150results about How to "Avoid Compensation Errors" patented technology

A double-input and double-output NDCS unknown time delay hybrid control method belongs to the technical field of a multiple-input and multiple-output NDCS having a limited bandwidth resource. A method using a real network data transmission process between all nodes in a TITO-NDCS to replace a network time delay compensation model between the nodes is brought forward aiming at the problems that, for the TITO-NDCS double input signals and double output signals of which are influenced and coupled with each other and which needs decoupling processing, stability of each closed-loop control circuit is influenced, stability of the whole system is influenced and that even loss of stability of the TITO-NDCS is resulted in due to network time delay of network data during transmission between the nodes. SPC and IMC are separately applied to a circuit of the TITO-NDCS. Measurement, estimation or identification of the network time delay between the nodes can be avoided, a clock signal synchronization requirement is reduced, an influence of a network uncertain time delay on TITO-NDCS stability is lowered, and the control performance quality of the system is improved.

The invention provides an improved adaptive droop control method for a hybrid energy storage system in a DC micro-grid and relates to the stable running field of the DC micro-grid. The method is characterized in that, based on the improved hybrid energy storage system in the DC micro-grid, a lithium battery is connected with a DC bus through a DC/DC converter I. A super capacitor is connected with the DC bus through a DC/DC converter II. In this way, a hybrid energy storage system of a parallel connection structure is formed. According to the technical scheme of the invention, the effective energy compensation problem of the lithium battery for the super capacitor of the hybrid energy storage system in the DC micro-grid can be is effectively solved. Meanwhile, an improved adaptive droop control method is provided for the hybrid energy storage system in the DC micro-grid.

The invention provides a compensation method of random time-delay of the external forward and internal feedback paths of a network cascade control system, belonging to the technical field of the network control system. The method uses the actual external forward network path nodes of the network cascade control system and adopts the network data transmission process between the internal feedback network path nodes to replace the compensation model of network time-delay between the nodes, avoid the measurement, observation, estimation or identification of the network data transmission random time-delay between the nodes and remove the synchronization requirement on the node clock signal. By adopting the method, the influence of the random network time-delay on the system stability can be reduced and the performance quality of system control can be imprved. The method of the invention is suitable for the dynamic compensation and control of random network time-delay when the mathematicalmodels of the main controlled object and auxiliary controlled object are known and the network only exists in the external forward and internal feedback paths of the cascade control system.

The invention belongs to the technical field of bandwidth resource limited MIMO-NCSs (multiple-input multiple-output networked control systems) and relates to a two-input two-output networked control system delay compensation SPC (smith predictor control) and IMC (internal model control) method. In order to solve the problems that two-input two-output signals in a TITO-NCS (two-input two-output networked control system) have mutual effect, network delay due to the transmission of network data between nodes affects the stability of one closed-loop control circuit of the system and may also affect the stability of another closed-loop control circuit while even stability loss is caused to the TITO-NCS, it is presented that an inter-node network delay compensation model is replaced by network data transmission process between all true node s in the TITO-NCS, with dynamic feedforward as well as SPC and IMC applied to the two circuits; by using the method of the invention, it is possible to omit the measurement, estimation or identification of inter-node network delay, omit the requirement on node clock signal synchronization, reduce the effect of network delay upon TITO-NCS stability, and improve the control performance quality of the system.

The invention provides a time-varying network time delay compensation method of a forward access of a networked cascade control system (NCCS), belonging to the technical field of networked control system. In the method, a network data transmission process among forward access nodes is used instead of a network time delay compensation model among the forward access nodes so as to avoid measurement, observation, estimation or recognition of time-varying time delay when network data among the real forward access nodes are transmitted and prevent the requirements of synchronization of node clock signals. By using the method, the influence of the time-varying network time delay on the stability of a system can be reduced and the control performance quality of the system can be improved. The method is suitable for dynamic compensation and control of the time-varying network time delay when a network only exists in the forward access of the networked cascade control system under the condition that a mathematical model of a main controlled object is known or uncertainly known, a mathematical model of a vice controlled object is known, and certain interference signals exist in the system.

The invention provides a compensation method for unknown network delay of a network cascade control system, belonging to the technical field of network control systems. The method adopts a network data transmission process among all forward and feedback network path nodes of the actual network cascade control system to replace a network delay compensation model thereof, avoids measurement, observation, estimate or identification for unknown delay of network data transmission among the nodes, and also avoids the synchronization requirement on node clock signals. The method can reduce the influence of unknown network delay on stability of the system and improve the control performance quality of the system. The method is suitable for dynamically compensating and controlling unknown network delay in all forward and feedback network paths of network simultaneously existing in the network cascade control system, when mathematical models of main auxiliary controlled objects are known or unknown, the system has unknown interference, and the network exists a certain amount of data packet losses.

The invention provides a network delay compensation method between a transmitter node and a (control) actuator node, and belongs to the technical field of network control systems. In the method, an actual network data transmission process between the transmitter node and the (control) actuator node is used for substituting a network delay compensation model of the process, so that measurement and estimation or identification of network data transmission delay between nodes and requirements on node clock signal synchronization are eliminated. By the method, the influence of delay on stability of a time system can be reduced and the control performance quality of the system can be improved. The method is suitable for delay dynamic compensation and control of a network control system in which a controlled object mathematic model is known, the network only exists between the transmitter node and the (control) actuator node and a certain number of data packets are lost in the network.

The invention discloses a random time delay compensation method for a TITO-NDCS (two-input and two-output networked decoupling control system) and belongs to the technical field of multiple-input and multiple-output networked decoupling control systems with limited bandwidth resources. As for the TITO-NDCS with two-input and two-output signals mutually affected and coupled requiring decoupling, in consideration that network time delay generated in a transmission process of network data among nodes affects stability of respective closed-loop control loops and the whole system and even leads to that the TITO-NDCS loses stability, the method for substituting a network data transmission process among all real nodes in the TITO-NDCS for a network time delay compensation model is put forward, so that measurement, estimation or identification of the network time delay among the nodes can be avoided, requirements on clock signal synchronization are lowered, influences of random time delay on stability of the TITO-NDCS are lowered and system control performance quality is improved.

The invention provides a long delay compensation method for two-input and two-output networked decoupling control systems, and belongs to the technical field of bandwidth resource limited MIMO-NDCS. Aiming at the problems of loss of stability of TITO-NDCS and influencing the stability of each closed control loop and influencing the stability of the whole system due to network delay generated by transmission of network data between nodes in the TITO-NDCS in which two-input and two-output signals are mutually influenced and coupled and require to be decoupled, the method that the network data transmission process between all the real nodes in the TITO-NDCS replaces a network delay compensation model is put forward, and SPC and IMC are performed on the two loops respectively so that measurement, estimation or identification of the network delay between the nodes can be omitted, the synchronization requirement of clock signals can be reduced, the influence of long delay on the stability of the TITO-NDCS can be reduced and the system control quality can be improved.

The invention discloses a chattering restraining method of optical axis of a rapid deflecting mirror based on a support vector machine. The chattering restraining method comprises the steps that modeling and identifying of rapid deflecting mirror linear dynamics are carried out, data collecting and processing are carried out, piezoelectric drive rapid deflecting mirror nonlinear hysteresis dynamics modeling is carried out, and the feed-forward feedback composite controller design of rapid deflecting mirror nonlinear hysteresis dynamics is carried out. Compared with the prior art, the chattering restraining method of the optical axis of the rapid deflecting mirror based on the support vector machine does not need parameter identifying of a specific hysteresis model, an accurate inverse piezoelectric hysteresis model is established based on an LS-SVM method and used for compensating the influence on the control precision of piezoelectric drive rapid deflecting mirror by the nonlinear hysteresis effect, and introducing compensating errors introduced by model parameter identifying is avoided; and meanwhile, a pruning method of support vector is designed to reduce model complexity and calculation time-consumption, the support vector of the model is removed, and the model identifying process is simplified; and on the basis of piezoelectric nonlinear hysteresis feed-forward compensating, feedback control is carried out on linear dynamics partial design of the piezoelectric drive rapid deflecting mirror, and control precision of the system is improved.

The invention provides a network delay compensation method of two-input and two-output networked decoupling control systems (TITO-NDCS), and belongs to the technical field of bandwidth resource limited MIMO-NDCS. Aiming at the problems of loss of stability of the TITO-NDCS and influencing the stability of respective closed control loops and influencing the stability of the whole system due to network delay generated by the transmission process of network data between nodes in the TITO-NDCS in which two-input and two-output signals are mutually influenced and coupled and require to be decoupled, the method that the network data transmission process between all the real nodes in the TITO-NDCS replaces a network delay compensation model is put forward so that measurement, estimation or identification of the network delay between the nodes can be omitted, the synchronization requirement of clock signals can be reduced, the influence of the network delay on the stability of the TITO-NDCS can be reduced and the control performance quality of the system can be improved.

The invention discloses a time-varying time delay compensation method for a TITO-NDCS (two-input and two-output networked decoupling control system) and belongs to the technical field of multiple-input and multiple-output networked decoupling control systems with limited bandwidth resources. As for the TITO-NDCS with two-input and two-output signals mutually affected and coupled requiring decoupling, in consideration that network time delay generated in a transmission process of network data among nodes affects stability of respective closed-loop control loops and the whole system and even leads to that the TITO-NDCS loses stability, the method for substituting a network data transmission process among all real nodes in the TITO-NDCS for a network time delay compensation model is put forward, so that measurement, estimation or identification of the network time delay among the nodes can be avoided, requirements on clock signal synchronization are lowered, influences of time-varying time delay on stability of the TITO-NDCS are lowered and system control performance quality is improved.

A compensation method for long network time delay of a TITO-NDCS belongs to the technical field of an MIMO-NDCS with limited bandwidth resource. In the TITO-NDCS in which two input signals and two output signals affect one another and are coupled and decoupling processing is required, because of network delay generated in a network data transmission process between nodes, not only is stability of a respective closed control loop reduced, but also stability of the whole system is reduced, and even un-stability of the TITO-NDCS is caused. According to the method of the invention, a network data transmission process between all real nodes in the TITO-NDCS replaces a network time delay compensation model between the nodes, and furthermore two-freedom IMC and SPC are applied to two loops, thereby avoiding measurement, estimation or identification for network time delay between the nodes, reducing a clock signal synchronization requirement, reducing effect of the long network time delay to stability of the TITO-NDCS, and improving system control quality.

The invention provides a two-input two-output NDCS unknown time delay compensation and IMC method and belongs to the technical field of bandwidth resource limited multiple-input-multiple-output networked decoupling control systems. For the TITO-NDCS, where two-input and two-output signals are mutually influenced and coupled, and need decoupling processing, since network delay of network data generated in the inter-node transmission process not only influences stability of each closed-loop control loop, but also influences stability of the whole system, or even causes loss of stability of the TITO-NDCS, a method of using a real network data transmission process between all nodes in the TITO-NDCS to replace network delay compensation models is proposed, and IMC is carried out on loops thereof, thereby avoiding measurement, estimation or identification of network delay between nodes, reducing requirement for clock signal synchronization, reducing influence of unknown time delay on stability of the TITO-NDCS, and improving quality of control performance of the system.