Anomaly detection plays an important role in ensuring the safety and reliability of complex Internet of Things (IoT) systems through analysis of time-series data. Generally, real-world signals exhibit intrinsic nonstationary characteristics, resulting in a significant challenge the context of anomaly detection for time-series data. In this study, a novel Wavelet-Koopman predictor is proposed for time-series data modeling and anomaly detection underlying nonstationary dynamics of complex systems. The proposed wavelet-Koopman decomposes nonstationary data into time variant and time invariant components and processes them separately using different neural Koopman operators. The operation of Wavelet decomposition avoids the impact of nonstationary temporal data on prediction results so the proposed Wavelet-Koopman is able to model and predict nonstationary time series data, which lays the foundation for the implementation of anomaly detection. Several experiments are conducted on common data sets and anomaly detection of liquid rocket engines are realized. The experimental results demonstrate that the proposed method outperforms several recent methods.