This thesis presents a 1.2V 10-bit CMOS two-channel time-interleaved pipelined ADC in a standard 0.13-μm CMOS process. For high conversion speed, the first stage with divided residue gain is proposed to increase the feedback factor of the MDAC. In order to reduce the mismatch-effects, opamp-sharing technique is applied between two channels, and the proposed clock generator is designed to suppress the sampling-time mismatch. According to the measurement results, the prototype ADC exhibits a DNL of -0.49/+0.43LSB and an INL of -1.05/+0.86LSB at the sampling rate of 50MS/s. For 1MHz input frequency, the SNDR and SFDR achieve 56.53dB and 68.38dB at 50MS/s. The SNDR and SFDR are reduced to 37.63dB and 41.61dB at 250MS/s for 1MHz input. The power consumption is 106mW at the conversion rate of 250MS/s. The chip with pads occupies 1.3mm2. Chapter 1 introduces the pipelined ADC architecture. Chapter 2 discusses the channel mismatch effects in the time-interleaved ADC system. A proposed architecture to increase conversion speed and to reduce mismatch effects is given in Chapter 3. Detail circuit implementation and simulation result are shown in Chapter 4. Chapter 5 presents the test setup and measurement results. Finally, conclusions are summarized in Chapter 6.