This thesis consists of three main parts. The first part presents the design and measurement results of 40-56 GHz broadband LNA with linearizer technique, fabricated in a 90-nm CMOS process. The second part discusses the design and measurement of a low-power distributed amplifier as wideband IF preamplifier for astronomical receivers, fabricated in a 90-nm CMOS process. The third part describes the design and measurement results of X-band non-uniform distributed power amplifier (NDPA) for high power-level system application, fabricated in 0.25-μm GaN HEMT process. The first part focuses on a broad band low-noise amplifier (LNA) by using two-stage current-reused and one-stage common source operating in the 40-56 GHz frequency range, utilizing the derivative superposition (DS) linearization technique in 90-nm CMOS technology. It also features an input matching design with a three-winding feedback transformer that provides low noise figure (NF), optimized input matching, and significant gain across a wide bandwidth. The LNA achieves a peak small signal gain of 21.3 dB at 46 GHz, with a 3-dB bandwidth from 40 to 56 GHz, a minimum NF of 4.8 dB at 48 GHz, and an average NF of 5.7 dB across the band, all while consuming only 19.4 mW of power. When the linearizer is active, the LNA exhibits an IIP3 of 0 dBm. The second part presents introduces This work presents a distributed amplifier (DA) operating in the 6-58 GHz frequency range, achieving a small signal peak gain of 18.5 dB at 8 GHz. The design features two stages of conventional distributed amplifiers (CDA), providing advantages like a low noise figure and high output power. The DA is efficient, consuming only 36.2 mW of DC power and having a compact chip size of 0.85 mm², including pads. It supports a bandwidth of up to 52 GHz, with gain variations maintained within 3-dB across the operating range. The last part presents This work presents a power amplifier (PA) designed for the X-band, fabricated using a 0.25-µm GaN HEMT process, aimed at achieving 10W output power through a one-stage non-uniform distributed amplifier architecture. The design includes a specialized cooling module to effectively manage heat dissipation. The PA demonstrates a small-signal gain exceeding 10.5 dB across the 6-12 GHz frequency range, with a die size of 12 mm², achieving a peak power-added efficiency (PAE) of 23.4% at 9 GHz and saturated output power exceeding 38 dBm. This research emphasizes the advantages of non-uniform distributed amplifiers (NDPA) in enhancing both output power and PAE in wideband GaN-based power amplifiers.