EV Research Projects
Real-world EV engineering projects built by student teams and professionals. Each project tracks milestones, artifacts, reviews, approvals, and certificate eligibility.
AI-Powered Air Taxi (eVTOL) Solutions
End-to-end AI-assisted design and development of electric Air Taxi (eVTOL) systems covering mission definition, system architecture, and performance validation. The project produces certification-ready engineering evidence, safety artifacts, and predictive operational intelligence.
Key Highlights
- Mission and requirement engineering for eVTOL operations including range, payload, safety, and turnaround constraints
- System-of-systems architecture design covering propulsion, energy storage, avionics, communications, thermal, and structures
- AI-assisted sizing, trade studies, and optimization of weight, power, and energy efficiency
- Digital twin and simulation models for mission performance, stress prediction, and validation
- Predictive maintenance framework using telemetry for anomaly detection and remaining useful life estimation.
0% Complete
EV BATTERY SAFETY SYSTEMS
A digital identity and lifecycle governance platform for EV battery packs enabling traceability, ownership verification, and regulatory compliance. The system creates an AI-ready data backbone for safety monitoring, lifecycle intelligence, and sustainable battery management..
Key Highlights
- Unique Battery Identity with QR/NFC-based lifecycle tracking from manufacturing to recycling
- Digital Battery Passport storing chemistry, configuration, warranty, and compliance records
- Role-based portals for OEMs, service centers, regulators, and recyclers with governance workflows
- Tamper-proof audit trail of battery events including service, swap, repair, and second-life transfer
- AI-ready structured data model enabling battery health scoring, risk prediction, and performance analytics
2% Complete
Design and Development of Micro & Nano Satellites with Light Rocket Systems
End-to-end design and development of micro and nano satellite systems integrated with light rocket platforms for low-altitude missions. The project focuses on payload design, avionics, telemetry, energy systems, and safe launch-recovery mechanisms, enabling hands-on aerospace engineering experience aligned with real-world space missions.
Key Highlights
- Design and development of micro/nano satellite (CANSAT-class) systems with modular payload architecture
- Lightweight model rocket design for safe payload deployment up to target altitude
- Integrated avionics system including sensors, flight controller, and telemetry communication
- Energy system design inspired by EV Battery Management Systems (BMS) for efficient power utilization
- Real-time data acquisition, transmission, and ground station monitoring
- Safe deployment, parachute-based descent, and recovery system design
- Simulation and validation using digital twin models for flight dynamics and mission performance
- End-to-end mission lifecycle engineering including design, testing, launch, and post-flight analysis
0% Complete