1. البحث السابع بحث منفرد منشور فى مؤتمر دولى متخصص (منشورة التحكيم علي البحث الكامل)
Adel A. Elbaset
13th International Middle East Power System Conference, MEPCON'2009, Assuit University, Faculty of Eng., Assuit, Egypt, Dec , 2009 

2. Modeling and Computer Simulation of Fault Calculations for Transmission Lines  نمذجة ومحاكاة لحساب قيم الأخطاء في خطوط النقل الهوائية

3. ملخص البحث باللغة العربية
حساب قيم الأخطاء التي تقع علي خط النقل له أهمية أساسية في الكشف عن الخطأ وتصنيف الخطأ وتحديد مكانه في خط النقل.
يقدم هذا البحث مقترح برنامج كمبيوتر بإستخدام الماتلاب لحساب قيم جميع الأخطاء التي قد تحدث في خط النقل مع الأخذ في الإعتبارنوع الخطأ، ومكان الخطأ ومقاومة الخطأ.
مدخلات البرنامج المقترح عبارة عن طول الخط ، وجهد المصدر، ومقاومة الخط والمصدر
. وتستخدم مخرجات البرنامح لتدريب شبكات الذكاء الاصطناعي للكشف عن الخطأ وتصنيفه وتحديد مكان العطل. البرنامج المقترح تم تطبقه علي خط نقل معروف وأوضحت النتائج مدي فاعليه الطريقه المقترحه.

4. To implement a novel application of ANFIS approach to fault detection, classification and location in transmission lines a proposed computer program based on Matlab software to calculate all ten types of shunt faults that may occur in a transmission line should be presented first.
This work divided into two papers
The first paper concerns with Transmission Lines Fault Calculations
The second paper concerns with Fault Detection and Classification in Transmission Lines Using ANFIS

5. In the first paper: Part I
This paper presents a proposed computer program based on Matlab software to calculate all ten types of shunt faults that may occur in a transmission line.
Various fault scenarios (fault types, fault locations and fault impedance) are considered in this paper.
The inputs of the proposed program are line length, source voltage, positive, negative and zero sequence for source impedance, line charging, and transmission line impedance.
The output of the algorithm is used to train an artificial intelligence networks to detect, classify and locate transmission lines faults. Simulation results have shown the effectiveness of the algorithm under the condition of all types of shunt faults.
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6. The first ANFIS has been proposed to detect all shunt faults.
In the Second paper: Part II
Presents a novel application of ANFIS approach to fault detection, classification and location in transmission.
Three ANFIS’s have been proposed to provide an integrated protective scheme for the transmission line.
The first ANFIS has been proposed to detect all shunt faults.
The second ANFIS has been proposed to identify the type of faults.

7. Figure 2. Single-line-to-ground fault at point F
Methodology
Figure 1. Faulted Transmission Line
The fault formula for balanced and various unbalanced faults are summarized below:-
II-I Modeling of SLG Faults Using Zbus
Figure 2. Single-line-to-ground fault at point F

8. The conditions at the fault bus 3 (point F) are expressed by the following equations:-
Ifb=0 , Ifc= (1)
The following equations give relationships between sequence components of fault currents at the fault point.
The fault line current at bus 3 can be calculated as follows [2,3,4,5]:
VPref(0): The prefault voltage at point F (bus 3) and can be calculated by using two port network as shown in Fig. 3

9. Figure 3. Power system in SLG fault

10. The symmetrical components of fault current is
II-III Modeling of DL Faults Using Zbus [2,5]
(15)
Figure 4. Double line fault at point F
The following relations must be satisfied at the fault point
Ifa=0 , Ifb= -Ifc
The symmetrical components of fault current is

11. Figure 5. Double line to ground fault at point F
II-III Modeling of DLG Faults Using Zbus [2,5]
Figure 5. Double line to ground fault at point F
The symmetrical components of fault current is

12. Figure 6. A balanced three-phase fault at point F
The fault line currents can be obtained from Equation
Where T is known as symmetrical components transformation matrix
II-IV Modeling of three-phase Faults Using Zbus
Figure 6. A balanced three-phase fault at point F

13. The symmetrical components of fault current are given by the following Equation:-
The fault line currents can be obtained from Equation (6)
II-V Modeling of Sending Voltage and Line current during Fault [5]
Using sequence components of the fault currents the symmetrical components of the sending end bus voltage during fault can be obtained by the following Equations

14. Where Z1, Z2 and Z0 : The matrix impedance of transmission line per unit length.
Vsa (0): The prefault phase voltage at sending end. The phase voltages at sending end during fault are

15. The symmetrical components of fault current in line 1 to 3 is given by
The line fault currents from Bus 1 to Bus 3 (point F) can be obtained as follows:-

16. Computer Simulation of Fault Calculation
The flow chart of the proposed computer program is shown in Fig. 7. The proposed computer program simulates various faults for different fault conditions. i.e. a-g, b-g, c-g, ab, bc, ca, ab-g, bc-g, ca-g, and abc fault) based on Zbus. The condition parameters that have been taken into account for each fault type are:
1) Variation of fault impedance, [0: 200] (Ω).
2) Variation of fault angle, [0: 90] (degree).
3) Variation fault locator [1:200] km.

18. Application and Results
The faulted transmission line is represented by distributed parameters. As an application, a 200 km overhead transmission line with the parameters of the transmission line model of Fig. 1 is as follows
Source voltages:
Source S: V1 = 400 kV; source R: V2 = 400 kV.
Source impedance (both sources):
Positive sequence impedance = j15.0;
Zero sequence impedance = j26.6;
Frequency = 50 Hz;
Transmission line impedance:
Positive sequence impedance = j94.5;
Zero sequence impedance = j308;
Positive sequence capacitance = 13 nF/km;
Zero sequence capacitance = 8.5 nF/km.
The significant parameters above are selected based on in real operations [8].

19. Influence of the Fault Distance and Fault Impedance
Figure 8. Influence of Fault Impedance, Fault distance at Fault current For Single Line-to-ground Fault at =10o.

20. Figure 9. Influence of Fault Impedance, Fault distance at Fault voltage For DLG Fault at =10o

21. Figure 10. Influence of Fault Impedance and Fault distance at Fault current
For DL Fault at =10o.

22. For Three phase Fault at =10o.
Figure 11. Influence of Fault Impedance, Fault distance at Fault current
For Three phase Fault at =10o.

23. Three phase Fault at =10o
Figure 15. Influence of Fault Impedance, Fault distance at Fault voltage For
Three phase Fault at =10o

24. Figure 25. Influence of Fault distance and Fault inception angle at
Fault current For DLG Fault at Zf =30 ohm.

25. Figure 20. Influence of Fault Impedance and Fault distance at
Fault voltage For SLG Fault at Lf =5km.

26. Figure 21. Influence of Fault Impedances and Fault distance at
Fault voltage For DLG Fault at Lf =5km.

27. Figure 22. Influence of Fault Impedance and Fault
distance at Fault voltage For DL Fault at Lf=5km.

28. Figure 27. Influence of Fault distance, Fault inception angle at
Fault current For Three phase Fault at Zf =30 ohm.

29. Figure 29. Influence of Fault distance and Fault
inception angle at Fault voltage For DLG Fault at Zf=30 ohm.

30. Conclusions
This paper presents a computer package to perform transmission line fault analysis based on Zbus methods along with the symmetrical components method. From the results obtained, the salient conclusions of this paper are:-
1. Calculates the fault conditions and to provide protective equipment designed to isolate the faulted zone from the reminder of the system in the appropriate time.
2. Presents a highly accurate transmission line simulation technique which utilized to calculate voltages and currents at the relay location (Sending end S) for different fault types, fault conditions and different power system data.
3. Calculate faults along different line lengths.
The results show that the method is suitable for design a protective scheme for transmission line based on artificial intelligence. As the method is easy applicable and it is flexible, it can be used for modeling other any transmission lines

31. Thanks for your attention and listening