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Modeling electric machines is one of the powerful approaches for analyzing their performance. A dynamic model and a steady-state model are introduced for each electric machine. Permanent magnet induction machine (PMIM) is a dual-rotor electric machine, which has various advantages such as high-power factor and low magnetizing current. Studying PMIM and its modeling might be valuable. The purpose of this paper is to introduce a simple and accurate method for dynamic and steady-state modeling of PMIM.

In this paper, arbitrary dqo reference frame is used to model PMIM. First, three-phase dynamic equations of stator and rotors are introduced. Then, they are transferred to an arbitrary reference frame. The voltage and magnetic flux equations aligned at dqo axes are obtained. These equations give the dynamic model. To investigate the results, PMIM simulation is performed according to obtained dynamic equations. Simulation results verify the analytic calculations.

In this paper, dynamic equations of PMIM are obtained. These equations are used to determine dynamic equivalent circuits of PMIM. Steady-state equations and one phase equivalent circuit of the PMIM using phasor relations are also extracted.

PMIM equations along dqo axes and their dynamic and steady-state equivalent circuits are determined. These equations and the equivalent circuits can be transformed to different reference frames and analyzed easily.

This article presents a general equilibrium model capable of assessing the impact of foreign price shocks on the real side of the oil‐based developing economies. The theoretical model departs from previous work in this area at least in that (1) the model takes into account endogenous income and price responses in all sectors of the economy; (2) it has two traded goods (exports and imports) and a non‐traded good; (3) it explicitly addresses the inherent open and small economic nature of developing countries; and (4) besides adjustments in the endogenous domestic prices, the model also allows for other structural adjustments. As such, the model combines the neoclassical macro theory with the structural micro approach. Empirical evidence deduced from an important oil‐based developing economy (Saudi Arabia) appears quite consistent with the model theoretical implications.

CASTORING stability requires automatic return, after displacement, of the castoring wheel to the central position. A hinged wheel may be automatically stable under static conditions, but dynamically unstable, or vice versa. Dynamic stability may be defined as the condition in which the forces on the wheel in motion secure its return to the path of direction of motion.

Using the weighted similarity coefficient (WSC) technique in the design of manufacturing facilities provides the system designer with a suitable method for the creation of efficient manufacturing cells. The formation of such well designed machine cells will then hopefully ensure that the achievable cost reduction benefits, in terms of lower operational costs incurred via the transfer of components between machines, are obtained by companies that wish to use cellular manufacturing in their approach to production operations. The aim of this paper is to outline and evaluate the application of a particular WSC equation to the formulation and design of cellular manufacturing systems.

By using a pragmatic approach, the paper chronicles the design and development of a particular weighted similarity coefficient as a means of defining a possibly useful methodology for cell design in manufacturing systems. The technique outlined is subsequently evaluated for its generic nature, applicability and effectiveness via the use of previously published synthetic production data and a comparison with the results of several alternative approaches.

The development of the proposed weighted similarity coefficient to manufacturing cellular design is outlined in the paper and the appropriateness of the technique is subsequently evaluated in order that the benefits obtainable by its use to a host organisation are highlighted. In addition, the results show how the approach can lead to useful improvements in cellular manufacturing performance if adopted by manufacturing system designers and implemented in their designs.

The design, development and application of the WSC proposed and its use in manufacturing cellular design provides a simple yet highly effective approach to achieving useful improvements in production system performance through improved work‐part transfer efficiency and associated cost savings. The paper offers practising manufacturing managers and engineers a technique whereby manufacturing cell productive efficiency and output can be improved whilst at the same time achieving a reduction in operational costs.

The paper focuses on the proposed WSC technique which contributes to the existing knowledge base on production cell design and may also provide impetus, guidance, support and encouragement for designers to achieve improved output performance and reduced costs in their manufacturing system designs.