During flag=1 call must be a real vector of length 10 error

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Maaz Madha
Maaz Madha am 23 Apr. 2022
Beantwortet: Chetan am 28 Dez. 2023
Hi all
I have a nonlinear matlab code which is
function[sys,x0,str,ts]=nonlinearxrae1_height(t,x,ui,flag,x0,s,ar,zf1,zf2,b,et,lf1,lf2,c,ha,mass,ix,iy,iz,ixz,clow,clo,clq,cdow,cmo,cmq,claw,cla,cln,cma,cmn,clad,k,cmad,yvb,lx,yzb,lzb,nzb,ro,g,pi)
%An M-file S-function for defining a system of continuous state equations:
%XRAE1 6DOF nonlinear simulation
%Dispatch the flag.
switch flag,
case 0
[sys,x0,str,ts]=mdlInitializeSizes(x0)
case 1
sys=mdlDerivatives(t,x,ui,s,ar,zf1,zf2,b,et,lf1,lf2,c,ha,mass,ix,iy,iz,ixz,clow,clo,clq,cdow,cmo,cmq,claw,cla,cln,cma,cmn,clad,k,cmad,yvb,lx,yzb,lzb,nzb,ro,g,pi)
case 3
sys=mdlOutputs(t,x); %Calculate outputs
case{2,4,9} %Unused flags
sys=[];
otherwise
error(['Unhandled flag=',num2str(flag)]); %Error handling
end
%End of XRAE1 func.
%=========================================================================
%mdlInitializesSizes
%Return the sizes, inital conditions and sample times for the S-function.
function [sys,x0,str,ts]=mdlInitializeSizes(x0)
%call simsizes for a sizes structure, fill it in and convert it
%to a sizes array.
sizes=simsizes;
sizes.NumContStates=10;
sizes.NumDiscStates=0;
sizes.NumOutputs=10;
sizes.NumInputs=4;
sizes.DirFeedthrough=0; %matrix Dis nonempty
sizes.NumSampleTimes=1;
sys=simsizes(sizes);
%initialize the inital conditions
x0=x0;
%str is an empty matrix.
str=[];
%Initialize the array of sample times; in this example the sample
%time is continuous, so set ts to 0 and its offset to 0.
ts=[0 0];
%End of mdlInitializeSizes.
%========================================================================
%mdlDerivatives
%Return the derivatives for the continuous states.
%========================================================================
function sys=mdlDerivatives(t,x,ui,s,ar,zf1,zf2,b,et,lf1,lf2,c,ha,mass,ix,iy,iz,ixz,clow,clo,clq,cdow,cmo,cmq,claw,cla,cln,cma,cmn,clad,k,cmad,yvb,lx,yzb,lzb,nzb,ro,g,pi)
%angle of attack
A=atan(x(3)/x(1));
%total velocity
vt=sqrt(x(1)^2+x(2)^2+x(3)^2);
%dynamic pressure
qp=0.5*ro*(vt^2);
%part of total lift coeficient
cl1=clo+cla*A+clq*((x(5)*c)/(2*vt))+cln*ui(1);
%wing body lift coefficent
clw=clow+claw*A;
%total drag coefficient
cd=cdow+k*(clw^2);
%thrust
T=26.7154*ui(4)-0.0026*(vt^2);
MAS=[1+qp*s*x(3)*clad*c*sin(A)/(2*mass*vt*(x(1)^2+x(3)^2)),-qp*s*x(1)*clad*c*sin(A)/(2*mass*vt*(x(1)^2+x(3)^2));-qp*s*x(3)*clad*c*cos(A)/(2*mass*vt*(x(1)^2+x(3)^2)),1+qp*s*x(1)*clad*c*cos(A)/(2*mass*vt*(x(1)^2+x(3)^2))];
Forces=[x(6)*x(2)-x(5)*x(3)-g*sin(x(8))+qp*s*(cl1*sin(A)-cd*cos(A))/mass+T/mass;x(5)*x(1)-x(4)*x(2)+g*cos(x(8))*cos(x(7))-qp*s*(cl1*cos(A)+cd*sin(A))/mass];
%[sys(1),sys(3)]=inv(MAS)*Forces;
x13d=MAS\Forces;
sys(1)=x13d(1);
sys(3)=x13d(2);
% coeficient needed for longitudinal equation
%b1=x(6)*x(2)-x(5)*x(3)-g*sin(x(8))+qp*s*(cl1*sin(A)-cd*cos(A))/mass+T/mass;
%b2=x(5)*x(1)-x(4)*x(2)+g*cos(x(8))*cos(x(7))-qp*s*(cl1*cos(A)+cd*sin(A))/mass;
%d=qp*s*clad*c/(2*mass*vt*(x(1)^2+x(3)^2));
%d1=1+d*(x(1)*cos(A)+x(3)*sin(A));
%d2=d*(b1*cos(A)+b2*sin(A));
%velocity rate along xb axis
%sys(1)=(b1+x(1)*d2)/d1;
%veloctiy rate along zb axis
%sys(3)=(b2+x(3)*d2)/d1;
%angle of attack rate
ad=(sys(3)*x(1)-sys(1)*x(3))/(x(1)^2+x(3)^2);
%pitching moment coefficient
cm=cmo+cma*A+((cmad*ad*c)/(2*vt))+((cmq*x(5)*c)/(2*vt))+cmn*ui(1);
%lift coefficient
cl=cl1+((clad*ad*c)/(2*vt));
%pitching angular acceleration about yb axis
sys(5)=((iz-ix)*x(4)*x(6)-(x(4)-x(6))*ixz+qp*s*c*cm-T*et-ha*qp*s*(cl*sin(A)-cd*cos(A)))/iy;
%lateral stability dervatives
%stability axes
nv=-0.0363+0.1969*(lf1*cos(A)+zf1*sin(A))/b;
lv=-0.0119-0.0074*clw-0.1969*(zf1*cos(A)-lf1*sin(A))/b;
x1=(zf2-(zf2*cos(A)-lf2*sin(A)))/b;
%sidewash component of ypf
X=[0.0 0.025 0.05 0.075 0.1 0.125 0.15 0.175 0.2 0.225 0.25];
Y=[0.0 0.036 0.075 0.114 0.156 0.2 0.25 0.295 0.345 0.4 0.45];
y1=abs(x1);
ysd=interp1(X,Y,y1);
yps=x1*ysd/y1;
ypf=-0.3133*((zf2*cos(A)-lf2*sin(A))/b-0.18-yps);
yp=0.078*cl+ypf;
cdvd=2*clw*(k-1/(pi*ar))*claw*pi/180.0;
np=-0.034*cl+1.23*cdvd-ypf*(lf2*cos(A)+zf2*sin(A))/b;
lp=-0.2457+ypf*(zf2*cos(A)-lf2*sin(A))/b;
yrf=0.2164*(lf1*cos(A)+zf1*sin(A))/b;
yr=-0.0109+yrf;
nr=-0.0022-0.1621*cdow-0.009*clw^2-yrf*(lf1*cos(A)+zf1*sin(A))/b;
lr=-0.00189+0.1243*clw+yrf*(zf1*cos(A)-lf1*sin(A))/b;
nx=0.0195*clw;
%transformation to body reference axes
ypb=yp*cos(A)-yr*sin(A);
yrb=yr*cos(A)+yp*sin(A);
lvb=lv*cos(A)-nv*sin(A);
lpb=lp*(cos(A))^2-(lr+np)*sin(A)*cos(A)+nr*(sin(A))^2;
lrb=lr*(cos(A))^2-(nr-lp)*sin(A)*cos(A)-np*(sin(A))^2;
nvb=nv*cos(A)+lv*sin(A);
npb=np*(cos(A))^2-(nr-lp)*sin(A)*cos(A)-lr*(sin(A))^2;
nrb=nr*(cos(A))^2+(lr+np)*sin(A)*cos(A)+lp*(sin(A))^2;
lxb=lx*cos(A)-nx*sin(A);
nxb=nx*cos(A)+lx*sin(A);
%aerodynamic force along yb axis
y=qp*s*(yvb*x(2)+b*ypb*x(4)+b*yrb*x(6))/vt+qp*s*yzb*ui(3);
%aerodynamic moment about xb axes
l=qp*s*b*(lvb*x(2)+b*lpb*x(4)+b*lrb*x(6))/vt+qp*s*b*(lzb*ui(3)+lxb*ui(2));
%aerodynamic moment about zb axis
n=qp*s*b*(nvb*x(2)+b*npb*x(4)+b*nrb*x(6))/vt+qp*s*b*(nzb*ui(3)+nxb*ui(2));
%velocity rate along yb axes
sys(2)=x(4)*x(3)-x(6)*x(1)+g*cos(x(8))*sin(x(7))+y/mass;
Inertia=[ix -ixz; -ixz iz];
Ml=l-(x(5)*x(6)*(iz-iy))+(x(4)*x(5)*ixz);
Mn=n-(x(4)*x(6)*(ix-iz))-((x(4))^2-((x(6))^2)*ixz);
%[sys(4),sys(6)]=inv(Inertia)*[Ml;Mn];
x46d=Inertia\[Ml;Mn];
sys(4)=x46d(1);
sys(6)=x46d(2);
%rolling angular acceleration about zb axes
%sys(4)=((iy-iz)*x(5)*x(6)+l)/ix;
%yawing angular acceleration about zb axes
%sys(6)=((ix-iy)*x(4)*x(5)+n)/iz;
%euler angle rates
sys(7)=x(4)+x(5)*tan(x(8))*sin(x(7))+x(6)*tan(x(8))*cos(x(7));
sys(8)=x(5)*cos(x(7))-x(6)*sin(x(7));
sys(9)=(x(6)*cos(x(7))+x(5)*sin(x(7)))/cos(x(8));
sys(10)=x(1)*sin(x(8))-x(2)*sin(x(7))*cos(x(8))-x(3)*cos(x(7))*cos(x(8));
%end of "dynamic derivative"
%end of program
%End of mdlDerivatives.
%=========================================================================
%mdlOutputs
%Return the block outputs.
%=========================================================================
function sys=mdlOutputs(t,x)
sys=x;
This is the code I'm trying to implement in Simulink s file with the s file being the name of the function above.
When I run this I get the error and I don't know why. Any suggestions would be very helpful.
  6 Kommentare
Walter Roberson
Walter Roberson am 25 Apr. 2022
If you can attach your .slx then someone might be willing to test.
Maaz Madha
Maaz Madha am 25 Apr. 2022
Bearbeitet: Maaz Madha am 26 Apr. 2022
I have attached the slx cw
The K_xrae is
or
K_xrae=zeros(4,10);
K_xrae(1,1)=-0.2488;
K_xrae(1,3)=0.3878;
K_xrae(1,5)=-0.4488;
K_xrae(1,8)=-19.9541;
K_xrae(1,10)=-2.3526;
K_xrae(4,1)=15.2227;
K_xrae(4,3)=-9.1902;
K_xrae(4,5)=5.2662;
K_xrae(4,8)=375.5046;
K_xrae(4,10)=29.4992;

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Antworten (1)

Chetan
Chetan am 28 Dez. 2023
I Understand that you're working on a MATLAB S-function for a 6DOF nonlinear system. And facing issues while simulating the model.
It seems like you are using level-1 S-functions. You can follow these steps to solve the issues:
Update Fortran S-Function: Level-1 Fortran S-functions are deprecated.
Transition to a Level-2 S-Function using a C gateway as outlined here:
MATLAB S-function Troubleshooting:
  • Script Name and Path: Ensure `nonlinearxrae1_height.m` is named correctly and in MATLAB's path.
  • Input Connections: Check that all Simulink inputs are connected and dimensioned correctly.
  • Initial Conditions: The `x0` vector should correspond to your model's state count (10).
  • Variable Initialization: Confirm initialization and passing of all variables and parameters.
  • Error Diagnosis: Look at MATLAB command window errors for guidance.
  • Debugging: Use breakpoints to debug your S-function script.
  • S-Function Registration: Use the correct S-Function block name in Simulink (`nonlinearxrae1_height`)
Refer to the following MathWorks documentation regarding the level 2 S-Functions:
Hope It helps

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