The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \...The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \space sin \space \theta}{\lambda}\), D is the slit width, λλ is the wavelength, and θθ is the angle from the central peak.
The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \...The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \space sin \space \theta}{\lambda}\), D is the slit width, λλ is the wavelength, and θθ is the angle from the central peak.
The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \...The intensity pattern for diffraction due to a single slit can be calculated using phasors as \(I = I_0 \left(\frac{sin \space \beta}{\beta}\right)^2,\) where \(\beta = \frac{\phi}{2} = \frac{\pi D \space sin \space \theta}{\lambda}\), D is the slit width, λλ is the wavelength, and θθ is the angle from the central peak.
