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Determine number of intersection if they exist, determine the point of intersection. Only for ii)

Determine number of intersection if they exist, determine the point of intersection-example-1
User Scrineym
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1 Answer

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Step-by-step explanation

In this problem, we have to:

• a) determine the number of intersections between two functions,

,

• b) find the points of intersection.

The discriminant of a polynomial y = ax² + bx + c is given by:


\Delta=b^2-4ac.

According to the value of the discriminant, we have:

• for Δ > 0 ⇒ two solutions,

,

• for Δ = 0 ⇒ one solution,

,

• for Δ < 0 ⇒ no solutions.

The solutions for y = 0 are given by:


x=(-b\pm√(\Delta))/(2a).

ii) We have the functions:


\begin{gathered} f(x)=5x^2-x+1, \\ g(x)=2x+3. \end{gathered}

(a) At the intersection of the functions, we have:


\begin{gathered} f(x)=g(x), \\ 5x^2-x+1=2x+3, \\ 5x^2-3x-2=0. \end{gathered}

Comparing this polynomial with the general equation from above, we see that:

• a = 5,

,

• b = -3,

,

• c = -2.

To find the number of intersections, we compute the discriminant of this polynomial:


\Delta=(-3)^2-4\cdot5\cdot(-2)=9+40=49>0\Rightarrow\text{ two solutions.}

So we have two intersections.

(b) The values of x at the intersections are:


x=(-(-3)\pm√(49))/(2\cdot5)=(3\pm7)/(10)\Rightarrow\begin{cases}x_1=\text{ }{1} \\ x_2={-(2)/(5)}.\end{cases}

Replacing these values in the equation of one of the polynomials, we get:


\begin{gathered} (x_1,y_1)=(1,2\cdot1+3)=(1,5), \\ (x_2,y_2)=(-(2)/(5),2\cdot(-(2)/(5))+3)=(-(2)/(5),(11)/(5))=(-0.4,2.2). \end{gathered}Answer

(ii)

• (a) There are 2 intersections

,

• (b) The intersections are (1,5) and (-0.4, 2.2)

User Rld
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