中文摘要：

针对冠状动脉系统混沌同步问题,系统模型受到有界但未知的不确定干扰条件下,利用几何齐次性理论和积分滑模面设计高阶滑模自适应控制器,使响应系统在有限时间内跟踪驱动系统,该方法无需提前预知扰动边界.采用Lyapunov理论对闭环系统进行分析并证明该控制器保证该系统能够在有限时间内镇定,从仿真实验结果可以看出所设计的控制器在不确定干扰的情况下系统具有良好鲁棒性和未知参数的自适应性,为能够有效治疗心肌梗死等冠状动脉疾病提供了一定的理论依据.

英文摘要：

Many biomedical engineering fields are studied by combining with nonlinear science which has major advances in theoretical curing related diseases. The coronary artery system is chosen as a muscular blood vessel model. With the change of vessel diameter, some chaotic behaviors will occur which may cause complex diseases such as myocardial infarction.In order to avoid the undesired chaotic motion, this paper investigates the finite-time chaos synchronization problem for a coronary artery system by utilizting high-order sliding mode adaptive control method. First, the error chaos synchronization system is obtained using the master and slave systems. Second, the error chaos synchronization system can be transformed into an integrator chain system by coordinate transformation, which is equivalent to an error chaos synchronization system. Considering that the sliding mode control has main obstacle（the control high activity and chattering phenomenon）, a high-order sliding mode adaptive controller is designed for a coronary artery system with unknown disturbances at geometric homogeneity and integral sliding mode surface. The proposed method shows that the drive and response systems are synchronized and the states of the response system track the states of the drive system in finite-time. This approach does not require any information about the bound of disturbances in advance. Theoretic analysis based on Lyapunov theory proves that the systems with the proposed controller could be stabilized in finite-time.The convergence time of the system states is estimated. In order to alleviate the chattering effect, we use tanh（·） function in place of sign（·） function to design an improved high-order sliding mode adaptive controller. Simulation results show that the proposed adaptive sliding mode controller can achieve better robustness and adaptation against disturbances,which offer the theoretic basis for curing myocardial infarction.