Hi Sharon,
It seems like we want to compute the following integral
I = int((u(x)+k(x))*w(x),x,0,1,'Hold',true)
I =
w(x) has a known form
w(x) = 1.5*exp(-2*(1-x));
which can be substituded into the expression for I
I = subs(I)
I =
Suppose for now we know the functional form of u(x) and k(x), for example
u(x) = x, k(x) = x^2
k(x) = 
Sub those expressions into I and evaluate the integral
I = subs(I)
I =
release(I)
ans =
Now, compute the integral numerically, assuming those same known expressions for u(x) and k(x)
w = @(x) 1.5*exp(-2*(1-x));
integral(@(x) (u(x)+k(x)).*w(x),0,1)
Same result.
But in this question we only have u and k evaluated at discrete set of values of x. For example
xval = linspace(0,1,100);
Now, to evaluate the integral we need to have some way to approximate u(x) and k(x) based on those vectors of points in order to evaluate the integrand. Here, I'm using interp1 with linear interplolation, but you may want to explore other options after plotting u and k and testing various options, which could be different for u(x) and k(x), to make sure the interpolated values are a a good approximation to the functions u(x) and k(x) (hopefully you have some idea what they should look like). The key is that the interpolation has to be performed in the evaluation of the integrand.
integral(@(x) (interp1(xval,u,x)+interp1(xval,k,x)).*w(x),0,1)
