Design and simulation of 7 GHz CMOS wideband amplifier(CMOSWA) using a modified cascode circuit realized in 90-nm CMOS technology is presented here. The proposed system consists of two stages, namely a modified folded cascode and an inductively degenerated common source amplifier. The circuit is experimented with and without a feedback network. This work discusses the performance variation as a function of reactive components, and the initial stage results in 22 dB gain,2.6 GHz bandwidth, and 40GHz unity gain-bandwidth. The circuit without the feedback network exhibits 30.7dB gain,4.8GHz bandwidth(BW), and 10GHz unity-gain bandwidth(UGB). The reactive feedback network's inclusion helped to achieve 38.7 dB gain, 6.95GHz BW, 30GHz UGB, and 55o phase margin. The circuit consumes 1.4mW power from a 1.8V power supply. Simulation results of the proposed circuit are comparable and better than the reported wideband designs in the literature. Realization of our proposed circuit would add value to the area of wideband amplifier design.
This work illustrates the design of the cell-based variable-gain amplifier (VGA) with less power consumption and improved noise margin. The variable gain amplifier is incorporated into the current wireless front-end modules. The body-bias technique in the n channel MOSFET (n-MOS) devices greatly aided in the power reduction of the cells. The device characteristics were fine-tuned to get better gain and bandwidth and reduced the supply voltage. This technique ultimately reduced the number of cell stages required to meet the expectation. The reduction of the supply voltage and the technology upscaling helped to improve the noise margin. The presented unit cell achieved accurate dB-linear characteristics across a wide tuning range, based on a unique gain control method with a combination of sub-threshold n-MOS and saturation n-MOS transistors as active loads. A 7-cell reconfigurable VGA is simulated in 0.18-[Formula: see text]m Complementary MOSFET technology to verify the concept. The simulation results showed that the bandwidth of the VGA is greater than 2.5[Formula: see text]GHz, while less than 0.78[Formula: see text]mW is consumed from a 1.5-V supply. A noise figure of 23.7[Formula: see text]dB is measured. Also, the VGA achieves a gain control range of 19[Formula: see text]dB with a gain error less than [Formula: see text][Formula: see text]dB or 26.3%. These results make the designed amplifier adequate for high-frequency applications.
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