As we stand at the border of a new technological era, RF components are becoming the core enablers of cutting-edge technologies. The most innovative products today often resemble a patchwork of complex microwave components, making it challenging to maintain, produce, and improve. To transition these systems from the lab to everyday life, scalability improvements are essential.



This dissertation explores the scalability challenges in two forefront domains: quantum computing and 6G communications. In the field of quantum computing, the focus is on improving low-noise amplifiers to transition from hybrid to fully integrated designs, using advanced technologies such as mHEMT and CMOS. In the domain of next-generation communications, the research addresses the challenges of phased-array antennas beyond 300 GHz, where tight integration is crucial for optimal performance. This work demonstrates the ways to achieve more scalable, efficient, and accessible technological solutions in these rapidly evolving fields.