application of partial differentiation
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Transcript of application of partial differentiation
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Presentation on Application of Partial
Differentiation
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Geometrical Meaning of Partial Derivative
The figure shows a plane y=b intersects the surface z=f(x, y) in the curve APCB. then (¶z/¶x)y denotes the tangent of the angle which the tangent to the curve in which plane y=b meets the surface z=f(x,y) makes with the +ve direction of the x-axis.
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TANGENT
The equation of the tangent plane
to the surface F(x,y,z)=0 is
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NORMAL
Equation of the normal at (x1,y1,z1) is
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Example of tangent and normal
Find the equation of the tangent plane and normal line to the surface xyz=a3 at (x1,y1,z1)
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Taylor’s theorem for a function of two variables
Taylor’s theorem for a function of a single variable x, we have
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Continue……
Cor.1. putting x=a and y=b in Taylor's
theorem, we have
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Continue….
In Cor.1. putting a+h=x and b+y=k so that
h=x-a and y=b-k
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Maclaurin’s theorem
In Cor.2. put a=0,b=0,we have
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Example…
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Errors and Approximations
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Errors and Approximations
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Example
What error in the common logarithm of a number will be produced by an error of 1% in the number.?
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Maximum and Minimum values
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Maximum and Minimum values
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Local Maximum Value
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Local minimum value
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Maximum and minimum values
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Working rule to find the extreme values of a function z=f(x,y)
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Lagrange’s method of undetermined Multipliers
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Advantages of Lagrange’s method
1. The stationary values of f(x,y,z) can be determined directly even without determining x,y,z explicitly
2. This method can be extended to a function of several variables and subject to any number of constraints.
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Disadvantages of LaGrange's method
1. This method does not enable us to find whether stationary point in maximum and minimum. Further investigations are needed.
2. The only necessary condition but not sufficient condition is