The heave motion of ships under medium sea conditions can be severe, with amplitudes often exceeding 1 m, posing significant risks to operational safety and personnel. To address this issue, this study proposes a deep learning-based method for predicting heave motion and subsequently compensating for it by treating the predicted motion as a disturbance. The CNN–Transformer–GRU neural network architecture is introduced and trained on a heave motion dataset. This model reduces prediction errors by more than 37.9% compared to conventional CNN–LSTM and Transformer-based approaches. To ensure effective and stable compensation, the predictions are incorporated as input disturbances into a model predictive control (MPC) framework. Simulation results demonstrate that the proposed controller exhibits excellent stability and robustness, maintaining relative displacement within 0.0015 m in the heave direction.
BorujeniSArrasLSrinivasanV, et al. (2023) Explainable sequence-to-sequence GRU neural network for pollution forecasting. Scientific Reports13: 9940–9940.
2.
ChenHXieJHanJ, et al. (2022) Position control of heave compensation for offshore cranes based on a particle swarm optimized model predictive trajectory path controller. Journal of Marine Science and Engineering10(10): 1427–1427.
3.
ChenNHuangDTuY, et al. (2025) A novel inertial parameter identification method for the ship-mounted Stewart platform based on a wave compensation platform. Measurement242(PC): 116010.
4.
ChenSXiePLiaoJ, et al. (2024a) Cascade NMPC-PID control strategy of active heave compensation system for ship-mounted offshore crane. Ocean Engineering302: 117648.
5.
ChenWWangSLiJ, et al. (2023) An ADRC-based triple-loop control strategy of ship-mounted Stewart platform for six-DOF wave compensation. Mechanism and Machine Theory184: 105289.
6.
ChenZCheXWangL, et al. (2024b) Machine learning for ship heave motion prediction: Online adaptive cycle reservoir with regular jumps. Ocean Engineering294: 116767.
7.
ConsensMDufaultCWainbergM, et al. (2025) Transformers and genome language models. Nature Machine Intelligence7: 346–362.
8.
DurapA (2023) A comparative analysis of machine learning algorithms for predicting wave runup. Anthropocene Coasts6(1): 17.
9.
GuoXZhangXTianX, et al. (2021) Predicting heave and surge motions of a semi-submersible with neural networks. Applied Ocean Research112: 102708.
10.
HalvorsenHØveraasHLandstadO, et al. (2021) Wave motion compensation in dynamic positioning of small autonomous vessels. Journal of Marine Science and Technology26: 693–712.
11.
HongLLiuHYangQ, et al. (2024) Model predictive attitude control of unmanned surface vehicle based on short-time wave prediction. Ocean Engineering314: 119727.
12.
HuLZhangMYuanZ, et al. (2023) Predictive control of a heaving compensation system based on machine learning prediction algorithm. Journal of Marine Science and Engineering11(4): 821–821.
13.
JimohIKüçükdemiralIBevanG (2021) Fin control for ship roll motion stabilisation based on observer enhanced MPC with disturbance rate compensation. Ocean Engineering224: 108706.
14.
KevinEJasonM (2021) Optimal methods for estimating the JONSWAP spectrum peak enhancement factor from measured and hindcast wave data. Journal of Offshore Mechanics and Arctic Engineering143(2): 021202.
15.
LiDWangSSongX, et al. (2024a) A BP-neural-network-based PID control algorithm of Shipborne Stewart platform for wave compensation. Journal of Marine Science and Engineering12(12): 2160.
16.
LiRFengZJiangZ, et al. (2025a) An improved constraint control framework for unmanned surface vehicles using command-filtered backstepping technique. Journal of the Franklin Institute362(2): 107499.
17.
LiRFengZShiY, et al. (2025b) Distributed finite-time bipartite consensus control for constrained nonlinear MASs: A switched function approach based on prioritized strategy. IEEE Transactions on Automatic Control. Epub ahead of print 1 August. DOI: 10.1109/TAC.2025.3595002.
18.
LiWWuCLinS, et al. (2025c) Active heave compensation of marine winch based on hybrid neural network prediction and sliding mode controller with a high-gain observer. Ocean Engineering322: 120448.
19.
LiWZhangJXuW (2024b) High-speed multihull anti-pitching control based on heave velocity and pitch angular velocity estimation. ISA Transactions146: 380–391.
20.
LinaroDBizzarriFGiudiceD, et al. (2023) Continuous estimation of power system inertia using convolutional neural networks. Nature Communications14(1): 4440.
21.
MarlantesEKBandykJPMakiJK (2024) Predicting ship responses in different seaways using a generalizable force correcting machine learning method. Ocean Engineering312: 119110.
22.
MathewMArunkumarLAdvaitT, et al. (2025) Oscillating activation functions can improve the performance of convolutional neural networks. Applied Soft Computing175: 113077.
23.
QiangHQiaoSHuangH, et al. (2025) Nonlinear adaptive control of maglev system based on parameter identification. Actuators14(3): 115–115.
24.
RichterMSchautSWalserD, et al. (2017) Experimental validation of an active heave compensation system: Estimation, prediction and control. Control Engineering Practice66: 1–12.
25.
TranCØveraasHJohansenT (2024) ROV recovery with wave-motion compensation using model predictive control. Ocean Engineering293: 116764.
26.
VaswaniAShazeerNParmarN, et al. (2017) Attention is all you need. In: 31st conference on neural information processing systems (NIPS 2017), Long Beach, CA, 4 December.
27.
WangWNingYZhangY, et al. (2025a) Linear active disturbance rejection control with linear quadratic regulator for Stewart platform in active wave compensation system. Applied Ocean Research156: 104469.
28.
WangYLuXGaoY, et al. (2025b) An anti-swing control method combining deep learning prediction models with a multistate fractional-order terminal sliding mode controller for wave motion compensation devices. Mechanical Systems and Signal Processing223: 111819.
29.
WangZGuanLWangG, et al. (2025c) R-OFFlow: An optical flow motion estimation method guided by offset fields for self-compensation of ladder jitter in offshore wind turbine boarding. IEEE Transactions on Instrumentation and Measurement74: 1–13.
30.
WoodacreJBauerRIraniR (2018) Hydraulic valve-based active-heave compensation using a model-predictive controller with non-linear valve compensations. Ocean Engineering152: 47–56.
31.
ZhangJLuWLiJ, et al. (2024) A data-driven methodology for wave time-series measurement on floating structures. Ocean Engineering303: 117629.
32.
ZhangQHeJGuB, et al. (2025) Hilbert-Huang time-delay compensation control strategy based on gauss-DeepAR for ship heave motion prediction. China Ocean Engineering39: 209–224.
33.
ZhangQWangXZhangZ, et al. (2023) Wave heave compensation based on an optimized backstepping control method. China Ocean Engineering36(6): 959–968.
