ABSTRACT This thesis is to discuss the high-speed transmission technique under the USB2.0 (Universal Serial Bus Revision 2.0) specification compliant, and to implement the circuit design of USB2.0 physical layer analog front-end receiver by using the process and SPICE models of TSMC 0.18um CMOS 1P5M. In the content, several frequently used circuit structures and techniques are introduced for high-speed transmission. In addition, a physical layer analog front-end receiver circuit design for USB2.0 that is backward compatible with USB1.1 is proposed. The design is composed of the high speed differential data receiver, the transmission envelope detector, the disconnection envelope detector, the full/low speed differential data receiver and two single-ended receivers for data bus (+) and data bus (). The role of the high speed differential data receiver is to receive high-speed signal with a data rate of 480Mbps. The transmission envelope detector has to sense and distinguish between high-speed signal and noise from the data bus. The disconnection envelope detector has to detect the state of connection between two devices. The full /low speed differential data receiver is for receiving the signal of full speed with a data rate of 12Mbps and low speed with a data rate of 1.5Mbps. The last are two single-ended receivers that are for receiving the signal from data bus (+) and data bus (), respectively. The signals on the data bus are processed by the circuits mentioned above to produce the outputs to the digital circuit. Then, the digital circuit decides the data flows of these outputs of the receivers. To save the power, a power down control circuit (PD) is added at each block. HSPICE is used to verify the overall circuit, and simulated by using the SPICE models of TSMC 0.18um CMOS 1P5M process.