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MULTIVARIABLEINTEGRALS
(JM)
Introduction• The multivariable integral is the definite
integral of functions of more than one real variable, for example, f(x, y) or f(x, y, z). Integrals of a function of two variables over a region are called double integrals, and integrals of a function of three variables over a region are called triple integrals.
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Interpretation• A single variable integral is the area under the curve. So, the multivariable
integral can be interpretated as volume under a 3D curve.• Consider a single variabled definite integral
• This is the area under the curve f(x) from x=a to x=b.
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Interpretation• The definite integral can be extended to functions of more than one
variable. Consider a function of 2 variables z=f(x,y). The definite integral is denoted by
• where R is the region of integration in the xy-plane.
• Here the curve is the graph of the function z=f(x,y). Then, the integral gives the volume of the space underneath it.
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Calculation• A multivariable integral is calculated as an ilterated integral.• This is similar to how we can compute partial derivatives by using our one-
variable differentiation rules. The trick in computing partial derivatives was treating all the other variables as constant. we use a similar trick to compute iterated integrals.
• First we integrate wrt x and treat y as constant and then vise versa. The process can be extended to how ever many variables the function depends upon.
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Example• Compute the integral
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APPLICATIONS
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1)Mass of 2D object• We can calculate the mass of a 2 dimensional object using double integral
if we know the function of its density.
• Let ρ(x,y) be the density of a lamina (flat sheet) R at the point (x,y). ρ(x,y)=lim∆m /∆A
• where ∆m and ∆A are the mass and area of a small rectangle that contains (x,y)
• Therefore we arrive at the definition of total mass in the lamina. All one has to do is find the double integral of the density function.
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Example• Let there is a thin metal plate that covers the
triangular region shown below. If the density in the plate is measured by ρ(x,y)=10-4x-2y
• Let the diagram shows the region the object covers.• Mass
So, mass is 25/3 units
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2)Center of mass in 2D
• Many structures and mechanical systems behave as if their masses were concentrated at at single point, called the centre of mass. It is important to locate this point so that we can better understand the behavior of our structure or system.
• Formula for center of mass is:
• Here M is the mass given by• And Mx and My are given by
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Example• Let we have to calculate the center of gravity of an object whose density is
given by:• we know mass of the object will be:
• we have
• These evaluate to: Mx=5k/12 , My=5k/12
• Putting all these values in formula we get the center of gravity as:
(x,y)=(5/8,5/8) This tells us that the metal plate will balance perfectly if we place a pin at
(5/8,5/8)
3)Indefinite Integral Displacement from Velocity, and
Velocity from Acceleration
• We can find an expression for velocity of a moving car by differentiating the expression for displacement:
• Similarly, we can find the expression for the acceleration by differentiating the expression for velocity, and this is equivalent to finding the second derivative of the displacement:
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• It follows (since integration is the opposite process to differentiation) that to obtain the displacement, s of an object at time t (given the expression for velocity, we would use:
• Similarly, the velocity of an object at time t with acceleration a, is given by:
• A car starts from rest at s=3 m from the origin and has acceleration at time t given by a=2t−5 ms −². Find the velocity and displacement of the car at t=4 s.
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EXAMPLE
GRAPHS• The graphs of the acceleration, velocity and displacement at
time t, indicating the velocity and displacement at t=4
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4)Area between 2 curves using integration
Area bounded by the curves y1 and y2 and the lines
x=a ,x=b.
• Curved surfaces are very common in our everyday life. Let there is a bridge whose pillars are curved and we need to find the area between two curved pillars in order to determine weather a car will be able to pass through or not.
• Then lets say the two curves are given by:
• We see that if we subtract the area under lower curve from the area under upper curve
We get required area.
• This can be achieved in one step easily if we use integration like so:
Example:Graph of y=x³showing portion bounded by x=0 and y=3
We will use
And use the horizontal elementsin this case c=0 and d=3we need to express in terms of x and y
5)Arc Length Of Curve: Parametric:
• We can find the length of an arc by using integrals.
•This application is useful in situations that involve curved paths e.g race car tracks
ExampleExample - Race TrackA race car was travelling around a curve described in
parametric equations as:x(t)=20+0.2t³y(t)=20t-2t²where x and y are in meters and t is time in seconds.What is the distance travelled by the car in the first 8
seconds?
Solution:
Graph:
length=144.7 m.
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7)Work Done• The work (W) done by a constant force (F) acting on a
body by moving it through a distance (d) is given by: W = F × d• The general definition of work done by a force must
take into account the fact that the force may vary in both magnitude and direction, and that the path followed may also change in direction. All these things can be taken into account by defining work as an integral.
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CONCLUSION• Integrals have many real life applications.• We can find masses of 2 dimensional objects like a sheet of
metal.• We can also find the center of mass of an object like a disc.• Acceleration and velocity of moving objects like cars can also
be found using integrals.• The arc length of a curve like a portion of race car track can
also be found using integrals. • Work done by a variable force or in a variable direction can be
found using integrals.
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