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diff --git a/3760/CH3/EX3.11/Ex3_11.sce b/3760/CH3/EX3.11/Ex3_11.sce
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+clc;

+d=0.28; // air gap diameter

+l=0.23; // core length of alternator

+spp=4; // slots per pole per phase

+b1=0.87; // amplitude of flux density in fundamental harmonic in Tesla

+b3=0.24; // amplitude of flux density in third harmonic in Tesla

+b5=0.14; // amplitude of flux density in fifth harmonic in Tesla

+p=6; // number of poles in alternator

+np=3; // number of phases

+c=8; // number of conductor per slot

+f=50; // frequency of supply

+f1=(2*d*l*b1)/p; // flux for fundamental harmonic

+f3=(2*d*l*b3)/(p*3); // flux for third harmonic

+f5=(2*d*l*b5)/(p*5); // flux for fifth harmonic

+ap=180/(spp*np); // slot angular pitch

+kd1=sin(((spp*ap)/2)*(%pi/180))/(spp*sin((ap/2)*(%pi/180))); // distribution factor for fundamental harmonic

+kd3=sin(((3*spp*ap)/2)*(%pi/180))/(spp*sin(((3*ap)/2)*(%pi/180))); // distribution factor for third harmonic

+kd5=sin(((5*spp*ap)/2)*(%pi/180))/(spp*sin(((5*ap)/2)*(%pi/180))); // distribution factor for fifth harmonic

+// coil is short pitched by one slot, therefore

+e=180/(spp*np); // chording angle

+cs1=cos((e/2)*(%pi/180)); // coil span factor for fundamental harmonic 

+cs3=cos(((3*e)/2)*(%pi/180)); // coil span factor for third harmonic 

+cs5=cos(((5*e)/2)*(%pi/180)); // coil span factor for fifth harmonic

+kw1=cs1*kd1; // winding factor for fundamental harmonic

+kw3=cs3*kd3; // winding factor for third harmonic

+kw5=cs5*kd5; // winding factor for fifth harmonic

+ts=spp*np*p; // total number of slots

+tt=(ts*c)/2; // total number of turns

+nph=tt/np; // series turn per phase

+ep1=sqrt(2)*%pi*f*kw1*nph*f1; // emf per phase for fundamental harmonics

+ep3=(ep1*kw3*3*f3)/(kw1*f1); // emf per phase for third harmonics

+ep5=(ep1*kw5*5*f5)/(kw1*f1); // emf per phase for fifth harmonics

+disp('case a(1): star connected alternator');  

+ep=sqrt(ep1^2+ep3^2+ep5^2); 

+printf('Resultant EMF per phase is %f V\n',ep);

+// third frequency line emf doesnot appear in line voltage

+el=sqrt(3)*sqrt(ep1^2+ep5^2);

+printf('Resultant line voltage is %f V\n',el);

+disp('case a(2): Delta connected alternator'); 

+// third frequency line emf doesnot appear in line and phase voltage as they are short circuited  by closed delta 

+ep=sqrt(ep1^2+ep5^2);

+printf('Resultant EMF per phase(also line voltage) is %f V\n',ep);

+disp('case b: delta connected alternator ');

+rpp=10; // reactance per phase

+// emf to due first and third harmonic cancels each other but third harmonic gives rise to circulating current

+I=(3*ep3)/(3*np*rpp);

+printf('Circulating current is %f A',I);