With the rapid development of 4G, 5G mobile communication and High Definition (HD) video, the information volume carried by traditional NRZ signal is not enough for today’s needs. Because the PAM-4 signal can carry twice the information volume of the NRZ signal, the PAM-4 signals have been adopted to replace NRZ signals in the next generation high-speed wired communication system. There are different types of noise, dispersion, attenuation, et cetera. which affect the overall signal transmission quality in the high-speed wired communication system, so real-time signal quality monitoring and analysis for high-speed wired communication system is indispensable. Due to the high data rate in high-speed wired communication system, a complex high-speed CDR (clock data recovery) circuit is needed for recovering the clock from the signal during the signal quality analysis in synchronous sampling. In this thesis, asynchronous sampling is employed on the receiver end which can avoid the use of the CDR to effectively reduce design cost of signal monitoring. A part from that, the asynchronous sampling can also be used in multi-channel systems of various data rates. In this thesis, asynchronous sampling of the PAM-4 signal is adopted, and an novel algorithm is development for reconstructing the PAM-4 signal eye diagrams. Because the PAM-4 signal is different from the NRZ signal, we proposed an eye segmentation and eye pattern overlap method for estimating the parameters of each individual PAM-4 signals’ sub-eye diagrams. The parameters include eyewides, eyeheights, peak-to-peak jitters, and symbol error rates. After extracting the signal parameters, the best sampling position for the overall signal can be determined. The PAM-4 eye-diagram parameter analysis algorithm presented in this thesis can obtain the signal parameters rapidly with a simple implementation. With slight modification, it can be applied for real-time signal quality monitoring and analysis of higher-order modulated signals.