This dissertation focuses on the developments of fast eye-diagram analyses and equalization techniques for solving the signal-integrity problems caused by the inter-symbol interference (ISI) in the high-performance backplane interconnect system. In the beginning, a worst-case eye-diagram analysis which relates to the step response of the transmission-line system is presented to quickly and accurately evaluate the electrical performance for the general interconnect systems. With the help of the prediction approach, the bounded voltage margins for the worst-case logic 1-state and 0-state are derived analytically. In addition to introducing how to obtain the worst-case bit patterns form the given step response, several examples are shown to demonstrate the accuracy of the developed approach. Secondly based on the finite-impulse response (FIR) filter as the transmitter pre-emphasis, a new design algorithm to directly optimize the eye diagram is proposed to counteract ISI in the high-speed data transmission. It is found that not only the frequency-dependent loss but also the multiple reflections due to impedance mismatch contribute much to ISI. Therefore, a systematic method is proposed to efficiently design FIR filters for the best eye-diagram improvement. The optimal sets of tap coefficients and numbers are thus determined by the direct eye-diagram optimization according to the target eye-masks as the objective function. Subsequently, the equalization results for counteracting the multiple reflections and lossy material problems are given to demonstrate the remarkable mitigation of ISI effects. Experimental results are also presented to validate the efficiency of the proposed method for the elimination of the ISI problems due to the multiple reflections and frequency-dependent loss. Furthermore, a passive FIR filter design is proposed to realize the de-emphasis function by taking the advantage of reflections under the additional inserting stub. The relations between the synthesized tap coefficients and the corresponding design parameters (RT, RS, Zh) are derived analytically and thus a universal design chart is well established to facilitate the passive FIR filter design. The passive solution has the advantages of reducing the power consumption of the transmitters and achieving the eye-diagram improvement efficiently. Finally, the systematic integration of signal-integrity aware layouts and the new continuous-time linear equalizer (CTLE) are proposed for enhancing the high-performance backplane interconnects system. First, the SI-aware layouts of patterned ground structure and capsule-shaped anti-pad are presented to enhance the connector performance. In addition, a new differential CTLE by taking the advantage of differential via-stubs is proposed to restore the eye-diagram deterioration in serial I/O links. Their application for a 117.5-cm SATA-II link demonstrates the significant improvement in the eye height and timing jitter. Furthermore, a viable approach is suggested to successfully re-open the eyes while the data rate increases from the current 3 Gb/s to 12 Gb/s. The measurement results are also provided to validate the proposed design concepts.