Warsame H. Ali scite author profile

Load flow is an important tool used by power engineers for planning, to determine the best operation for a power system and exchange of power between utility companies. In order to have an efficient operating power system, it is necessary to determine which method is suitable and efficient for the system's load flow analysis. A power flow analysis method may take a long time and therefore prevent achieving an accurate result to a power flow solution because of continuous changes in power demand and generations. This paper presents analysis of the load flow problem in power system planning studies. The numerical methods: Gauss-Seidel, Newton-Raphson and Fast Decoupled methods were compared for a power flow analysis solution. Simulation is carried out using Matlab for test cases of IEEE 9-Bus, IEEE 30-Bus and IEEE 57-Bus system. The simulation results were compared for number of iteration, computational time, tolerance value and convergence. The compared results show that Newton-Raphson is the most reliable method because it has the least number of iteration and converges faster.

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Discrete-time chaotic-map truly random number generators: design, implementation, and variability analysis of the zigzag map

Nejati

Beirami

Ali

2012

Analog Integr Circ Sig Process

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In this paper, we introduce a novel discrete chaotic map named zigzag map that demonstrates excellent chaotic behaviors and can be utilized in Truly Random Number Generators (TRNGs). We comprehensively investigate the map and explore its critical chaotic characteristics and parameters. We further present two circuit implementations for the zigzag map based on the switched current technique as well as the current-mode affine interpolation of the breakpoints. In practice, implementation variations can deteriorate the quality of the output sequence as a result of variation of the chaotic map parameters. In order to quantify the impact of variations on the map performance, we model the variations using a combination of theoretical analysis and Monte-Carlo simulations on the circuits. We demonstrate that even in the presence of the map variations, a TRNG based on the zigzag map passes all of the NIST 800 − 22 statistical randomness tests using simple post processing of the output data.

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Fundamentals of Electric Machines

Ali¹,

Abood²,

Sadiku³

2019

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Digital Pid Controller Design for Delayed Multivariable Systems

Zhang

Shieh

Akujuobi

et al. 2004

Asian Journal of Control

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A new methodology is proposed to design digital PID controllers for multivariable systems with time delays. Except for a few parameters that are preliminarily selected, most of the PID parameters are systematically tuned using the developed plant state-feedback and controller state-feedforward LQR approach, such that satisfactory performance with guaranteed closed-loop stability is achieved. In order to deal with the modeling error owing to the delay time rational approximation, an IMC structure is utilized, such that robust stability is achieved, without need for an observer, and with improved online tuning convenience. Using the prediction-based digital redesign method, the digital implementation is obtained based on the above-proposed analog controller, such that the resulting mixed-signal system performance will closely match that of the analog controlled system. An illustrative example is given for comparison with alternative techniques.

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Warsame H. Ali

Load Disturbance Resistance Speed Controller Design for PMSM

Analysis of the Load Flow Problem in Power System Planning Studies

Discrete-time chaotic-map truly random number generators: design, implementation, and variability analysis of the zigzag map

Fundamentals of Electric Machines

Digital Pid Controller Design for Delayed Multivariable Systems

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