How the brain controls complex movements has been a mystery. Advances in artificial intelligence now make it possible to simulate this process in virtual animals. Comparing activations in artificial ...

Hyundai has recently provided an enlightening explanation of how electric vehicle (EV) motors operate, simplifying complex engineering concepts into digestible insights. This comprehensive guide, ...

Vector Control, also known as Field Oriented Control or FOC is an AC motor control scheme that enables fine-grained control over a connected motor, through the precise control of its phases. In a ...

Brake-by-wire systems are becoming a core technology for intelligent electric vehicles, but their performance depends heavily ...

Electric motors, which convert electrical energy into mechanical energy, play an essential role in a variety of industrial and robotics applications. Given that electric motors account for ...

How current-control loops in BLDC motors improve performance and efficiency while protecting against overcurrent conditions. The differences between current-control loops, field-oriented control (FOC) ...

A new sensor provides full-range motor position tracking, interference resistance, and safety for high-speed control in electric vehicle systems.

Engineers involved in EV projects are transitioning from hardware-first to software-integrated control strategies. System-level engineering is now essential, ensuring all vehicle components operate ...

AI can be added to legacy motion control systems in three phases with minimal disruption: data collection via edge gateways, non-interfering anomaly detection and supervisory control integration.

How the challenges of electric-motor control design can be overcome using digital twins in all design and test phases. How automated testing within a continuous and integrated toolchain is able to ...