Hello friend, in what I could see was from your work I realized two things that can help you. The first is that you can model as I show you acontinuation:
From there I cleared the second derivative of theta according to the rest of the state variables, as you can see in the code below (see F = @ (t, x)).
The second consideration is that if you look you can consider the following:
<<latex-codecogs-com-gif-latex-sig-5Cleft-28-20-5Cdot-7B-5Ctheta-7D-20-5Cright-29-20-5Cleft-7C-20-5Cdot-7B-5Ctheta-7D-20-5Cright-7C-20-3D-5Cdot-7B-5Ctheta-7D-20-5Cwedge-20-5C-5C-20sig-5Cleft-28-20-5Cdot-7B-5Ctheta-7D-20-5Cright-29-20-5Cdot-7B-5Ctheta-7D-20-3D-5Cleft-7C-5Cdot-7B-5Ctheta-7D-20-5Cright.7C>>
See how it modifies F = @ (t, x) in the code, where the sign function sig(tetha) was. And finally look at the units, you are working in international system, then the mass (m) must be in kilograms, you enter it in grams.
Keep in mind that the dynamics is susceptible to the constants you introduce, assuming a mass of m = 1000 [g] and a r = 0.05; I was able to obtain the plot that I will show you next with the code that I append you.
% function [t,x] = Untitled
clear all
clc
clf
% global m r EGR Q u k taustall xi B C D A
m = 1000; %g
r = 0.05; %meters
EGR = 1; %external gear ratio
Q = (0.003531/513.3)/2; %stall torque coeff in N-m
u = 0.1; %dynamic friction coeff
k = 30.7; %N/m
taustall = 0.003531; %N-m
xi = 0.02; %meters
B = 6/(2*pi);
C = (3*pi)/2;
D = k*xi; %N
A = (2.2-D); %N
ts=[0 100];
xo = [0 0];
U3 = k*xi*r;
% options=odeset('RelTol',1e-12);
F=@(t,x) [x(2);((((A/2)*sin(B*t-C)+(A/2)+D)*r)-(k*r^2*x(1))-U3-(u*abs(x(2)))-(EGR*(-Q*x(2)+taustall)))/(0.5*m*r^2)];
[t, x]=ode45(F,ts,xo);
plot(t,x)
