Take a look at what we’re working on…
Quantum technologies are at the forefront of next-generation innovation, leveraging the principles of quantum mechanics to revolutionize information processing and communication. Our work aims to develop robust and scalable quantum networks. Quantum photonics combines light and quantum mechanics to enable on-chip quantum circuits, essential for quantum information processing. We investigate components for integrated quantum photonic platforms, quantum communication protocols.
We explore nanophotonics, which enables light control at the nanoscale for compact, energy-efficient devices. Surface plasmon resonances in metals can concentrate light into subwavelength volumes-critical for ultra-sensitive biosensing and nanoscale light-matter interaction. Metasurfaces is a planar nanostructured material that precisely control the phase, amplitude, and polarization of light. Our research focuses on designing, fabricating, and characterizing these advanced photonic platforms using cutting-edge nanofabrication and simulation tools.
Historically, we studied reflector designs, patch antenna for power efficiency and radiation pattern optimization. Satellite dishes offer high-gain communication links for remote sensing and deep-space communication. Patch antennas are low-profile, planar devices ideal for compact wireless systems and wearable electronics. Horn antennas, known for their high directivity and stability, are key in test ranges and microwave systems. We explored novel materials and miniaturization techniques to enhance bandwidth and polarization control.
The field of computer architecture underpins the performance and efficiency of all modern computing systems—from smartphones to supercomputers. Our research explores how to design processors that are faster, more energy-efficient, and capable of handling the demands of AI, scientific computing, and large-scale data analytics. We study microarchitecture components such as instruction pipelines, memory hierarchies, branch predictors, and multicore processors.
Embedded systems are specialized computing platforms built into larger systems to perform dedicated tasks, often under real-time constraints. Our research centers on designing energy-efficient, intelligent, and reliable embedded solutions for diverse applications. Embedded systems are specialized computing platforms built into larger systems to perform dedicated tasks, often under real-time constraints. Our research centers on designing energy-efficient, intelligent, and reliable embedded solutions for diverse applications.
We investigate solar cells, the core components that convert sunlight into electricity, aiming to improve their efficiency through novel materials and fabrication techniques. At the system level, we study solar panels, optimizing layout, orientation, and thermal management to enhance power output. Beyond generation, our research extends to grid optimization, ensuring stable integration of renewables into existing power infrastructures. We explore smart grid architectures, energy storage strategies, and predictive control algorithms to balance supply and demand.