As the increasing demand of ultrasound imaging system in wide variety of hand-held devices in diagnostic medicine, design of analog receiver front-end circuits has become an important issue, especially enlarging the dynamic range with a limited power budget. In this dissertation, a receiver chain including low-noise amplifier (LNA), voltage-controlled attenuator (VCA), programmable-gain amplifier (PGA), and low-pass filter (LPF) is realized in a 0.13-µm CMOS process. With reasonable power consumption, good harmonic distortions and input-referred noise in the LNA are achieved, leading to an optimized dynamic range. Besides, other minor LNA specifications such as input matching, dc-offset cancellation, common-mode feedback, and overload recovery time are also considered. In the following VCA stage, a design procedure including sizing strategy is given, which analyzes controlled range, gain error, linearity, noise, and mismatch in detail. To further reduce the distortion, a simple and effective linearization technique suitable for voltage-controlled MOS resistors is proposed, where the short-channel-device model is utilized for analysis. In the last stages of this receiver chain, the PGA with two gain modes provides appropriate voltage gains for the aimed analog-to-digital convertor, while the 3rd LPF has two controllable frequency corners, which is responsible for anti-aliasing. According to the system requirements and the power budget in a full receiver chain, this dissertation also discusses the parameters’ selection as well as the trade-off. Using 1.2-V and 3.3-V supply voltages, the proposed analog receiver chain achieves 1.1-nV/rtHz input-referred noise, 42-dB gain range, 0.6-dB gain error, 10/20-MHz 3rd frequency corner, and 2-VPP output swing with HDs better than -50 dBc. Consuming power less than 80 mW, the proposed work is proved suitable for the systems in hand-held devices and has comparable performances with commercial products.