Fatigue experimental setups for studying the crack growth propagation in a high strength low alloy DMR 249A ship steel were arranged by loading the specimen with the real sea state conditions value of 4 for the application of structural health monitoring of ships. The experimental setup consists of a fatigue loading machine, acoustic emission (AE) sensors, AE nodes for pre-processing of data. In this investigation, a methodology to identify the crack propagation phenomenon in a specimen independent of the AE parameters has been developed. This methodology proves beneficial in identifying the noise and crack information in ship steel by creating the phase portraits of the time domain signal and indicating the same onto the phase portraits. A polynomial regression-based model for estimating the crack growth rate in the material has been developed by introducing a new parameter mean of box count (MBC). IEEE