Adaptive control of power electronic drives for servomechanical
... a transportation system. The advantages and engineering challenges of operating this type of coupling and the associated drive circuitry over a range of power levels and applications have been reviewed in numerous publications, including [4]–[9], among others. In [10]–[12], we exploited large-signal ...
... a transportation system. The advantages and engineering challenges of operating this type of coupling and the associated drive circuitry over a range of power levels and applications have been reviewed in numerous publications, including [4]–[9], among others. In [10]–[12], we exploited large-signal ...
an efficient locomotion system for autonomous robots
... hardware to be simplified to reduce costs. An embedded system is not always a separate block, very often it is physically built-in to the device it is controlling. A microcontroller is a highly integrated chip which includes, on one chip, all or most of the parts needed for a controller. In contrast ...
... hardware to be simplified to reduce costs. An embedded system is not always a separate block, very often it is physically built-in to the device it is controlling. A microcontroller is a highly integrated chip which includes, on one chip, all or most of the parts needed for a controller. In contrast ...
Capacitor bank controllers
... The control shall report via unsolicited messaging for state change The control can report via unsolicited messaging for when the control is tracking voltage, VAR, voltage, current, temperature, or neutral current fault condition. 1.7.9. The control shall provide an unsolicited report of the reason ...
... The control shall report via unsolicited messaging for state change The control can report via unsolicited messaging for when the control is tracking voltage, VAR, voltage, current, temperature, or neutral current fault condition. 1.7.9. The control shall provide an unsolicited report of the reason ...
April 2007 - CEME Logo Research Projects by Area
... The objective is to develop a control methodology for a DFIG that can achieve: – Variable speed and reactive power control – Compensation of problems caused by an unbalanced grid ...
... The objective is to develop a control methodology for a DFIG that can achieve: – Variable speed and reactive power control – Compensation of problems caused by an unbalanced grid ...
1.Introduction
... used in the control. Also, the coupling effect of the d–q current control was removed since the nonlinearity of the system was completely eliminated in theory. By adding integrators to the exact feedback linearization, the zero tracking errors were made, even in the presence of parameter perturbatio ...
... used in the control. Also, the coupling effect of the d–q current control was removed since the nonlinearity of the system was completely eliminated in theory. By adding integrators to the exact feedback linearization, the zero tracking errors were made, even in the presence of parameter perturbatio ...
Motor Control Centers - A117 North American IC Catalog
... starting and stopping, limitation of the inrush current, and reduction of the effects of water hammer in pumping systems. Allen-Bradley medium voltage SMC Flex controllers include motor protection, communication and diagnostic capabilities, and high flexibility, making it ideal for virtually any app ...
... starting and stopping, limitation of the inrush current, and reduction of the effects of water hammer in pumping systems. Allen-Bradley medium voltage SMC Flex controllers include motor protection, communication and diagnostic capabilities, and high flexibility, making it ideal for virtually any app ...
Distributed control system
A distributed control system (DCS) is a control system for a process or plant, wherein control elements are distributed throughout the system. This is in contrast to non-distributed systems, which use a single controller at a central location. In a DCS, a hierarchy of controllers is connected by communications networks for command and monitoring.Example scenarios where a DCS might be used include: Chemical plants Petrochemical (oil) and refineries Boiler controls and power plant systems Nuclear power plants Environmental control systems Water management systems Metallurgical process plants Pharmaceutical manufacturing Sugar refining plants Dry cargo and bulk oil carrier ships Formation control of multi-agent systems