Showing posts with label #EC8451 Electromagnetic Fields. Show all posts
Showing posts with label #EC8451 Electromagnetic Fields. Show all posts

Wednesday, 15 April 2020

EC8451 Electromagnetic Fields Unit- 4 Time varying Fields and Maxwell's Equations

Electrodynamic fields

Introduction:


In our study of static fields so far, we have observed that static electric fields are produced by electric charges, static magnetic fields are produced by charges in motion or by steady current. Further, static electric field is a conservative field and has no curl, the static magnetic field is continuous and its divergence is zero. The fundamental relationships for static electric fields among the field quantities can be summarized as:
In this chapter we will consider the time varying scenario. In the time varying case we will observe that a changing magnetic field will produce a changing electric field and vice versa.

We begin our discussion with Faraday's Law of electromagnetic induction and then present the Maxwell's equations which form the foundation for the electromagnetic theory.

Faraday's Law of electromagnetic Induction

Michael Faraday, in 1831 discovered experimentally that a current was induced in a conducting loop when the magnetic flux linking the loop changed. In terms of fields, we can say that a time varying magnetic field produces an electromotive force (emf) which causes a current in a closed circuit. The quantitative relation between the induced emf (the voltage that arises from conductors moving in a magnetic field or from changing magnetic fields) and the rate of change of flux linkage developed based on experimental observation is known as Faraday's law. Mathematically, the induced emf can be written as

(a)     time changing flux linkage a stationary closed path.

(b)    relative motion between a steady flux a closed path.

(c)     a combination of the above two cases.

The negative sign in equation (5.3) was introduced by Lenz in order to comply with the polarity of the induced emf. The negative sign implies that the induced emf will cause a current flow in the closed loop in such a direction so as to oppose the change in the linking magnetic flux which produces it. (It may be noted that as far as the induced emf is concerned, the closed path forming a loop does not necessarily have to be conductive).

If the closed path is in the form of N tightly wound turns of a coil, the change in the magnetic flux linking the coil induces an emf in each turn of the coil and total emf is the sum of the induced emfs of the individual turns, i.e.,
which is the Faraday's law in the point form
We have said that non zero dϕ/dt can be produced in a several ways. One particular case is when a time varying flux linking a stationary closed path induces an emf. The emf induced in a stationary closed path by a time varying magnetic field is called a transformer emf .

Example: Ideal transformer

As shown in figure 5.1, a transformer consists of two or more numbers of coils coupled magnetically through a common core. Let us consider an ideal transformer whose winding has zero resistance, the core having infinite permittivity and magnetic losses are zero.
These assumptions ensure that the magnetization current under no load condition is vanishingly small and can be ignored. Further, all time varying flux produced by the primary winding will follow the magnetic path inside the core and link to the secondary coil without any leakage. If N1 and N2 are the number of turns in the primary and the secondary windings respectively, the induced emfs are

(The polarities are marked, hence negative sign is omitted. The induced emf is +ve at the dotted end of the winding.)
i.e., the ratio of the induced emfs in primary and secondary is equal to the ratio of their turns. Under ideal condition, the induced emf in either winding is equal to their voltage rating.
where 'a' is the transformation ratio. When the secondary winding is connected to a load, the current flows in the secondary, which produces a flux opposing the original flux. The net flux in the core decreases and induced emf will tend to decrease from the no load value. This causes the primary current to increase to nullify the decrease in the flux and induced emf. The current continues to increase till the flux in the core and the induced emfs are restored to the no load values. Thus the source supplies power to the primary winding and the secondary winding delivers the power to the load. Equating the powers
i.e., the net magnetomotive force (mmf) needed to excite the transformer is zero under ideal condition.

Motional EMF:

Let us consider a conductor moving in a steady magnetic field as shown in the fig 5.2.

This force will cause the electrons in the conductor to drift towards one end and leave the other end positively charged, thus creating a field and charge separation continuous until electric and magnetic forces balance and an equilibrium is reached very quickly, the net force on the moving conductor is zero.
A classic example of motional emf is given in Additonal Solved Example No.1 .

Maxwell's Equation

Equation (5.1) and (5.2) gives the relationship among the field quantities in the static field. For time varying case, the relationship among the field vectors written as
 
The equation 5.20 (a) - (d) must be consistent with equation (5.21). 
We observe that 

A classic example for this is given below . Suppose we are in the process of charging up a capacitor as shown in fig 5.3.
Let us apply the Ampere's Law for the Amperian loop shown in fig 5.3. Ienc = is the total current passing through the loop. But if we draw a baloon shaped surface as in fig 5.3, no current passes through this surface and hence Ienc = 0. But for non steady currents such as this one, the concept of current enclosed by a loop is ill-defined since it depends on what surface you use. In fact Ampere's Law should also hold true for time varying case as well, then comes the idea of displacement current which will be introduced in the next few slides.

We can write for time varying case,
 

The modification of Ampere's law by Maxwell has led to the development of a unified electromagnetic field theory. By introducing the displacement current term, Maxwell could predict the propagation of EM waves. Existence of EM waves was later demonstrated by Hertz experimentally which led to the new era of radio communication.

Boundary Conditions for Electromagnetic fields
The differential forms of Maxwell's equations are used to solve for the field vectors provided the field quantities are single valued, bounded and continuous. At the media boundaries, the field vectors are discontinuous and their behaviors across the boundaries are governed by boundary conditions. The integral equations(eqn 5.26) are assumed to hold for regions containing discontinuous media.Boundary conditions can be derived by applying the Maxwell's equations in the integral form to small regions at the interface of the two media. The procedure is similar to those used for obtaining boundary conditions for static electric fields (chapter 2) and static magnetic fields (chapter 4). The boundary conditions are summarized as follows

With reference to fig 5.3
 
Equation 5.27 (a) says that tangential component of electric field is continuous across the interface while from 5.27 (c) we note that tangential  component of the magnetic field is discontinuous by an amount equal to  the surface current density. Similarly 5.27 (b) states that normal  component of electric flux density vector D(Bar) is discontinuous across the interface by an amount equal to the surface current density while normal  component of the magnetic flux density is continuous.  If one side of the interface, as shown in fig 5.4, is a perfect electric  
Wave equation and their solution: 
From equation 5.25 we can write the Maxwell's equations in the differential form as 
 
As we have assumed that the field components are independent of y and z eqn (5.34) reduces to
A field component satisfying either of the last two conditions (i.e (ii) and (iii))is not a part of a plane wave motion and hence Ex is taken to be equal to zero. Therefore, a uniform plane wave propagating in x direction does not have a field component (E or H) acting along x.
Without loss of generality let us now consider a plane wave having Ey component only (Identical results can be obtained for Ez component) .

The equation involving such wave propagation is given by
corresponds to a wave traveling in the -x direction. The general solution of the wave eqn thus consists of two waves, one traveling away from the source and other traveling back towards the source. In the absence of any reflection, the second form of the eqn (5.37) is zero and the solution can be written as
Such a wave motion is graphically shown in fig 5.5 at two instances of time t1 and t2.

Let us now consider the relationship between E and H components for the forward traveling wave.
The constant of integration means that a field independent of x may also exist. However, this field will not be a part of the wave motion.
which relates the E and H components of the traveling wave.
is called the characteristic or intrinsic impedance of the free space

ASSIGNMENT PROBLEMS

EC 8451 Electromagnetic Fields Unit- 3 Magnetostatics


Magnetostatics

In previous chapters we have seen that an electrostatic field is produced by static or stationary charges. The relationship of the steady magnetic field to its sources is much more complicated.

The source of steady magnetic field may be a permanent magnet, a direct current or an electric field changing with time. In this chapter we shall mainly consider the magnetic field produced by a direct current. The magnetic field produced due to time varying electric field will be discussed later. Historically, the link between the electric and magnetic field was established Oersted in 1820. Ampere and others extended the investigation of magnetic effect of electricity

. There are two major laws governing the magnetostatic fields are:

·           Biot-Savart Law

·           Ampere's Law

ually, the magnetic field intensity is represented by the vector H(Bar). It is customary to represent the direction of the magnetic field intensity (or current) by a small circle with a dot or cross sign depending on whether the field (or current) is out of or into the page as shown in Fig. 4.1.

Biot- Savart Law

Similar to different charge distributions, we can have different current distribution such as line current, surface current and volume current. These different types of current densities are shown in Fig. 4.3.
By denoting the surface current density as K (in amp/m) and volume current density as J (in amp/m2) we can write:



Ampere's Circuital Law:


Applications of Ampere's law:


We illustrate the application of Ampere's Law with some examples.
 

Example 4.3: We consider the cross section of an infinitely long coaxial conductor, the inner conductor carrying a current I and outer conductor carrying current - I as shown in figure 4.6.

Magnetic Flux Density: 


In the case of electrostatic field, we have seen that if the surface is a closed surface, the net flux passing through the surface is equal to the charge enclosed by the surface. In case of magnetic field isolated magnetic charge (i. e. pole) does not exist. Magnetic poles always occur in pair (as N-S). For example, if we desire to have an isolated magnetic pole by dividing the magnetic bar successively into two, we end up with pieces each having north (N) and south (S) pole as shown in Fig. 4.7 (a). This process could be continued until the magnets are of atomic dimensions; still we will have N-S pair occurring together. This means that the magnetic poles cannot be isolated.
Similarly if we consider the field/flux lines of a current carrying conductor as shown in Fig. 4.7 (b), we find that these lines are closed lines, that is, if we consider a closed surface, the number of flux lines that would leave the surface would be same as the number of flux lines that would enter the surface.

From our discussions above, it is evident that for magnetic field,
which is the Gauss's law for the magnetic field.

By applying divergence theorem, we can write:
which is the Gauss's law for the magnetic field in point form.

Magnetic Scalar and Vector Potentials:


In studying electric field problems, we introduced the concept of electric potential that simplified the computation of electric fields for certain types of problems. In the same manner let us relate the magnetic field intensity to a scalar magnetic potential and write:
This point can be illustrated as follows. Let us consider the cross section of a coaxial line as shown in fig 4.8.
We now introduce the vector magnetic potential which can be used in regions where current density may be zero or nonzero and the same can be easily extended to time varying cases. The use of vector magnetic potential provides elegant ways of solving EM field problems.


Computing similar solutions for other two components of the vector potential, the vector potential can be written as
Vector potential thus have the physical significance that its integral around any closed path is equal to the magnetic flux passing through that path.

Boundary Condition for Magnetic Fields:


Similar to the boundary conditions in the electro static fields, here we will consider the

That is, the normal component of the magnetic flux density vector is continuous across the interface.

In vector form,
To determine the condition for the tangential component for the magnetic field, we consider a closed path C as shown in figure 4.8. By applying Ampere's law we can write
i.e., tangential component of magnetic field component is discontinuous across the interface where a free surface current exists.

If Js = 0, the tangential magnetic field is also continuous. If one of the medium is a perfect conductor Js exists on the surface of the perfect conductor.
In vector form we can write,


ASSIGNMENT PROBLEMS

1. An infinitely long conductor carries a current I A is bent into an L shape and placed as shown in Fig. P.4.7. Determine the magnetic field intensity at a point P (0,0, a).