I have some coupled nonlinear ordinary differential equations. Three equations have three 2nd order derivative coupled together. Can someone tell me how I can get the response

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prabin kumar meher am 21 Sep. 2022

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Kommentiert: prabin kumar meher am 22 Sep. 2022

I have some coupled nonlinear ordinary differential equations. Three equations have three 2nd order derivative coupled together. Can someone tell me how I can get the response, numerically? i.e t vs x , t vs theta dot plots.

Thanks in advance

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James Tursa am 21 Sep. 2022

Do you have initial conditions for all the variables and first derivatives?

prabin kumar meher am 21 Sep. 2022

all initial condition are zero

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Answer 1

Torsten am 21 Sep. 2022

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Bearbeitet: Torsten am 21 Sep. 2022

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Solve the third equation for theta_dotdot and insert this expression in equations (1) and (2).

Then use the usual substitutions

z1 = x
z2 = xdot
z3 = y
z4 = ydot
z5 = theta
z6 = thetadot

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prabin kumar meher am 21 Sep. 2022

yes f is a constant term

James Tursa am 21 Sep. 2022

OK, then you can use Torsten's advice.

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Answer 2

James Tursa am 21 Sep. 2022

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Bearbeitet: James Tursa am 21 Sep. 2022

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Another related approach is to isolate all the 2nd derivatives on the LHS and put everything else on the RHS. Then pick off the coefficients of the 2nd order derivatives to form a matrix problem that you solve for the 2nd derivatives. E.g., the matrix problem would look something like this based on your comment edits:

A*z = b

where

A = [     1                0         -f*sin(theta);
          0                1          f*sin(theta);
    -m*e*sin(theta)  m*e*cos(theta)  (m*e^2+Ip)/B^2]

and

z = [x_dotdot; y_dotdot; theta_dotdot]

and

b = 3x1 vector with all the other stuff from RHS

Then solve for z to get the 2nd derivatives.

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prabin kumar meher am 21 Sep. 2022

Bearbeitet: Torsten am 22 Sep. 2022

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clc;

close all;

clear all;

% T=0;0.01;100;

% IC=[0 0.1 0 0.1 0 0.1];

t=0:0.1:90;

options = odeset('RelTol',1e-10,'AbsTol',1e-10);

[t,x]=ode45(@system_prabin,t,[0 0 0 0 0 0 ],options);

plot(t,x(:,5))

function dx = system_prabin(t,x)

e=10*5*10^-7;

m=0.54;

C=0.0458;

C0=0.5*10^-3;

K=4.865*10^-7;

mum=0.1;

Rd=0.0002;

Rm=40;

Ip=0.1;

Kp=2440;

Kd=0.1178;

I0=0.8;

Vs=1;

a=0.3927;

f=e/C0;

p=Kp*C0/I0;

B=sqrt((m*C0^3)/(K*I0^2));

d=Kd*C0/(B*I0);

c1=B*C/m;

% P=(mum*Vs)/(Rm*((m*e^2)+Ip));

% S=((mum^2)/(Rm*((m*e^2)+Ip)))+((Rd)/((m*e^2)+Ip));

mu= c1+(8*d*(cos(a)+cos(3*a)));

w= sqrt(8*p*(cos(a)+cos(3*a))-16);

a1=-24-4*cos(4*a)-4*cos(12*a)+6*p*(3*cos(a)+4*cos(3*a)+cos(9*a))-4*p^2*(cos(2*a)+cos(6*a)+2);

a2=-24+12*cos(4*a)+12*cos(12*a)+18*p*(cos(a)-cos(9*a))+4*p^2*(cos(2*a)+cos(6*a)-2);

a3=-8*p*d*(cos(2*a)+cos(6*a)+2)+6*d*(3*cos(a)+4*cos(3*a)+cos(9*a));

a4=6*d*(cos(a)-cos(9*a));

a5=4*d^2*(cos(2*a)+cos(6*a)-2);

a6=-4*d^2*(cos(2*a)+cos(6*a)+2);

a7=12*d*(cos(a)-cos(9*a))+8*p*d*(cos(2*a)+cos(6*a)-2);

dx= zeros(6,1);

dx(1)=x(2);

dx(2)=(f*((x(6)^2*cos(x(5)))+(((1/(((m*e^2)+Ip)-(f*m*e*sin(x(5))*sin(x(5)))-(f*m*e*cos(x(5))*sin(x(5)))))*(((mum*Vs*B^2)/Rm)-(((mum^2/Rm)+Rd)*B*x(6))+(f*m*e*cos(x(5))*(sin(x(5))-cos(x(5)))*x(6)^2)-(m*e*sin(x(5))*((mu*x(2))+(w^2*x(1))+(a1*x(1)^3)+(a2*x(1)*x(3)^2)+(a3*x(1)^2*x(2))+(a4*x(2)*x(3)^2)+(a5*x(1)*x(4)^2)+(a6*x(1)*x(2)^2)+(a7*x(1)*x(3)*x(4))))+(m*e*cos(x(5))*((mu*x(4)-(w^2*x(3))+(a1*x(3)^3)+(a2*x(3)*x(1)^2)+(a3*x(3)^2*x(4))+(a4*x(4)*x(1)^2)+(a5*x(3)*x(2)^2)+(a6*x(3)*x(4)^2)+(a7*x(1)*x(3)*x(2)))))))*sin(x(5)))))-(mu*x(2))-(w^2*x(1))-(a1*x(1)^3)-(a2*x(1)*x(3)^2)-(a3*x(1)^2*x(2))-(a4*x(2)*x(3)^2)-(a5*x(1)*x(4)^2)-(a6*x(1)*x(2)^2)-(a7*x(1)*x(3)*x(4));

dx(3)=x(4);

dx(4)=(f*((x(6)^2*cos(x(5)))-(((1/(((m*e^2)+Ip)-(f*m*e*sin(x(5))*sin(x(5)))-(f*m*e*cos(x(5))*sin(x(5)))))*(((mum*Vs*B^2)/Rm)-(((mum^2/Rm)+Rd)*B*x(6))+(f*m*e*cos(x(5))*(sin(x(5))-cos(x(5)))*x(6)^2)-(m*e*sin(x(5))*((mu*x(2))+(w^2*x(1))+(a1*x(1)^3)+(a2*x(1)*x(3)^2)+(a3*x(1)^2*x(2))+(a4*x(2)*x(3)^2)+(a5*x(1)*x(4)^2)+(a6*x(1)*x(2)^2)+(a7*x(1)*x(3)*x(4))))+(m*e*cos(x(5))*((mu*x(4)-(w^2*x(3))+(a1*x(3)^3)+(a2*x(3)*x(1)^2)+(a3*x(3)^2*x(4))+(a4*x(4)*x(1)^2)+(a5*x(3)*x(2)^2)+(a6*x(3)*x(4)^2)+(a7*x(1)*x(3)*x(2)))))))*sin(x(5)))))-(mu*x(4))-(w^2*x(3))-(a1*x(3)^3)-(a2*x(3)*x(1)^2)-(a3*x(3)^2*x(4))-(a4*x(4)*x(1)^2)-(a5*x(3)*x(2)^2)-(a6*x(3)*x(4)^2)-(a7*x(1)*x(3)*x(2));

dx(5)=x(6);

dx(6)=(1/(((m*e^2)+Ip)-(f*m*e*sin(x(5))*sin(x(5)))-(f*m*e*cos(x(5))*sin(x(5)))))*(((mum*Vs*B^2)/Rm)-(((mum^2/Rm)+Rd)*B*x(6))+(f*m*e*cos(x(5))*(sin(x(5))-cos(x(5)))*x(6)^2)-(m*e*sin(x(5))*((mu*x(2))+(w^2*x(1))+(a1*x(1)^3)+(a2*x(1)*x(3)^2)+(a3*x(1)^2*x(2))+(a4*x(2)*x(3)^2)+(a5*x(1)*x(4)^2)+(a6*x(1)*x(2)^2)+(a7*x(1)*x(3)*x(4))))+(m*e*cos(x(5))*((mu*x(4)-(w^2*x(3))+(a1*x(3)^3)+(a2*x(3)*x(1)^2)+(a3*x(3)^2*x(4))+(a4*x(4)*x(1)^2)+(a5*x(3)*x(2)^2)+(a6*x(3)*x(4)^2)+(a7*x(1)*x(3)*x(2))))));

end

Torsten am 22 Sep. 2022

Bearbeitet: Torsten am 22 Sep. 2022

It works up to t = 90 approximately (see above).

Then all your variables seem to blow up.

Either your equations are wrong, there is a singularity around t = 90 or the integrator is not able to solve your problem.

For all three problems, I cannot be of help.

prabin kumar meher am 22 Sep. 2022

Thank you @Torsten for yor help

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I have some coupled nonlinear ordinary differential equations. Three equations have three 2nd order derivative coupled together. Can someone tell me how I can get the response

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I have some coupled nonlinear ordinary differential equations. Three equations have three 2nd order derivative coupled together. Can someone tell me how I can get the response

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