The consumer electronics industry is moving at a pace we’ve never seen before. Think about what sits in our homes and pockets today - wearables that track our health, wireless chargers that eliminate cables, compact appliances

Permanent magnets lie at the heart of modern electromechanical systems—from electric vehicles and wind turbines to MRI machines and high-speed actuators.

In the modern world of rail, electrification, speed, and connectivity define progress. Trains today are no longer just mechanical marvels—they are electromechanical ecosystems..

This blog explores key EV components, including electronic control units, power components, PCBs, wiring, charging connectors, and busbars, before delving into strategies for managing heat.

As the automotive industry accelerates its transition to electric mobility, the demand for efficient and high-performance electric vehicle (EV) powertrains is growing exponentially.

Electric motors (E-motors) account for a significant portion of global energy consumption, comprising 70% of the electricity used in the industrial sector.

Superconducting quantum circuits (SQC), particularly those based on qubits, are at the core of modern quantum computing.

Hybrid Electric Vehicles (HEVs) are transforming the automotive industry by merging traditional internal combustion engines with electric powertrains.

Synchronous reluctance motors (synRMs) are becoming increasingly prominent in electronic devices and electric vehicles (EVs) due to their efficiency, robustness, and cost-effectiveness.

From the past few decades, the world has witnessed many versions of a cellular network, 1G version was a basic voice communication system that supported only Analog modulation. The flavour of data connectivity was present in the second version that used in digital technology.