2024-03-29T17:55:40+03:30
http://joc.kntu.ac.ir/browse.php?mag_id=15&slc_lang=fa&sid=1
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Error Analyses of Inertial Navigation System Based on Only Accelerometers and Without Gyroscope
Vahid
ghasemzadeh
ghvahid61@yahoo.com
Jafar
Heyrani Nobari
nobari@eetd.kntu.ac.ir
current inertial navigation systems usually use liner accelerometer and gyroscopes to sense linear accelerations and angular velocity, respectively. The gyroscopes have the disadvantage such as: complicated manufacture technique, high cost, and large volume and so on. Due to these factors the small accelerometers with low cost to replace the gyroscopes in some inertial navigation systems.
In this paper a ten-accelerometer configuration is proposed which can determine linear acceleration an angular velocity completely. The advantages of this method in comparison with previous works are the simplicity of the equations and elimination of direct integration of angular acceleration.
Actual accelerometers have errors such as bias and misalignment which have significant effect on precision of inertial navigation systems. So, these errors and their effect on navigation are considered in modelling and simulation. The obtained results of simulation show that this method has suitable precision in short time navigation systems.
Inertial navigation
gyroscope
accelerometer
bias
misalignment
2011
12
01
1
10
http://joc.kntu.ac.ir/article-1-78-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Presentation of an approximate method for the design of decoupler and study the compromise in two-step design method using decoupler and sequential loop closing for stable linear multivariable systems
Ghasem
Kerchi
kerchi@ikiu.ac.ir
Aref
Shahmansoorian
shahmansoorian@ikiu.ac.ir
In this paper a new method to design dynamical decoupler is presented. This method is based on drawing the frequency characteristic of decoupler and its estimation by using of a proper, stable and causal transfer function in a determined frequency range.Then has been discussed about the relationship between design decoupler and controller and its role in reducing the interactions of loops. Finally the sequential loop closing method with relay test and PID controllers is combined with the proposed decoupler design method. Successful results of this method in decoupling the multivariable system is shown with simulation.
MIMO
Decoupler
Sequential design
Relay test
PID
2011
12
01
11
23
http://joc.kntu.ac.ir/article-1-79-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Comparison the State Vector Fusion Methods for Data Fusion in Multi Sensors Networks
Bijan
Moaveni
b_moaveni@iust.ac.ir
Shima
Rouhi
shimarouhi@yahoo.com
In this paper, we compare the performance of state vector fusion methods for data fusion of multi sensors networks by comparing the estimation errors covariance. Here, we represent the three main state vector data fusion methods and we prove the equivalency of the estimation error covariance matrices corresponding to these three methods. In last part of the paper, the simulation results are presented to show the effectiveness of the theoretical results. Also, we analyze the computational load of these three methods by simulation analysis.
Multi-Sensor Data Fusion
State Vector Fusion
Kalman Filter
Estimation Error Covariance.
2011
12
01
24
35
http://joc.kntu.ac.ir/article-1-80-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Guidance Law Design using Finite Time Second Order Sliding Mode Control
Vahid
Behnam Gol
vahidbehnamgol@yahoo.com
Iman
Mohammad Zaman
mohammadzaman@modares.ac.ir
AhmadReza
Vali
vali@mut.ac.ir
Nemat Allah
Ghahramani
ghahramani@aut.ac.ir
In this paper, a two point guidance law for homing interceptors using finite time second order sliding mode control and based on parallel navigation is proposed. In the proposed guidance law, sliding surface is selected as the line of sight rate and the target maneuvers are considered as an uncertainty which only needs the upper bound of these maneuvers. Furthermore, the proposed algorithm can guarantee the finite time convergence of the LOS rate to zero or a small neighborhood of zero. Therefore, the performance and stability of guidance loop against maneuvering targets are increased.
guidance law
parallel navigation
second order sliding mode
finite time control.
2011
12
01
36
44
http://joc.kntu.ac.ir/article-1-81-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Assessment and Robust Controller Design of STATCOM for Power System Stability Improvement Using Honey Bee Mating Optimization
Masoud
Aliakbar Golkar
golkar@kntu.ac.ir
Ali
Ahmadian
ali.ahmadian1367@gmail.com
Amin
Safari
asafari1650@yahoo.com
Damping of low-frequency electro-mechanical oscillation is very important for the system secure operation. The fast acting, FACTS device which is capable of improving both steady state and dynamic performance permit newer opproaches to system stabilization. In this paper, presents a novel approach for designing of damping controller for STATCOM in order to enhance the damping of power system low frequency oscillations(LFO). Based on Phillips-heffron model linearization, problem of damping controller design considered as an optimizing problem of multi purpose with criterion function and it is solved with utilizing honey bee mating optimization algotithm. To validate the accuracy of results a comparison with GA has been made. This controller is designed in order to transmit unstable electromechanical modes to specific area of complex plane. The proposed controller performance is confirmed by analysis of eigenvalue and nonlinear time-domain simulation under various disturbances with both control parameter of STATCOM( capacitor voltage control and terminal voltage control). Simulation results illustrate that design of controller based of capacitor voltage control in comparison with terminal voltage control has better low frequency oscillation damping and it increases dynamical stability of power system.
Honey Bee Mating Optimization
power system stability
power oscillation Damping
STATCOM
multiple optimization
2011
12
01
45
56
http://joc.kntu.ac.ir/article-1-83-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Time Optimal Trajectory Planning For a High Speed Planing Boat
Mohammad Taghi
Ghorbani
mt_ghorbani@mehr.sharif.ir
Hasan
Salarieh
salarieh@sharif.ir
Nima
Assadian
assadian@sharif.ir
In this paper, the problem of trajectory planning for a high speed planing boat with the aim of time optimization under nonlinear equality and inequality constraints is addressed. First, a nonlinear mathematical model of the craft dynamic and then the Hamiltonian boundary value problem (HBVP) equations are derived. The problem is solved using nolinear programming by discretizing the control time history and adjoining the constraints to the cost function via Linear Extended Penalty Function (LEPF) method. The Steepest Descent (SD) approach is used to solve this nonlinear programming. Some examples of boat minimum time maneuver are presented to demonstrate the effectiveness of the approach for designing optimal maneuvers
High Speed Planing Boat
Trajectory Optimization
Hamiltonian Boundary Value Problem
Steepest Descent Approach
Linear Extended Penalty Function Method.
2011
12
01
57
68
http://joc.kntu.ac.ir/article-1-82-en.pdf
Journal of Control
JoC
2008-8345
2538-3752
10.52547/joc
2011
5
3
Designing Minimum Variance Controller using VARX Model
Yusef
Alipouri
alipouri_yousef@elec.iust.ac.ir
Javad
Poshtan
jposhtan@iust.ac.ir
In most industrial applications, attaining minimum output variance certifies the efficiency of system and results in increasing productivity and decreasing energy consuming. Therefore, minimum variance index is considered as one of the main subjects in control engineering field. A minimum variance controller is an optimal controller that provides (theoretically) the minimum possible variance. Designing this controller, however, requires exact models of both the system and disturbance. Due to existence of interactions among loops, modeling MIMO systems is often complicated. Existence of disturbance is another reason for this complication. In this paper, in order to avoid the need for an analytical model of system, VARX model has been used to simultaneous identification of the plant and disturbance. Then, the estimated model is used for designing a minimum variance controller. In this method, operating data of inputs and outputs of the system are the only requirements for identification of the VARX model. The proposed method has been tested on an experimental benchmark such as a four-tank system which has a nonlinear behavior. The investigation results show that a minimum variance controller can be designed, based on an identified VARX model, for a MIMO system, without any need for an exact model of the system, while at the same time, capable of providing an acceptable minimum variance compared to that precisely obtained using the model-based “Interactor-Matrix” method.
Minimum variance controller
VARX model
Modeling plant and disturbance
Time series method
Quadruple-tank benchmark.
2011
12
01
69
80
http://joc.kntu.ac.ir/article-1-84-en.pdf