answersLogoWhite

0


Best Answer

A line integral can evaluate scalar and vector field functions along a curve/path. When applied on vector field, line integral is considered as measure of the total effect of the vector field along a specific curve whereas in scalar field application, the line integral is interpreted as the area under the field carved out by a particular curve.Line integral has many applications in physics. In mechanics, line integral is used to determine work done by a force in moving an object along a curve. In circuit analysis, it is used for calculating voltage.

User Avatar

Wiki User

13y ago
This answer is:
User Avatar

Add your answer:

Earn +20 pts
Q: Discuss line integral and its real life applications?
Write your answer...
Submit
Still have questions?
magnify glass
imp
Continue Learning about Calculus

Application of definite integral in real life?

Finding the area under a curve or the length of a line segment. These are real life uses, not just fun in your math class.


How do you calculate the length of the curve using calculus?

Do a line integral.


Differential and integral calculus sixth edition by Clyde E Love and Earl D.Rainville?

the area bounded by the curve y= e-x, the axes, and the line x-2 is revolved about the x-axis. Find the volume generated


What is the geometrical interpretation of line integral?

A line integral or a path or curve integral is a function used when we integrate along a curve. The first step is to parametrize the curve if it is not already in parametric form. So let's look at a general curve, c in its parametric form. The letter t will stand for time. x=h(t) and y=g(t) so both x and y are functions of time. (We assume the curve is smooth) We will integrate over an interval [a,b] so a≤t≤b Now to understand what it means geometrically, let's look at a common geometric shape, the circle. x2 +y2 =16 is the equation of a circle centered at the origin with radius 4. We are going to integrate xy4 along half of the circle. We first need it in parametric form. So x=4cos(t) and y=4sin(t). Keep in mind this circle will be our domain. Just like we find definite integrals over an interval, we use the curve as our analogous domain. We are going to integrate over half the circle so we need to specify t so that our curve will trace out half the circle. We can let -pi/2≤t≤pi/2 Next we compute ds so we need to find dx/dt and dy/dt. So dx/dx=-4sint and dy/dt=4cost. Now we know that ds=Square root (16sin2 t + 16cos2 t)dt=4dt. ( ds is used to show we are moving along the curve) So the integral of xy4 along a general curve c, becomes the integral of cos(t)sin4 (t) dt integrated between -pi/2 to pi/2. The result of integration along this path is 8192/5 so now we ask what does this mean geometrically? (Took a bit of time to get here, but we needed the example) Imagine putting some points on the half circle curve we used. Say point 0, 1, 2, 3, 4 etc. Now draw vectors from 0 to 1, 1 to 2, 2 to 3 etc. We have partitioned our curve into subcurves, the vectors. This is like dividing an interval into the rectangles you have often seen for Riemann integrals and Riemann sums, Instead of looking at the areas of each of those rectangles, we look at the f(pn) where pn are the points 0,1,2,3 etc mentioned above. Just like we add up the sum of the areas of the rectangles for a Riemann sum, we add up the values of the function at each point on our curve, in this case a half circle. Now if we take the limit as the vectors get smaller or as the length of the subintervals along the curve tends toward 0, this is the line integral The path is being partitioned into a polygonal path. We are letting the length or mesh or the partition go to 0. You can do this in 2 or 3 dimension space and we can integrate over a vector field. This last example helps you see an even more geometric example. Sometimes the geometry is hard to see in the examples like the one I gave above. In this one, it is pretty easy. suppose we have a function of two variables that's just a sheet above the x-y plane. Let's look at f(x,y)=5 and we want to take the line integral of this function around the closed path which is the unit circle x2+y2=1. Geometrically, the line integral is the area of a cylinder of length 1 and radius 5. You can check the this is 10Pi ( remember the surface area of a cylinder is 2Pirh, which is 2Pi5x1=10Pi) This one is easier to see geometrically because f(x,y)=5 is a sheet above the x-y plane which is easy to see. If we evaluate the that along the unit circle, then we can see how the cylinder would have to be length or height 1 and radius 5 from the sheet. To tie this to what we said earlier, think of dividing the path, the unit circle, into small subpaths or polygonal paths and evaluating f(x,y)=5 on each of these path. For each one, we get a small piece of the cylinder. If you have trouble seeing this, consider the small piece of the circle between t=0 and t=pi/1000 A very small sector. Now when we look at the value of the function on that very think sector, we have a pie shaped sector with radius 5. We add up lots of these and get the cylinder. Line integrals are also commonly used to find the work done by force long a curve. One last thing to help understand the geometry. Since we talked about vectors and dividing the curve into vectors, let's look at that geometry. Of course, the dot product of any two vectors is positive if the point in the same direction and zero if they are perpendicular. It is negative it they point in roughly opposite directions. The line integral geometrically add up dot products. If F is a vector field and DeltaR is a displacement vector. We look at the dot product of F and DeltaR long the path. If the magnitude of F is constant, the line integral will be a positive number if F is mostly pointing the same way as DeltaR and negative if F is pointing in the opposite direction. If the F is perpendicular to the path at all times, the line integral has a value of zero. We should mention one last thing ( it really is the last thing) Imagine a piece of string or wire. Let that be the curve we have been talking about analogous to the half circle etc. Now suppose we have a function f(x,y) that tells us the mass of the wire or string per unit length. The mass of the string if the line integral of f(x,y) evaluated along the string. An ordinary everyday integral is of y (a function of x) which is just a sum of all the values of the thin rectangles y times dx for all the tiny pieces of dx which make up the x axis. It can be regarded as a line integral along the line known as the x axis. But you could do an integral along any other line or curve, provided you know the value of the function at all points on the line or curve. And that is called a line integral. Instead of the fragment dx, you have a fragment ds where s is your position along the line, just as x describes where you are on the x axis.


Are A line on the wall and a line on the floor are skew?

Sometimes.

Related questions

What is the definition of line integral?

It means that the integral is calculated along a given line, which may be curved.


Geometrically the definite integral gives the area under the curve of the integrand Explain the corresponding interpretation for a line integral?

gemetrically the definite integral gives the area under the curve of the integrand. explain the corresponding interpretation for a line integral.


How do you find a curved line distance?

Use a line integral.


What is the difference between definite integral and line integral?

Both kinds of integrals are essentially calculations of areas under curves. In a definite integral the surface whose area is to be calculated is planar. In a line integral the surface whose area to be calculated might occupy two or more dimensions. You might be interested in the animated diagrams in the wikipedia article for the line integral.


Application of definite integral in real life?

Finding the area under a curve or the length of a line segment. These are real life uses, not just fun in your math class.


What are practical applications of influence line diagrams?

What are the practical applications of influence line diagram


How do you calculate the length of the curve using calculus?

Do a line integral.


Show that the line integral is independent of the path?

since the line integral depends on the two values upper & lower limits and the function to which we have to integrate. the values changes only when the upper & lower limits changes, whatever the path is.


What are the applications of losses in transmission line?

There are no applications for losses, that's why they are called 'losses'!


What vehicles are required to be chocked when parked on the flight line?

Vehicles that do not have an integral braking system are required to be chocked when parked on the flight line.


Mathematical field calculus?

Calculus is mainly about limits, which in turn are used to calculate the slope of a line (known as the "derivative"; lots of applications for that), and to calculate the area under a curve (the "integral" - also lots of applications for that). For more details, read the Wikipedia article on "Calculus", or read an introductory book on calculus. As prerequisites, you should be well-acquainted with high-school algebra.


What actions are required when parking a vehicle on the flight line?

vehicles without an integral braking system.