Global Connected E-Bike Market Size, Share and Forecasts 2031

Key Findings

• The connected e-bike market is growing rapidly due to rising consumer demand for smart mobility solutions and integrated digital features.
• GPS tracking, IoT-enabled diagnostics, and smartphone app integrations are transforming the e-bike riding experience.
• Real-time navigation, performance analytics, and theft protection systems are key features boosting adoption worldwide.
• Europe leads premium connected e-bike adoption, while Asia-Pacific dominates in production volumes and emerging markets.
• Increasing investment from automotive and tech companies is driving innovation in e-bike connectivity ecosystems.
• The shift toward sustainable urban mobility solutions is accelerating global connected e-bike market expansion.
• Over-the-air (OTA) software updates and cloud-based connectivity platforms are gaining traction across leading brands.
• Battery management, predictive maintenance, and remote locking features are becoming standard in connected e-bikes.
• Collaborations between e-bike OEMs, telecom operators, and mobility-as-a-service (MaaS) providers are rising steadily.
• Government incentives for e-mobility adoption indirectly drive demand for connected e-bike technologies.

Connected E-Bike Market Size and Forecast

The global connected e-bike market was valued at USD 2.1 billion in 2024 and is projected to reach USD 7.8 billion by 2031, growing at a CAGR of 20.3% during the forecast period. Increasing urbanization, rising fuel costs, and the need for sustainable mobility solutions are accelerating adoption worldwide. Continuous innovation in IoT, 5G connectivity, and battery management technologies is further driving demand for connected e-bikes across multiple regions.

Market Overview

Connected e-bikes integrate advanced digital technologies such as IoT modules, GPS systems, and cloud-based platforms to provide riders with real-time data, improved safety, and enhanced convenience. These bikes are equipped with sensors and smart controllers enabling predictive maintenance, battery optimization, and seamless app-based interaction. The growing ecosystem of smart mobility solutions and digital services is transforming the cycling experience from manual commuting to technology-driven, data-enabled mobility.

Future Outlook

The future of connected e-bikes lies in AI-based route optimization, advanced telematics, and integration with urban mobility platforms. Over-the-air updates and vehicle-to-infrastructure (V2I) communication will enable smarter traffic interactions and energy-efficient ride planning. Strategic partnerships between e-bike OEMs, software firms, and telecom providers will shape the next phase of product innovation. With rising focus on sustainability and urban mobility, connected e-bikes are expected to play a central role in next-generation smart cities.

Connected E-Bike Market Trends

• Integration of IoT and Cloud Platforms
  Connected e-bikes are increasingly adopting IoT modules for real-time data sharing with cloud servers, enabling analytics-driven insights for users and fleet operators. These features support predictive maintenance, remote diagnostics, and performance monitoring to improve overall ride quality. Cloud platforms enhance user experience through seamless synchronization with smartphones and wearables. As connectivity costs decline, adoption is expected to accelerate in both consumer and commercial markets. Companies are focusing on modular IoT integration to make the technology scalable across models.

• Adoption of GPS-based Navigation and Theft Prevention Systems
  Integrated GPS solutions are becoming a standard feature in connected e-bikes, providing real-time navigation, geofencing, and anti-theft alerts directly on smartphones. This is particularly important in urban regions with rising e-bike theft cases, making security-focused features a major selling point. Riders benefit from automated route optimization for time and energy efficiency, enhancing convenience and reducing commuting times. The combination of GPS data and mobile connectivity supports advanced fleet management applications. Premium brands are offering subscription-based services for enhanced tracking and security features.

• Growth of Smartphone App Ecosystems for Riders
  E-bike manufacturers are launching dedicated mobile applications for ride analytics, health tracking, and remote vehicle control. These apps offer features such as trip history, battery status monitoring, and OTA firmware updates for enhanced functionality. Smartphone ecosystems create a seamless user experience by integrating navigation, communication, and performance tracking in one interface. As app ecosystems mature, riders will gain access to AI-powered insights and route recommendations. Growing consumer expectations for smart mobility are pushing continuous app innovation across the industry.

• Rise of Mobility-as-a-Service (MaaS) and Fleet Deployments
  Connected e-bikes are increasingly deployed in shared mobility and last-mile delivery fleets due to their connectivity-enabled telematics features. Fleet operators rely on real-time data for vehicle tracking, battery status monitoring, and predictive maintenance to reduce downtime and operating costs. This trend is supported by urban regulations promoting zero-emission last-mile delivery vehicles. Commercial fleet adoption is driving demand for rugged, connectivity-rich e-bike platforms with advanced telematics dashboards. Integration with MaaS platforms further enhances operational efficiency and customer experience.

• Advancements in Battery Management and Energy Optimization
  Connected e-bikes now feature smart battery systems offering real-time monitoring, automated energy optimization, and fault detection alerts. Advanced battery management systems (BMS) integrate with mobile apps for charge scheduling, energy analytics, and predictive diagnostics. This improves battery lifespan while reducing operational costs for both consumers and fleet operators. Battery-related data also enables AI-driven performance recommendations for riders. Manufacturers are focusing on modular and swappable battery architectures with enhanced safety standards.

Market Growth Drivers

• Rising Adoption of E-bikes in Urban Mobility Programs
  Cities across Europe, Asia, and North America are integrating e-bikes into public transportation and last-mile connectivity networks. Connected technologies improve operational efficiency through real-time tracking, route planning, and automated billing systems. Urban congestion and environmental policies further support connected e-bike deployments in smart city projects. Governments are incentivizing e-bike sharing schemes to reduce vehicle emissions and promote sustainable commuting. These initiatives accelerate adoption across both consumer and commercial segments globally.

• Technological Advancements in Connectivity Infrastructure
  5G networks, edge computing, and IoT platforms are enabling low-latency, high-speed data transmission for connected e-bikes. This technological evolution supports real-time navigation, over-the-air updates, and AI-based traffic optimization. Manufacturers are integrating advanced telematics modules to enhance ride safety, energy efficiency, and rider experience. Emerging connectivity standards improve interoperability across multiple mobility platforms. The combination of hardware and software innovation is driving industry-wide adoption of connected e-bike technologies.

• Increasing Consumer Demand for Digital Features
  Modern consumers expect smartphone connectivity, ride analytics, and personalized mobility experiences in their vehicles. Connected e-bikes meet this demand by offering app-based control, health tracking, and entertainment integrations. Digital features also support subscription-based revenue models for premium services such as theft tracking and predictive diagnostics. User-friendly interfaces and real-time data access enhance customer satisfaction levels. As digital lifestyles expand, e-bikes are evolving into fully connected mobility devices rather than standalone vehicles.

• Growth of E-commerce and Direct-to-Consumer Channels
  Online platforms are driving sales of connected e-bikes by enabling personalized configurations, remote diagnostics support, and doorstep delivery options. E-commerce adoption expands market reach for manufacturers while lowering distribution costs. Digital retail platforms facilitate data-driven marketing campaigns targeting urban commuters and delivery fleet operators. Integration with mobile apps supports seamless after-sales service and software updates. Direct-to-consumer models allow manufacturers to collect real-time user data for product development insights.

• Collaborations Between E-bike OEMs and Technology Providers
  Partnerships with telecom operators, software companies, and IoT solution providers are accelerating development of connected e-bike ecosystems. These collaborations enable bundled offerings integrating hardware, connectivity, and cloud analytics in a single package. Strategic alliances also support standardization efforts for interoperability across different brands and platforms. Co-development initiatives shorten product launch cycles while ensuring feature-rich offerings for end users. Joint marketing campaigns further expand consumer awareness and adoption rates.

Challenges in the Market

• High Costs of Connected Technologies
  Advanced connectivity modules, GPS systems, and telematics dashboards significantly increase e-bike production costs, limiting affordability for price-sensitive consumers. Manufacturers face the challenge of balancing premium features with competitive pricing strategies for emerging markets. High upfront costs restrict large-scale adoption in low-income regions despite growing interest in smart mobility. Cost reductions through mass production and local sourcing are essential for broader market penetration. The shift toward modular designs aims to lower integration expenses for OEMs.

• Data Privacy and Cybersecurity Concerns
  Connected e-bikes generate large volumes of location and user data, raising concerns around data security and privacy protection. Cyberattacks targeting mobility platforms could compromise rider safety and sensitive information. Manufacturers must implement robust encryption, authentication, and cybersecurity protocols to build consumer trust. Compliance with regional data protection regulations adds complexity for global market players. Continuous monitoring and threat detection solutions are becoming integral parts of connected e-bike ecosystems.

• Lack of Standardization in Connectivity Protocols
  Different manufacturers adopt proprietary connectivity standards, resulting in interoperability challenges across e-bike models and platforms. The absence of common technical specifications limits third-party app development and ecosystem expansion. Standardization efforts by industry associations are essential for ensuring seamless integration of hardware and software solutions. Lack of harmonization also increases production costs for accessory and component suppliers. Collaborative standard-setting initiatives can accelerate industry-wide adoption of connected technologies.

• Limited Charging and Connectivity Infrastructure in Emerging Markets
  In developing regions, inadequate charging stations and unreliable internet connectivity hinder connected e-bike adoption. Rural and semi-urban areas face additional challenges with network coverage and energy infrastructure. Governments and private investors must prioritize digital and energy infrastructure to support connected mobility growth. Manufacturers are exploring offline-capable features for markets with poor connectivity reliability. Infrastructure development will play a critical role in unlocking full market potential for connected e-bikes.

• Supply Chain Disruptions and Component Shortages
  Global semiconductor shortages, logistics delays, and geopolitical uncertainties are impacting availability of telematics modules and IoT chips. These disruptions increase production costs and delay product launches for connected e-bike manufacturers. Companies are diversifying supplier bases and adopting regional manufacturing hubs to reduce dependency risks. Inventory optimization strategies are helping mitigate short-term supply constraints across the value chain. Long-term resilience planning is essential for sustaining growth in volatile market conditions.

Connected E-Bike Market Segmentation

By Technology

• IoT Modules and Telematics Systems

• GPS Navigation and Tracking Solutions

• Smartphone App Ecosystems

• Cloud Connectivity Platforms

• Battery Management Systems

By Application

• Consumer Commuting E-bikes

• Fleet and Commercial Delivery E-bikes

• Mobility-as-a-Service (MaaS) Platforms

• Recreational and Tourism E-bikes

By Sales Channel

• Online E-commerce Platforms

• Offline Specialty Stores

• Direct-to-Consumer Channels

• OEM Dealership Networks

By Region

• North America

• Europe

• Asia-Pacific

• Latin America

• Middle East & Africa

Leading Key Players

• Bosch eBike Systems

• Shimano Inc.

• Yamaha Motor Co. Ltd.

• Giant Bicycles

• Trek Bicycle Corporation

• VanMoof BV

• Specialized Bicycle Components

• Mahle GmbH

• Brose Fahrzeugteile SE & Co. KG

• Livall Tech Co. Ltd.

Recent Developments

• Bosch eBike Systems launched AI-powered predictive maintenance features for connected e-bikes through its IoT platform.

• Yamaha Motor Co. Ltd. introduced 5G-enabled connected e-bike prototypes for smart city pilots in Japan.

• VanMoof BV partnered with telecom operators to integrate eSIM connectivity in premium e-bike models.

• Trek Bicycle Corporation rolled out OTA software update capabilities for real-time performance enhancements.

• Shimano Inc. collaborated with cloud service providers to develop fleet management dashboards for delivery e-bikes.

This Market Report will Answer the Following Questions

• How many Connected E-Bike systems are manufactured per annum globally? Who are the sub-component suppliers in different regions?

• Cost Breakdown of a Global Connected E-Bike system and Key Vendor Selection Criteria.

• Where is the Connected E-Bike system manufactured? What is the average margin per unit?

• Market share of Global Connected E-Bike manufacturers and their upcoming products.

• Cost advantage for OEMs who manufacture Global Connected E-Bike systems in-house.

• Key predictions for the next 5 years in the Global Connected E-Bike market.

• Average B2B Connected E-Bike market price in all segments.

• Latest trends in the Connected E-Bike market, by every market segment.

• The market size (both volume and value) of the Connected E-Bike market in 2025–2031 and every year in between.

• Production breakup of the Connected E-Bike market, by suppliers and their OEM relationships.