Sunday, January 26, 2020

CURVE TRACING EXAMPLE 6


Given equation of the curve is

{y^2} = {x^2}\left( {\frac{{a - x}}{{a + x}}} \right)

Symmetry

 1.Replace y by -y in the equation of the given curve.

\begin{array}{l} {\left( { - y} \right)^2} = {x^2}\left( {\frac{{a - x}}{{a + x}}} \right)\\ \Rightarrow {y^2} = {x^2}\left( {\frac{{a - x}}{{a + x}}} \right) \end{array}

which is same as the equation of the given curve.
So, the curve is symmetric about the x-axis.

2.Replace x by -x in the equation of the given curve.

{y^2} = {\left( { - x} \right)^2}\left( {\frac{{a - \left( { - x} \right)}}{{a + \left( { - x} \right)}}} \right)
\Rightarrow {y^2} = {x^2}\left( {\frac{{a + x}}{{a - x}}} \right)
which is same as the equation of the given curve.
So the curve is not symmetric about the y-axis and neither about the opposite quadrants.

3.Interchange y and x in the equation of the given curve.

{y^2} = {x^2}\left( {\frac{{a + x}}{{a - x}}} \right)
\Rightarrow {x^2} = {y^2}\left( {\frac{{a + y}}{{a - y}}} \right)
which is not same as the equation of the given curve.
So the curve is not symmetric about the line y=x.

4.Interchange y and -x along with -y and x in the equation of the given curve.

{\left( { - x} \right)^2} = {\left( { - y} \right)^2}\left( {\frac{{a - y}}{{a + y}}} \right)
\Rightarrow {x^2} = {y^2}\left( {\frac{{a + y}}{{a - y}}} \right)

which is not same as the equation of the given curve.
So the curve is not symmetric about the line y=-x.

Check for Origin

 Replace (x,y) instead of (0,0) in the equation of the given curve.

{0^2} = {0^2}\left( {\frac{{a + 0}}{{a - 0}}} \right)
\Rightarrow 0 = 0.______________________(1)

The given equation of the curve can also be written as

\begin{array}{l} {y^2}\left( {a + x} \right) = {x^2}\left( {a - x} \right)\\ {x^2}a - {y^2}a - {x^3} - {y^2}x = 0 \end{array}

Equating the lowest degree terms to zero

{x^2} - {y^2} = 0
\left( {x - y} \right)\left( {x + y} \right) = 0_______________________(2)

From (1) and (2) the curve passes through the origin and (x-y=0) and (x+y=0) are the tangents thereat.

Point of Intersection with the x- axis and the y-axis

 Put x=0 in the equation

{x^2}a - {y^2}a - {x^3} - {y^2}x = 0__________________________(3)

we get

y=0.

The curve meets y-axis at the origin only.

Putting y=0 in equation (3)

 we get

{x^2}a - {x^3} = 0

x = 0,a

The curve meets x-axis at (a,0) and at origin.

Asymptotes

Equate the highest degree term of y to zero in

{x^2}a - {y^2}a - {x^3} - {y^2}x = 0

which leads us to

\left( {x + a} \right) = 0

is the asymptote parallel to y-axis.

Equate the highest degree term of x to zero in

{x^2}a - {y^2}a - {x^3} - {y^2}x = 0

which leads us to

-1=0

which is not true.

So there are no asymptotes parallel to the x-axis.

Domain

 The region in which the curve lies is defined as follows,

 y = x\sqrt {\frac{{a - x}}{{a + x}}}

The curve is defined in the region

\left( { - a,a} \right]

Intervals of increase and decrease

 Given equation of the curve is

{y^2} = {x^2}\left( {\frac{{a - x}}{{a + x}}} \right)

Differentiating,

2y\frac{{dy}}{{dx}} = \frac{{2{a^2}x - 2a{x^2} - 2{x^3}}}{{{{\left( {a + x} \right)}^2}}}
2y\frac{{dy}}{{dx}} = \frac{{ - 2x\left( {{x^2} + xa - {a^2}} \right)}}{{{{\left( {a + x} \right)}^2}}}

In the domain the curve increases in the interval,

\left( { - a,0.618a} \right)

and decreases in the interval

\left( {0.618a,a} \right).
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