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3. Beam optics.

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Presentation on theme: "3. Beam optics."— Presentation transcript:

1 3. Beam optics

2 3-1. The Gaussian beam A paraxial wave is a plane wave e-jkz modulated by a complex envelope A(r) that is a slowly varying function of position: The complex envelope A(r) must satisfy the paraxial Helmholtz equation One simple solution to the paraxial Helmholtz equation : paraboloidal waves Another solution of the paraxial Helmholtz equation : Gaussian beams

3 Gaussian beams z0 : Rayleigh range.

4 Gaussian beam : Intensity
The intensity is a Gaussian function of the radial distance r.  This is why the wave is called a Gaussian beam. On the beam axis (r = 0) At z = z0 , I = Io/2

5 Gaussian beam : Power The result is independent of z, as expected.
The beam power is one-half the peak intensity times the beam area. The ratio of the power carried within a circle of radius r in the transverse plane at position z to the total power is

6 Beam radius At the Beam waist : Waist radius = W0 Spot size = 2W0
(divergence angle)

7 Depth of Focus The axial distance within which the beam radius lies within a factor root(2) of its minimum value (i.e., its area lies within a factor of 2 of its minimum) is known as the depth of focus or confocal parameter (twice the Rayleigh range) A small spot size and a long depth of focus cannot be obtained simultaneously !

8 Phase of the Gaussian beam
kz : the phase of a plane wave. : a phase retardation ranging from - p/2 to - p/2 . : This phase retardation corresponds to an excess delay of the wavefront in comparison with a plane wave or a spherical wave The total accumulated excess retardation as the wave travels from Guoy effect

9 Wavefront - bending Wavefronts (= surfaces of constant phase) :

10 wave fronts near the focus
Wave fronts: p/2 phase shift relative to spherical wave wave fronts near the focus Changes in wavefront radius with propagation distance Radius of curvature

11 Gaussian parameters : Relationships between parameters

12

13 3.2 TRANSMISSION THROUGH OPTICAL COMPONENTS
A. Transmission Through a Thin Lens

14 B. Beam Shaping Beam Focusing
If a lens is placed at the waist of a Gaussian beam, If (2 z0 ) >> f ,

15 (a) z and z’ :

16 Gaussian Beams higher order beams
Hermite-Gaussian Bessel Beams

17 q(z) ?

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