In recent years of ship accidents, an oil tanker loaded with 22 million gallons of fuel oil, unfortunately suffered a shipwreck. Finally, it split in half and sank in the sea. All the fuel oil are leaked out, causing extremely serious environment problem. The container ship was cracked at the midship in harsh marine environment and broken into two pieces. The ship was only five years old, and lost more than 250 million US dollars. Above two accidents show that structural health monitoring play an important role in shipbuilding industry. Therefore, this paper is study optimized sensor placement and establishment of structural health monitoring method for large container ship. The stress response amplitude operator of shell elements under different ship speeds, heading angles and frequencies are calculated by using hydrodynamic analysis tool. Through results of short-term response analysis with 26 sea conditions and 5 equivalent regular wave design, the optimalized sensor position of large container ship is calculated, and shell elements at the optimalized sensor position are taken out. For short-term response analysis with different wave heights, this paper is established 6 data sets with different wave heights, and design different deep learning architectures according to the characteristics of stress signals. This paper is proposed five different deep learning architectures: RNN, LSTM, GRU, CNN combined with LSTM and CNN combined with GRU. Observe the influence of different deep learning architectures on multi-dimensional time series forecasting. The model with best performance in the North Atlantic sea conditions is LSTM model, the average root mean square error in each dataset is 0.008, and LSTM model architecture is used to establish structural health monitoring for different sea conditions.