You want to approximate u'' knowing only the value of u on the right (or the left) of a point.
In order to have a second order approximation, you need 3 equations (basic taylor expansion):
u(i+1) = u(i) + h u' + (1/2) h^2 u'' + (1/6) h^3 u''' + O(h^4)
u(i+2) = u(i) + 2 h u' + (4/2) h^2 u'' + (8/6) h^3 u''' + O(h^4)
u(i+3) = u(i) + 3 h u' + (9/2) h^2 u'' + (27/6) h^3 u''' + O(h^4)
Solving for u'' gives (1):
h^2 u'' = -5 u(i+1) + 4 u(i+2) - u(i+3) + 2 u(i) +O(h^4)
To get the laplacian you need to replace the traditional formula with this one on the borders.
For example where "i = 0" you'll have:
del2(u) (i=0,j) = [-5 u(i+1,j) + 4 u(i+2,j) - u(i+3,j) + 2 u(i,j) + u(i,j+1) + u(i,j-1) - 2u(i,j) ]/h^2
The laplacian is the sum of the 2nd derivatives in the x and in the y directions. You can calculate the second derivative with the formula (2)
u'' = (u(i+1) + u(i-1) - 2u(i))/h^2
if you have both u(i+1) and u(i-1). If i=0 or i=imax you can use the first formula I wrote to compute the derivatives (notice that due to the simmetry of the 2nd derivative, if i = imax you can just replace "i+k" with "i-k"). The same applies for the y (j) direction:
On the edges you can mix up the formulas (1) and (2):
del2(u) (i=imax,j) = [-5 u(i-1,j) + 4 u(i-2,j) - u(i-3,j) + 2 u(i,j) + u(i,j+1) + u(i,j-1) - 2u(i,j) ]/h^2
del2(u) (i,j=0) = [-5 u(i,j+1) + 4 u(i,j+2) - u(i,j+3) + 2 u(i,j) + u(i+1,j) + u(i-1,j) - 2u(i,j) ]/h^2
del2(u) (i,j=jmax) = [-5 u(i,j-1) + 4 u(i,j-2) - u(i,j-3) + 2 u(i,j) + u(i+1,j) + u(i-1,j) - 2u(i,j) ]/h^2
And on the corners you'll just use (1) two times for both directions.
del2(u) (i=0,j=0) = [-5 u(i,j+1) + 4 u(i,j+2) - u(i,j+3) + 2 u(i,j) + -5 u(i,j+1) + 4 u(i+2,j) - u(i+3,j) + 2 u(i,j)]/h^2
Del2 is the 2nd order discrete laplacian, i.e. it permits to approximate the laplacian of a real continuous function given its values on a square cartesian grid NxN where the distance between two adjacent nodes is h.
h^2 is just a constant dimensional-factor, you can get the matlab implementation from these formulas by setting h^2 = 4.
For example, if you want to compute the real laplacian of u(x,y) on the (0,L) x (0,L) square, what you do is writing down the values of this function on an NxN cartesian grid, i.e. you calculate u(0,0), u(L/(N-1),0), u(2L/(N-1),0) ... u( (N-1)L/(N-1) =L,0) ... u(0,L/(N-1)), u(L/(N-1),L/(N-1)) etc. and you put down these N^2 values in a matrix A.
Then you'll have
ans = 4*del2(A)/h^2, where h = L/(N-1).
del2 will return the exact value of the continuous laplacian if your starting function is linear or quadratic (x^2+y^2 fine, x^3 + y^3 not fine). If the function is not linear nor quadratic, the result will be more accurate the more points you use (i.e. in the limit h -> 0)
I hope this is more clear, notice that i used 0-based indices for accessing matrix (C/C++ array style), while matlab uses 1-based.