Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) PDF Download

In the last lecture we defined the curl of a vector field as a ratio of the line integral over the boundary of an open surface to the area of the surface, in the limit of the surface becoming infinitesimally small. The direction of the curl was defined as along the outward normal to the surface element. This definition resulted in relating the line integral to the surface integral of the curl of the vector, known as the Stoke’s Theorem :

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

It may be noted that the surface must be an open surface defined by the contour over which the line integral is taken. Note that a given contour does not uniquely specify a surface. For instance, if the contour is a circle, it can define a disk, an open cylinder or any number of other surfaces. It is important to realize that the surface is arbitrary as long as it is bounded by the given curve. This enables us to choose the most convenient surface to evaluate such integrals.

We will now obtain an expression for the curl in the Cartesian coordinates. Consider a rectangular contour ABCD in the yz plane, as shown. Let us consider the rectangular surface bounded by this contour. The direction of the surface is clearly along the positive x direction.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Let us calculate the line integral of a vector field  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) over this contour. We will enumerate the line integral over the paths AB, BC, CD and DA. Let the corner A have the coordinates (0, y,z). On the path AB, the line integral is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) where, we have assumed that over the short length ∆y, the value of the function does not vary much. Likewise, over the path CD, the contribution to the line integral is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) the minus sign appears because the path is traversed in the opposite direction to the path AB. Note that the paths AB and CD differ by having different z components, and, we can express  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) plus terms which are of the order of ∆z or its higher powers. By retaining only the first power in a Taylor expansion, we can write Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus the contribution from these two paths to the line integral is given by Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) We can do a similar computation of the contribution to the line integral from the pair of paths BC and DA and obtain, Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The net line integral over the path ABCD works out to Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

On the other hand, the surface integral of the curl is given by  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) These two, by Stoke’s theorem must be equal. Thus we have, for the x-component of the curl of  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

One can similarly obtain the y and z components of the curl of the vector field Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) as follows

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

One can observe that the right hand side looks very much like a cross product of vectors, excepting that the first vector seems to have differential operators  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) as its components. This of course is the familiar gradient operator that we have met before. The curl, therefore, is also written as  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) One can write the components of a curl as a determinant, the way we express cross products of vectors :

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Why do we call it curl? Remember that a lot of terminology of vector calculus developed from fluid dynamics. “Curl”, as the name suggests gives the direction of rotation of a fluid (i.e. which direction does the fluid curl) at a point. The magnitude of the curl is the magnitude of rotation and its direction is given by the direction of the axis of rotation. To illustrate it consider what happens when we put a paddle wheel inside a liquid. The wheel would rotate if the velocity field has a nonzero curl in the direction determined by the variation of the velocity components of the fluid.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Example :

Consider a vector field  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Calculate its curl. Calculation is straightforward.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

The curl is constant in magnitude and direction. The picture of the field is shown below

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

The force field is in the xy plane but the curl is in the z direction as the sense of rotation of the field is like a rotation about the z-axis.

Curl of a conservative field is zero :

This is an important result as it provides a test for whether a vector field is conservative or not. We know that a conservative field can be expressed as the gradient of a scalar field. It can be easily shown that the curl of a gradient is identically zero. (This is left as an exercise for the tutorial.) Because of this, a conservative field is also called an “irrotational” field.

Example 1:A vector field is given by  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Show that the field is conservative. Obtain a scalar potential for this field.
We show that the x-component of the curl is zero. One can check similarly for the other components.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

The field is conservative. To obtain a scalar potential ϕ, we note the following :

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Using these relations we can get an unique expression for the scalar potential ϕ, but for a constant (which we have taken to be zero)

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Thus curl Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
(1) the line integral  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
(2) The integral  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) is independent of the path connecting A and B and only depends on the two end points A and B.
(3)  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) be written as a gradient of a scalar potential  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Example 2: Use Stoke’s theorem to calculate the line integral of  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) over the path shown below. The contour defines the first quadrant of a circle of radius R.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Let us first calculate the line integral by direct integration. Along OA, y=0, z=0 and  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The line element is along the x direction Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Similarly, from B to O the integral is also zero. We only need to evaluate the integral along the circular arc from A to B. We can parameterize the curve in polar coordinates Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) the line element vector, which has a magnitude Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) giving

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

We will now verify this result by calculating the line integral using the Stoke’s theorem. The curl of the given vector field is easily computed to be  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) which gives the surface integral of the curl to be Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) consistent with the result obtained by direct evaluation of the line integral.

Example 3: Find the line integral of Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) over a circle of radius R in the xy plane centered at the origin.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

We choose the surface defined by the circle to be the disk of radius R in the xy plane. Since the cdisk is in the xy plane, the outward surface normal is along the z-direction. Thus the surface integral of the curl is given by  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) You may find it instructive to calculate the line integral by a direct substitution using the parameterization of the previous example.

To see that the choice of surface is unimportant, as long as it is defined by the same boundary, let us take the boundary to be the bottom cap of an open cylinder of height h place over it. The top cap is closed.

In this case, the cylinder has two surfaces, the top cap whose Outward normal is along the positive z direction, which clearly gives πR2 since the z component of the curl is constant. For the curved surface, the outward normal is along the polar Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) of the xy plane. The surface element is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

We can express the curl of the field in the cylindrical coordinates 

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Thus the surface integral is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The angle integral vanishes. The total surface integral is thus the contribution from the top cap, which is πR2.

Tutorial Problems :

1. Calculate the curl of the vector field  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
2. Show that the curl of a conservative vector field is zero.
3. Show that the divergence of a curl is zero.
4. Consider two different surfaces S1 and S2, both bounded by the same curve C. Show that the curl a vector field has the same surface integral over both the surfaces.
5. Using Stoke’s theorem calculate the line integral of  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) over a circle of radius R in the xy plane cantered at the origin. Take the open surface to be a hemisphere in z>0.

Solutions toTutorial Problems

1. The curl is given by 

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

2. A conservative field can be written as a gradient of a scalar field Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Using Cartesian coordinates Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Curl of this is zero, as can be seen, e.g. by calculating x component of the curl Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) It can be checked that the y and z components also vanish.
3. Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

4. 4. As S1 and S2 are both bounded by the same boundary, if we reverse the direction of the normal of one of the surfaces, say S2, the resulting surface S1-S2 is a closed surface. (This can be visualized in the figure below).

Thus  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Where the last integral is over a closed surface. Becauseof this it can be converted to a volume integral using theDivergence theorem,  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) as the divergence of a curl is identically zero. In the figure to the left, both S1 and S2 are described by the dashed contour. When the directions of the normals to S2 are reversed, the resulting surface S1-S2 is a closed surface.

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

5. The curl of the vector field is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The unit normal on the surface of the hemisphere being in the radially outward direction is given by Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus we need to calculate the surface integral  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The hemisphere being symmetrical with respect to x and y coordinates, the first two integrals vanish and we are left with Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The integral is conveniently done in spherical coordinates Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The azimuthal integral gives 2π . The surface integral is thus given by Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)The line integral can be directly calculated. Since the circle is in the xy plane, the line integral is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) 
The first and the third terms on the right give zero as z=0 on the contour. We are left with Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) which can be parameterized in polar coordinates Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) so that we get the integral to be Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

Self Assessment Quiz

1. If a vector field  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) where M, N and P are functions of x, y and z, show that the field is conservative if Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) the subscripts indicating partial differentiation with respect to these variables. Using this show that the field Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) conservative. Here Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

2. Verify Stokes theorem for the vector field Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) where the contour is a circle of radius R in the xy plane centered at the origin. Take the surfaces to be (1) a disk (2) a hemisphere Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) a right circular cone radius R and height h.

3. Evaluate Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) over a circle of radius 2 whose centre is located at (0,2,2). 

4. Show that the line integral of Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) along any closed contour is zero. 

5. Find the contour integral of  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) along a triangle whose vertices are at the points (1,0,0), (0,1,0) and (0,0,1).

Solutions toSelf Assessment Quiz

1. The curl of the given field is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus the curl becomes zero when the quantities inside each bracket vanishes. For the given vector field  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

2. Let us first calculate the line integral directly. We have  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Since the contour is in the xy plane (z=0), the second and the third integrals vanish. The first integral can be evaluated by polar parameterization Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) This gives the line integral to be  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
The curl of the given field is seen to be Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
a. For a disk, if the contour is in the xy plane and in counterclockwise direction, the outward normal is along the  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
b. For the hemisphere, the outward normal is in the radially outward direction. The unit normal is given by  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) so that the surface integral of the flux is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The integral is readily evaluated in a spherical polar coordinates Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The flux integral is thus given by -  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The first two terms are zero because the azimuthal integral vanishes .The last term gives the flux to Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
c. (this is a hard problem)

The equation to the cone is given by
Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
The normal to the surface is along the gradient of f i.e. along

Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

The area element on the surface is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) where dl is along the slant of the cone, Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus the surface integral of the curl is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Substitute  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)
Using these the surface integral becomes  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

The first two terms vanish as the azimuthal integration gives zero, leaving us with the last term, which gives - πR2.

3. The curl of the given field is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Since the contour is in the yz plane, x=0 and the normal to the disk is in the x direction. . This leaves us with a single surface integral Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The line integral is equally easy as x=0 on the contour leaving us with a single integral Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)  Since the center of the circle is at (2,2) in the yz plane, the polar parameterization is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The line integral becomes Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

4. The curl of the given field being zero, the line integral; on any closed contour which is equal to the surface integral of the curl would vanish.

5. (this is a hard problem) The line integral is easy to calculate directly. Since the corners of the triangle are at (1,0,0), (0,1,0) and (0,0,1), the equation to the plane is x+y+z=1. Defining the boundary in anticlockwise direction gives the first line in xy plane Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) second line in yz plane Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) and the third line in xz plane Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Because of the symmetry of the integrand we need to calculate any of the three line integrals and multiply by 3. Let us take the first line in xy plane with z=0. The integral is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Note that on this line x=y=1 so that the integral can be written as  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus the value of the integral over the boundary is -1. To get this result by application of Stoke’s theorem, we first calculate the curl of the field which is  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The unit normal to the surface is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus we have to evaluate Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) To evaluate this we need to take a projection of the surface into any convenient plane. Taking the projection onto xy plane for which the normal is along  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) we can write  Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Thus the surface integral is   Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) Since the equation to the plane is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) we can eliminate z and write the integral as Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The limits are as follows : Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) The integral is Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) -1.

The document Conservative Field, Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE) is a part of the Electrical Engineering (EE) Course Electromagnetic Fields Theory (EMFT).
All you need of Electrical Engineering (EE) at this link: Electrical Engineering (EE)
10 videos|45 docs|56 tests

Top Courses for Electrical Engineering (EE)

FAQs on Conservative Field, Stoke’s Theorem - Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

1. What is a conservative field?
Ans. A conservative field is a vector field in which the line integral between any two points is independent of the path taken. In other words, the work done by the field to move an object from one point to another is only dependent on the initial and final positions, not on the specific path taken.
2. How can Stoke’s Theorem be applied to a conservative field?
Ans. Stoke’s Theorem is a mathematical tool that relates the curl of a vector field to the line integral of the field over a closed curve. In the case of a conservative field, where the curl is zero, Stoke’s Theorem simplifies to the fundamental theorem of line integrals, also known as the conservative vector field theorem.
3. Can Stoke’s Theorem be used to evaluate the circulation of a conservative field?
Ans. Yes, Stoke’s Theorem can be used to evaluate the circulation of a conservative field. Since the curl of a conservative field is zero, Stoke’s Theorem states that the circulation of the field around a closed curve is zero. This provides a useful shortcut to determine if a vector field is conservative by checking if its circulation is zero.
4. What are some practical applications of Stoke’s Theorem in physics and engineering?
Ans. Stoke’s Theorem is widely used in physics and engineering to solve problems involving fluid flow, electromagnetism, and other vector field phenomena. It allows us to relate the behavior of a vector field over a closed surface to the behavior of its curl along the boundary of that surface. This has applications in fluid dynamics, electromagnetic field analysis, and the study of potential flows.
5. Can Stoke’s Theorem be used in three-dimensional space?
Ans. Yes, Stoke’s Theorem can be applied in three-dimensional space. In this case, the integral over a closed curve is replaced by an integral over a closed surface, and the curl of the vector field is integrated over the surface. Stoke’s Theorem still holds true, relating the curl of the field to the line integral of the field over the boundary of the surface. This extension of Stoke’s Theorem is particularly useful in three-dimensional fluid dynamics and electromagnetism.
10 videos|45 docs|56 tests
Download as PDF
Explore Courses for Electrical Engineering (EE) exam

Top Courses for Electrical Engineering (EE)

Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

Previous Year Questions with Solutions

,

Conservative Field

,

Objective type Questions

,

Viva Questions

,

Important questions

,

Semester Notes

,

Conservative Field

,

Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

,

mock tests for examination

,

Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

,

ppt

,

Conservative Field

,

Free

,

Extra Questions

,

MCQs

,

study material

,

pdf

,

past year papers

,

practice quizzes

,

Summary

,

Sample Paper

,

Exam

,

Stoke’s Theorem | Electromagnetic Fields Theory (EMFT) - Electrical Engineering (EE)

,

video lectures

,

shortcuts and tricks

;