Condition for diffraction
[tex]dsin\theta = m\lambda[/tex]
Where
a = Distance between slits
m = Order of the fringes
[tex]\lambda[/tex] = Wavelength
[tex]\theta[/tex] = At the angle between the ray of light and the projected distance perpendicular between the two objects
For small angles
[tex]sin\theta = \approx tan\theta[/tex]
Where
[tex]tan\theta = \frac{Y}{L}[/tex]
Where L is the distance between the slits and Y the length of the light.
Replacing we have
[tex]d\frac{Y}{L} = \lambda m[/tex]
[tex]Y = \frac{m\lambda L}{d}[/tex]
The distance between slits d can be expressed also as [tex]d= \frac{L}{N}[/tex] Where N is the number of the fringes, then
[tex]Y_n = mN\lambda L[/tex]
Similarly when there is added a new Fringe we have the change of the distance would be :
[tex]Y_{n+1} = (m+1)N\lambda L[/tex]
Linear distance between fringes is
[tex]\Delta Y = \Delta Y_{m+1}-Y_m[/tex]
[tex]\Delta Y = (m+1)N\lambda L - mN\lambda L[/tex]
Therefore the answer is
[tex]\Delta Y = N\lambda L[/tex]
