, position sensors play a critical role in precision machining operations, providing accurate feedback on tool position and movement to ensure optimal cutting performance and dimensional accuracy. In robotics, position sensors enable precise control of robotic arms and end-effectors, facilitating tasks such as pick-and-place operations, assembly, and welding. Motion systems rely on position sensors for motion control and feedback in applications ranging from industrial automation to aerospace guidance systems. Material handling equipment such as conveyors, cranes, and forklifts utilize position sensors for load positioning, collision avoidance, and inventory management. Test equipment, including dynamometers, coordinate measuring machines (CMMs), and testing rigs, employ position sensors for accurate measurement and control of test parameters.

The end-user segmentation of the position sensor market encompasses a wide range of industries, including manufacturing, automotive, aerospace, packaging, healthcare, electronics, and others. In manufacturing, position sensors are integral to process automation, quality control, and production efficiency improvement initiatives. The automotive industry utilizes position sensors in various applications such as throttle position sensing, pedal position sensing, and gearbox position sensing, contributing to vehicle performance, safety, and efficiency. Aerospace applications of position sensors include aircraft flight control systems, landing gear position sensing, and engine thrust vectoring, where precise positioning is crucial for flight safety and performance. Packaging machinery relies on position sensors for accurate filling, sealing, labeling, and packaging operations, ensuring product quality and production throughput. In healthcare, position sensors are used in medical devices such as infusion pumps, robotic surgery systems, and patient monitoring equipment, supporting diagnosis, treatment, and patient care. The electronics industry employs position sensors in semiconductor manufacturing equipment, robotics, and automation systems, enhancing production precision and efficiency.

Global Automotive Angular Positions Sensors Segment Analysis

In this report, the Global Automotive Angular Positions Sensors Market has been segmented by Type, Application, End-User and Geography.

Global Automotive Angular Positions Sensors Market, Segmentation by Type

The Global Automotive Angular Positions Sensors Market has been segmented by Type into Linear Type, Rotary Position Sensors and Other Sensors.

Linear type position sensors are essential components within automotive systems, providing accurate measurement of linear displacement or position along a straight path. These sensors are commonly utilized in applications such as throttle position sensing, pedal position sensing, and seat position adjustment, where precise linear movement tracking is crucial for vehicle performance and safety. Linear type sensors offer reliable feedback on the linear motion of various vehicle components, contributing to the efficient operation of automotive systems and enhancing the overall driving experience.

Rotary position sensors, another significant segment of the automotive angular position sensors market, play a vital role in measuring rotational displacement or position around a fixed axis within vehicles. These sensors are widely deployed in applications such as steering angle measurement, throttle valve position sensing, and transmission gear position detection. Rotary position sensors provide accurate feedback on rotational movement, enabling precise control of vehicle systems such as electronic power steering (EPS), throttle control, and transmission shifting. By monitoring rotational positions, these sensors facilitate smooth operation, optimal performance, and enhanced safety in automotive applications.

The category of other sensors encompasses specialized position sensing technologies that cater to specific automotive requirements and niche applications. These sensors include tilt sensors, magnetic position sensors, and optical encoders, among others, each offering unique capabilities and advantages in measuring angular positions within vehicles. Tilt sensors, for instance, detect changes in inclination or orientation and are used in applications such as vehicle stability control and rollover prevention systems. Magnetic position sensors utilize magnetic fields to determine angular positions and are commonly employed in automotive steering systems and electronic throttle control systems. Optical encoders provide high-resolution position feedback using light-based detection methods and find applications in precision automotive systems such as adaptive headlights and robotic assembly lines.

Global Automotive Angular Positions Sensors Market, Segmentation by Application

The Global Automotive Angular Positions Sensors Market has been segmented by Application into Machine Tools, Robotics, Motion Systems, Material Handling, Test Equipment and Others.

One significant application of automotive angular position sensors is in the realm of powertrain systems. Within powertrain applications, these sensors are utilized for tasks such as throttle position sensing, crankshaft position sensing, and camshaft position sensing. By accurately measuring the angular position of engine components, angular position sensors enable precise control of fuel injection timing, ignition timing, and valve timing, contributing to engine efficiency, performance, and emissions control.

Another key application area for automotive angular position sensors is in vehicle chassis and suspension systems. Within chassis and suspension applications, these sensors play critical roles in tasks such as steering angle measurement, wheel alignment sensing, and suspension height sensing. By providing accurate feedback on the angular positions of steering components, wheels, and suspension elements, angular position sensors enable dynamic stability control, adaptive steering systems, and active suspension systems, enhancing vehicle handling, ride comfort, and safety.

Automotive angular position sensors find extensive usage in advanced driver assistance systems (ADAS). Within ADAS applications, these sensors are employed for functionalities such as lane departure warning, adaptive cruise control, and automatic emergency braking. By accurately measuring the angular positions of vehicle components and surrounding objects, angular position sensors enable intelligent decision-making algorithms to detect and respond to potential hazards, contributing to enhanced driver safety and accident prevention.

Aautomotive angular position sensors are integral components in vehicle body and interior systems. Within body and interior applications, these sensors are utilized for tasks such as seat position sensing, mirror position sensing, and convertible top position sensing. By providing accurate feedback on the angular positions of vehicle interior components, angular position sensors enable automated adjustments, memory settings, and convenience features, enhancing driver comfort and convenience.

The segmentation of the global automotive angular position sensors market by application underscores the diverse range of automotive systems and functionalities that rely on angular position sensing technology. From powertrain systems to chassis and suspension systems, ADAS, and vehicle body and interior systems, angular position sensors play critical roles in enabling precise measurement, control, and automation, contributing to vehicle performance, safety, and user experience. As automotive technology continues to advance, the demand for accurate and reliable angular position sensing solutions across these applications is expected to grow, driving innovation and expansion opportunities in the automotive sensor market.

Global Automotive Angular Positions Sensors Market, Segmentation by End-User

The Global Automotive Angular Positions Sensors Market has been segmented by End-User into Manufacturing, Automotive, Aerospace, Packaging, Healthcare, Electronics and Others.

One significant end-user segment of the automotive angular position sensors market is the manufacturing industry. Within the manufacturing sector, angular position sensors are utilized in automotive production facilities for tasks such as robotic assembly, CNC machining, and quality control. These sensors enable precise positioning and motion control of manufacturing equipment, ensuring accurate assembly of vehicle components and adherence to strict quality standards throughout the production process.

The automotive industry itself represents another key end-user segment for angular position sensors. Within the automotive sector, these sensors are integrated into vehicles during manufacturing for various applications such as engine management, chassis control, and driver assistance systems. Angular position sensors enable critical functionalities such as throttle control, steering angle measurement, and adaptive lighting, contributing to vehicle performance, safety, and comfort on the road.

Furthermore, the aerospace industry is a significant end-user of automotive angular position sensors. Within the aerospace sector, these sensors are utilized in aircraft manufacturing and maintenance for tasks such as flight control system calibration, landing gear position sensing, and engine thrust vectoring. Angular position sensors play a vital role in ensuring precise control and navigation of aircraft, enhancing flight safety and operational efficiency in both civilian and military aviation applications.

Other end-user industries that utilize automotive angular position sensors include packaging, healthcare, electronics, and more. In the packaging industry, these sensors are employed in packaging machinery for tasks such as labeling, filling, and palletizing, enabling precise positioning and control of packaging processes. In healthcare, angular position sensors are utilized in medical devices such as robotic surgery systems, patient monitoring equipment, and diagnostic imaging machines, supporting accurate positioning and motion control in medical procedures and treatments.

Global Automotive Angular Positions Sensors Market, Segmentation by Geography

In this report, the Global Automotive Angular Positions Sensors Market has been segmented by Geography into five regions; North America, Europe, Asia Pacific, Middle East and Africa and Latin America.

Global Automotive Angular Positions Sensors Market Share (%), by Geographical Region, 2024

Europe represents another key region in the global automotive angular position sensors market, characterized by a mature automotive ecosystem, rigorous safety regulations, and a strong emphasis on vehicle performance and efficiency. European automakers are at the forefront of innovation in automotive technology, driving the adoption of angular position sensors in applications such as engine management, chassis control, and driver assistance systems. Moreover, Europe's focus on sustainable transportation solutions and smart city initiatives creates opportunities for sensor manufacturers to support the development of electric vehicles, connected mobility, and autonomous driving infrastructure.

Asia-Pacific emerges as a significant growth driver in the global automotive angular position sensors market, fueled by the rapid expansion of the automotive industry, increasing vehicle production, and rising consumer demand for advanced automotive technologies. Countries such as China, Japan, and South Korea are leading automotive manufacturing hubs, driving demand for angular position sensors in applications ranging from powertrain systems to ADAS and vehicle electrification. Furthermore, Asia-Pacific's focus on urbanization, infrastructure development, and smart transportation initiatives presents opportunities for sensor manufacturers to supply solutions for intelligent mobility, electric vehicle charging infrastructure, and connected vehicle technologies.

Other regions, including Latin America, the Middle East, and Africa, also contribute to the global automotive angular position sensors market, albeit to a lesser extent compared to the major automotive markets. Factors such as urbanization, industrialization, and infrastructure investments influence sensor demand in these regions, particularly in applications such as industrial automation, aerospace, and healthcare.

This report provides an in depth analysis of various factors that impact the dynamics of Global Automotive Angular Positions Sensors Market. These factors include; Market Drivers, Restraints and Opportunities Analysis.

Drivers, Restraints and Opportunity Analysis

Drivers :

• Regulatory Compliance Requirements
• Rising Demand for Advanced Driver Assistance Systems (ADAS)

• Vehicle Electrification and Hybridization - Vehicle electrification and hybridization represent transformative trends reshaping the automotive industry, driven by the urgent need to reduce greenhouse gas emissions, improve fuel efficiency, and address environmental concerns. Electrification involves the adoption of electric powertrains, which replace or supplement traditional internal combustion engines (ICEs) with electric motors and batteries. On the other hand, hybridization involves the integration of both ICEs and electric powertrains in hybrid electric vehicles (HEVs), plug-in hybrid electric vehicles (PHEVs), and mild hybrid electric vehicles (MHEVs), offering varying degrees of electrification.

  One of the primary drivers behind vehicle electrification and hybridization is the imperative to reduce carbon dioxide (CO2) emissions and mitigate the impact of transportation on climate change. With growing awareness of the environmental consequences of fossil fuel consumption, governments worldwide have implemented stringent regulations and emissions standards to incentivize automakers to develop cleaner, more fuel-efficient vehicles. Electrification and hybridization technologies offer a pathway to achieve lower emissions and improve air quality by reducing reliance on fossil fuels and transitioning to electric propulsion.

  Vehicle electrification and hybridization align with broader sustainability goals and initiatives aimed at promoting renewable energy sources and reducing dependence on finite resources. Electric vehicles (EVs) and hybrids offer the potential to leverage clean energy sources such as solar, wind, and hydroelectric power for vehicle charging, thereby reducing greenhouse gas emissions and decreasing the environmental footprint of transportation. Additionally, advancements in battery technology, energy storage, and charging infrastructure are driving improvements in the range, performance, and affordability of electric and hybrid vehicles, making them increasingly viable alternatives to conventional ICE vehicles.

  Vehicle electrification and hybridization offer benefits beyond environmental sustainability, including enhanced energy efficiency, reduced operating costs, and improved driving experiences. Electric powertrains are inherently more efficient than ICEs, resulting in lower energy consumption and operating costs over the vehicle's lifetime. Hybrid vehicles combine the benefits of electric propulsion with the range and flexibility of traditional ICEs, offering improved fuel economy, reduced emissions, and smoother acceleration. As a result, consumers are increasingly drawn to electric and hybrid vehicles for their lower fuel costs, quieter operation, and responsive performance.

Restraints :

• Cost Constraints
• Complexity in Integration
• Reliability Concerns

• Compatibility Issues - Compatibility issues in the context of vehicle electrification and hybridization refer to challenges related to the integration of electric and hybrid powertrains with existing vehicle platforms, components, and infrastructure. These issues arise due to differences in design, specifications, and operating characteristics between conventional internal combustion engine (ICE) vehicles and electrified vehicles.

  One of the primary compatibility issues is the integration of electric powertrains into vehicle platforms originally designed for ICEs. Electric vehicles (EVs) and hybrid electric vehicles (HEVs) require unique components such as electric motors, batteries, power electronics, and charging systems, which may not be compatible with the existing architecture of conventional vehicles. Retrofitting or redesigning vehicle platforms to accommodate electric powertrains involves significant engineering and manufacturing challenges, including structural modifications, weight distribution considerations, and thermal management requirements.

  Compatibility issues arise in the context of vehicle components and subsystems. Electric and hybrid vehicles require specialized components such as high-voltage wiring, electric cooling systems, regenerative braking systems, and energy management systems, which may not be compatible with legacy vehicle components designed for ICEs. Ensuring compatibility between electric and conventional vehicle components involves addressing differences in voltage levels, electrical interfaces, communication protocols, and safety requirements, which can complicate vehicle integration and increase development costs.

  Compatibility issues extend to charging infrastructure and service networks. Electric vehicles rely on charging infrastructure for replenishing battery energy, which includes public charging stations, home charging units, and fast-charging networks. Ensuring compatibility between electric vehicles and charging infrastructure involves standardization of charging protocols, connector types, and power delivery specifications, enabling seamless interoperability and user experience. Additionally, compatibility issues may arise in the context of service and maintenance, as electric and hybrid vehicles require specialized training, tools, and diagnostic equipment for servicing electric powertrains and battery systems, which may not be readily available or accessible to traditional automotive service providers.

  Addressing compatibility issues in vehicle electrification and hybridization requires collaboration and standardization efforts across the automotive industry, government agencies, and technology stakeholders. Establishing common standards, protocols, and certification requirements for electric vehicle components, charging infrastructure, and service networks can facilitate interoperability and compatibility, accelerating the adoption and deployment of electric and hybrid vehicles. Moreover, investing in research and development initiatives aimed at advancing vehicle integration technologies, battery management systems, and charging infrastructure solutions can help overcome compatibility challenges and drive the transition towards a more sustainable and electrified transportation ecosystem.

Opportunities :

• Rapid Technological Advancements
• Increasing Demand for Electric and Hybrid Vehicles
• Expansion of Advanced Driver Assistance Systems (ADAS)

• Integration in Autonomous Vehicles - Integration in autonomous vehicles refers to the incorporation of various sensors, actuators, computing systems, and software algorithms to enable autonomous driving capabilities. This integration process involves the seamless coordination and interoperability of hardware and software components within the vehicle architecture, allowing it to perceive, interpret, and respond to its environment without human intervention.

  One of the key components integrated into autonomous vehicles is a suite of sensor technologies, including cameras, LiDAR (Light Detection and Ranging) sensors, radar, ultrasonic sensors, and GPS (Global Positioning System) receivers. These sensors provide real-time data on the vehicle's surroundings, including road conditions, traffic, pedestrians, and obstacles, enabling the vehicle to create a detailed perception of its environment and make informed driving decisions.

  Autonomous vehicles rely on advanced computing systems, including onboard computers and processors, to process sensor data, run complex algorithms, and make real-time decisions. These computing systems are equipped with powerful processors, memory, and storage capabilities, enabling them to handle the massive amounts of data generated by sensor inputs and execute sophisticated algorithms for perception, localization, mapping, and path planning.

  Integration in autonomous vehicles involves the deployment of software algorithms for perception, decision-making, and control. These algorithms leverage sensor data to detect and classify objects in the vehicle's environment, predict their behavior, and plan safe and efficient driving trajectories. Machine learning and artificial intelligence techniques are often employed to train algorithms and improve their performance over time, enabling autonomous vehicles to adapt to changing driving conditions and learn from past experiences.

  Autonomous vehicles incorporate actuators such as steering, braking, and acceleration systems to execute driving commands generated by the onboard computing systems. These actuators enable the vehicle to control its movement, navigate through traffic, and respond to dynamic situations, ensuring safe and reliable autonomous driving.

  Integration in autonomous vehicles also extends to communication systems and connectivity technologies, enabling vehicles to exchange data with other vehicles, infrastructure, and cloud-based services. Vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I) communication capabilities enable cooperative driving behaviors, such as platooning and intersection coordination, enhancing traffic flow and safety in connected environments.

Key players in Global Automotive Angular Positions Sensors Market include :

• SICK AG
• TE Connectivity
• Bourns
• Allegro MicroSystems
• Renishaw plc

In this report, the profile of each market player provides following information:

• Company Overview and Product Portfolio
• Key Developments
• Financial Overview
• Strategies
• Company SWOT Analysis