Polarization of EM waves

Presentation on theme: "Polarization of EM waves"— Presentation transcript:

1 Polarization of EM waves
The polarization of a uniform plane wave refers to the time-varying behaviour of the electric field vector at fixed point in space. Consider, for example, a uniform plane wave travelling in the z-direction. With the E and H vectors lying in the x-y plane. Case 1: If Ey=0, and only Ex is present: The wave is said to be polarized in the x direction. If Ex=0, and only Ey is present: The wave is said to be polarized in the y direction.

2 If both Ex and Ey are present, and are in phase (=0, 2, 4
If both Ex and Ey are present, and are in phase (=0, 2, 4....) the resultant electric vector has a direction, dependent on the relative magnitude of Ex and Ey. The resultant vector will make the angle tan-1(Ey/Ex). In all the above cases the wave is said to be linearly polarized because the resultant vector is constant with time. Case 2: If both Ex and Ey are not in phase (=(2n+1)/2, n=0, 1, ), i.e. their maximum values (of amplitude) reach at different time, the direction of resultant electric vector will vary.

3 The locus of the end point of the resultant E will be an ellipse and the wave is said to be elliptically polarized. Case: 3 When Ex and Ey have equal magnitudes and not in phase i.e.(=(2n+1)/2, n=0, 1, ), the locus of the resultant E will be an circle and the wave is said to be circularly polarized.

4 Equation (1) can be written as:
Let the two plane polarized EM waves may superimpose. One has Electric vector, Ex in X direction and other has electric vector, Ey in Y direction, and both are propagating in Z direction. Where a and b are the amplitude of the waves and  is the phase difference between them. Equation (1) can be written as:

5 From 2nd equation: From above equation we can find: Put these values in equation 3: or or

6 or or This equation in general represents an ellipse. Therefore in this case the resultant will be elliptically polarised light. But actual nature of resultant wave can be given by following cases: Case I: n: integer then

7 So equation 4 will be: or or or Which is the equation of a straight line. Thus emergent ray in this case will be plane polarised light.

8 Case II: then So equation 4 will be: Which is the equation of an ellipse. Thus emergent ray in this case will be elliptically polarised light.

9 Case III: with a=b So equation 4 will be: Which is the equation of a circle of radius a. Thus emergent ray in this case will be circularly polarised light.