Matlab Code into Simulink Help
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I want to put the following code into Simulink. I tried MATLAB Function block but it gives me many errors. May be a S-Function block will help. I want to have a block with 4 inputs (J, P_D, BARatio, NosBlades) and to have 3 outputs (TT, TQ, TE). Here is the original code
J=0.4;
P_D=0.875;
BARatio=0.55;
NosBlades=4;
%%%%%%%%%%
C2(2)=0.208;
C2(3)=0.241;
C2(4)=0.263;
C2(5)=0.276;
C2(6)=0.279;
C2(7)=0.269;
C2(8)=0.241;
C2(9)=0.184;
%%%%%%%%%
PA(2)=0.888;
PA(3)=1.008;
PA(4)=1.055;
PA(5)=1.060;
PA(6)=1.039;
PA(7)=1.000;
PA(8)=0.948;
PA(9)=0.888;
%%%%%%%%
VV=0;
LA=0.97;
RT=0.045;
LM=0.8*11.3;
LI=0.8*12.67;
%%%%%%%%%
for i=2:9
C1(i)=C2(i)*BARatio*4.0/(NosBlades*0.5);
CP=NosBlades*C1(i); %Nc/D
X(i)=i/10; %x/R
AI(i)=0; %Assume initial Angle of Attack=0
PR(i)=P_D*PA(i); %Pitch/diameter ratio at blade element
TD=RT-(RT*0.935)*X(i);
TC(i)=TD/C1(i);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
counter=1;
SubConverged=0;
while and(counter <2000, SubConverged==0)
counter=counter+1;
HA=atan(PR(i)/(pi*X(i)))/pi*180-AI(i);
H1=tan(HA/180*pi); %tan phi
AA=J/(pi*X(i)); %tan psi (undisturbed flow angle?)
EI=AA/H1; %Ideal Efficiency
EA(i)=0.9*EI; %Local Efficiency Estimate
AE=0.0; %tan(gamma) =atan(Cd(i)/Cl(i)) assume =0.0
KF=X(i)*H1; %Lambda parameter for Goldstein correction
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
SF=NosBlades/(2.0*KF)-0.5;
F1=cosh(SF);
F2=cosh(SF*X(i));
F3=F2/F1;
F4=acos(F3);
K=2.0*F4/pi;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
GK(i)=K;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
counter2=0;
SubSubConverged=0;
while and(counter2<2000, SubSubConverged==0)
counter2=counter2+1;
FA(i)=(1-EI)/(EI+AA*AA/EA(i)); %axial flow factor
KT(i)=pi*J^2*X(i)*K*FA(i)*(1+FA(i)); %local dKT/dx
AE=tan(AE/180*pi); %tan(gamma)
FT(i)=1-EI*(1+FA(i)); %a' tangential flow factor
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
CL(i)=KT(i)*cos(HA/180*pi);
CL(i)=CL(i)*4/(pi^2)/(X(i)^2);
CL(i)=CL(i)/((1-FT(i))^2*(1-H1*AE)*CP);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
F6=0.0107+(AI(i)+1.0)*(-0.0015+AI(i)*(0.0015+0.000965*(AI(i)-1.0)));
F7=-0.03833+(AI(i)+1.0)*(0.0133+AI(i)*(-0.015-0.01166*(AI(i)-1.0)));
F8=0.8193+(AI(i)+1.0)*(-0.0138+AI(i)*(0.0903+0.079*(AI(i)-1.0)));
F9=-3.076+(AI(i)+1.0)*(-0.0728+AI(i)*(-0.3162-0.2437*(AI(i)-1.0)));
CD(i)=F6+TC(i)*(F7+(TC(i)-0.06)*(F8+F9*(TC(i)-0.12)));
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
AG=CD(i)/CL(i);
AE=atan(AG)/pi*180; %gamma
EZ=AA/tan((HA+AE)/180*pi); %
if (abs(EZ-EA(i)) < 0.001)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
K2(2)=1.0+2.857*(BARatio-0.4)*(BARatio-0.6)*(BARatio-0.9);
K2(3)=1.19+(BARatio-0.4)*(BARatio-0.6)*(0.267+(BARatio-0.9)*0.1665);
K2(4)=1.3+(BARatio-0.4)*(0.1+(BARatio-0.6)*(1+(BARatio-0.9)*0.43));
K2(5)=1.54+(BARatio-0.4)*(0.15+(BARatio-0.6)*(1.1+0.286*(BARatio-0.9)));
K2(6)=1.67+(BARatio-0.4)*(0.55+(BARatio-0.6)*(0.1667+(BARatio-0.9)*2.9465));
K2(7)=1.8+(BARatio-0.4)*(0.75+(BARatio-0.6)*(0.3+(BARatio-0.9)*2.835));
K2(8)=1.8+(BARatio-0.4)*(1.0+(BARatio-0.6)*(1.333+(BARatio-0.9)*1.905));
K2(9)=1.75+(BARatio-0.4)*(1.25+(BARatio-0.6)*(1.5+(BARatio-0.9)*3.55));
U1=-0.65*KF*KF+1.1*KF+0.664;
U2=(0.85+(KF-0.3)*(-4.0+(KF-0.4)*(15.42-47.95*(KF-0.5))));
U2=-0.09+(KF-0.2)*U2;
U3=(1.375+(KF-0.3)*(-3.75+(KF-0.4)*(20.85-75.7875*(KF-0.5))));
U3=-0.2+(KF-0.2)*U3;
K1=U1+(BARatio-0.4)*(U2+U3*(BARatio-0.8));
CC(i)=K1*K2(i);
if VV==1
MC(i)=MT(i)*TC(i);
AC=(CC(i)*CL(i)/LI-MC(i))*LM/0.1097+(MC(i)*LI/LA);
elseif VV==5
MC(i)=0.5*TC(i);
AC=(CC(i)*CL(i)/LI-MC(i))*LM/0.1097+(CL(i)/LA);
MT(i)=MC(i)/TC(i);
else
AC=CL(i)/LA;
MC(i)=CL(i)/LI;
MC(i)=MC(i)*CC(i);
if (MC(i)<0.5*TC(i))
MT(i)=MC(i)/TC(i);
else
VV=5;
MC(i)=0.5*TC(i);
AC=(CC(i)*CL(i)/LI-MC(i))*LM/0.1097+(CL(i)/LA);
MT(i)=MC(i)/TC(i);
end
end
SubSubConverged=1; %Set subsub loop converged flag to 1
else
EA(i)=EZ; %update local efficiency estimate
end
end %subsubloop
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
if (abs((AC-AI(i))/(AC))<0.1)
%subloop converged difference between angle of attack assumed AI and calculated angle of attack AC <0.1*AC
KQ(i)=4.935*J*X(i)*X(i)*X(i)*K*FT(i)*(1+FA(i)); %calculate dkq/dx
SubConverged=1; %set subloop converged flag to 1
else
AI(i)=(AC+AI(i))/2; %New Guess of Angle of Attack AI(i)
end
end %subloop
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
end %End Main Loop
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
X(10)=1.0;
KT(10)=0.0;
KQ(10)=0.0;
FA(10)=0.0;
FT(10)=0.0;
GK(10)=0.0;
MT(10)=MT(9);
PR(10)=PR(9);
AI(10)=AI(9);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%Numerical Integration of Total Values
TT=(KT(2)+2.0*(KT(4)+KT(6)+KT(8))+4.0*(KT(3)+KT(5)+KT(7)+KT(9)));
TT=0.1*TT/3.0;
TQ=(KQ(2)+2.0*(KQ(4)+KQ(6)+KQ(8))+4.0*(KQ(3)+KQ(5)+KQ(7)+KQ(9)));
TQ=0.1*TQ/3.0;
TE=J*TT/(2.0*3.1416*TQ);
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