本文采用两阶离散MIMO(Multi 1nput Multi Output)动态模型描述生化反应过程的动态行为,并以青霉素重复流加发酵为例,借助于计算机在线检测系统,在40,000L大罐上进行参数辨识与多变量自校正控制仿真研究。结果表明:该控制策略能够克服...本文采用两阶离散MIMO(Multi 1nput Multi Output)动态模型描述生化反应过程的动态行为,并以青霉素重复流加发酵为例,借助于计算机在线检测系统,在40,000L大罐上进行参数辨识与多变量自校正控制仿真研究。结果表明:该控制策略能够克服噪声和过程不确定性影响,使发酵沿最优轨迹进行,实现跟踪优化控制。展开更多
The advances in MIMO systems and networking technologies introduced a revolution in recent times, especially in wireless and wired multi-cast (multi-point-to-multi-point) transmission field. In this work, the distribu...The advances in MIMO systems and networking technologies introduced a revolution in recent times, especially in wireless and wired multi-cast (multi-point-to-multi-point) transmission field. In this work, the distributed versions of self-tuning proportional integral plus derivative (SPID) controller and self-tuning proportional plus integral (SPI) controller are described. An explicit rate feedback mechanism is used to design a controller for regulating the source rates in wireless and wired multi-cast networks. The control parameters of the SPID and SPI controllers are determined to ensure the stability of the control loop. Simulations are carried out with wireless and wired multi-cast models, to evaluate the performance of the SPID and SPI controllers and the ensuing results show that SPID scheme yields better performance than SPI scheme;however, it requires more computing time and central processing unit (CPU) resources.展开更多
文摘本文采用两阶离散MIMO(Multi 1nput Multi Output)动态模型描述生化反应过程的动态行为,并以青霉素重复流加发酵为例,借助于计算机在线检测系统,在40,000L大罐上进行参数辨识与多变量自校正控制仿真研究。结果表明:该控制策略能够克服噪声和过程不确定性影响,使发酵沿最优轨迹进行,实现跟踪优化控制。
文摘The advances in MIMO systems and networking technologies introduced a revolution in recent times, especially in wireless and wired multi-cast (multi-point-to-multi-point) transmission field. In this work, the distributed versions of self-tuning proportional integral plus derivative (SPID) controller and self-tuning proportional plus integral (SPI) controller are described. An explicit rate feedback mechanism is used to design a controller for regulating the source rates in wireless and wired multi-cast networks. The control parameters of the SPID and SPI controllers are determined to ensure the stability of the control loop. Simulations are carried out with wireless and wired multi-cast models, to evaluate the performance of the SPID and SPI controllers and the ensuing results show that SPID scheme yields better performance than SPI scheme;however, it requires more computing time and central processing unit (CPU) resources.
