Quadratic Equations, SPM Practice (Paper 2)

Posted on April 18, 2020 by user

Question 4:
It is given α and β are the roots of the quadratic equation x (x – 3) = 2k – 4, where k is a constant.

\begin{array}{l} (a) Find the range of values of k if α \neq β . \\ (b) Given \frac{α}{2} and \frac{β}{2} are the roots of another quadratic equation \\ 2 x^{2} + t x - 4 = 0, where t is a constant, find the value of t and of k . \end{array}

Solution:

\begin{array}{l} (a) \\ x (x - 3) = 2 k - 4 \\ x^{2} - 3 x + 4 - 2 k = 0 \\ a = 1, b = - 3, c = 4 - 2 k \\ b^{2} - 4 a c > 0 \\ {(- 3)}^{2} - 4 (1) (4 - 2 k) > 0 \\ 9 - 16 + 8 k > 0 \\ 8 k > 7 \\ k > \frac{7}{8} \end{array}

\begin{array}{l} (b) \\ From the equation x^{2} - 3 x + 4 - 2 k = 0, \\ α + β = - \frac{b}{a} \\ = - \frac{- 3}{1} \\ = 3............. (1) \\ α β = \frac{c}{a} \\ = \frac{4 - 2 k}{1} \\ = 4 - 2 k ............. (2) \\ From the equation 2 x^{2} + t x - 4 = 0, \\ \frac{α}{2} + \frac{β}{2} = - \frac{t}{2} \\ α + β = - t ............. (3) \\ \frac{α}{2} \times \frac{β}{2} = - \frac{4}{2} \\ α β = - 8............. (4) \\ Substitute (1) = (3), \\ 3 = - t \\ t = - 3 \\ Substitute (2) = (4), \\ 4 - 2 k = - 8 \\ 4 + 8 = 2 k \\ k = 6 \end{array}

Quadratic Equations, SPM Practice (Paper 2)

Posted on April 18, 2020 by user

2.10.2 Quadratic Equations, SPM Practice (Paper 2)

Question 3:

If α and β are the roots of the quadratic equation 3x² + 2x– 5 = 0, form the quadratic equations that have the following roots.

\begin{array}{l} (a) \frac{2}{α} and \frac{2}{β} \\ (b) (α + \frac{2}{β}) and (β + \frac{2}{α}) \end{array}

Solution:

3x² + 2x – 5 = 0

a = 3, b = 2, c = –5

The roots are α and β.

\begin{array}{l} α + β = - \frac{b}{a} = - \frac{2}{3} \\ α β = \frac{c}{a} = \frac{- 5}{3} \end{array}

(a)

\begin{array}{l} The new roots are \frac{2}{α} and \frac{2}{β} . \\ Sum of new roots \\ = \frac{2}{α} + \frac{2}{β} = \frac{2 β + 2 α}{α β} \\ = \frac{2 (α + β)}{α β} = \frac{2 (- \frac{2}{3})}{- \frac{5}{3}} = \frac{4}{5} \end{array}

\begin{array}{l} Product of new roots \\ = (\frac{2}{α}) (\frac{2}{β}) = \frac{4}{α β} \\ = \frac{4}{- \frac{5}{3}} = - \frac{12}{5} \end{array}

Using the formula, x²– (sum of roots)x + product of roots = 0

The new quadratic equation is

x^{2} - (\frac{4}{5}) x + (- \frac{12}{5}) = 0

5x² – 4x– 12 = 0

(b)

\begin{array}{l} The new roots are (α + \frac{2}{β}) and (β + \frac{2}{α}) . \\ Sum of new roots \\ = (α + \frac{2}{β}) + (β + \frac{2}{α}) \end{array}

\begin{array}{l} = α + β + (\frac{2}{α} + \frac{2}{β}) = α + β + \frac{2 α + 2 β}{α β} \\ = α + β + \frac{2 (α + β)}{α β} \\ = \frac{4}{5} + \frac{2 (\frac{4}{5})}{- \frac{12}{5}} \\ = \frac{4}{5} - \frac{2}{3} = \frac{2}{15} \end{array}

\begin{array}{l} Product of new roots \\ = (α + \frac{2}{β}) (β + \frac{2}{α}) \\ = α β + 2 + 2 + \frac{4}{α β} \end{array}

\begin{array}{l} = - \frac{12}{5} + 4 + \frac{4}{- \frac{12}{5}} \\ = - \frac{12}{5} + 4 - \frac{5}{3} = - \frac{1}{15} \end{array}

The new quadratic equation is

x^{2} - (\frac{2}{15}) x + (- \frac{1}{15}) = 0

15x² – 2x– 1 = 0

Quadratic Equations, SPM Practice (Paper 2)

Posted on April 18, 2020 by user

Question 2:

Given α and β are two roots of the quadratic equation (2x + 5)(x + 1) + p = 0 where αβ = 3 and p is a constant.

Find the value p, α and of β.

Solutions:

(2x + 5)(x + 1) + p = 0

2x² + 2x + 5x + 5 + p = 0

2x² + 7x + 5 + p = 0

*Compare with, x²– (sum of roots)x + product of roots = 0

x^{2} + \frac{7}{2} x + \frac{5 + p}{2} = 0 \leftarrow \begin{array}{l} divide both \\ sides with 2 \end{array}

Product of roots, αβ = 3

\frac{5 + p}{2} = 3

5 + p = 6

p = 1

Sum of roots =

- \frac{7}{2}

\begin{array}{l} α + β = - \frac{7}{2} \to (1) \\ and α β = 3 \to (2) \\ from (2), β = \frac{3}{α} \to (3) \\ Substitute (3) into (1), \\ α + \frac{3}{α} = - \frac{7}{2} \end{array}

2α²+ 6 = –7α ← (multiply both sides with 2α)

2α²+ 7α + 6 = 0

(2α + 3)(α + 2) = 0

2α + 3 = 0 or α + 2 = 0

α=− 3 2 α = –2

\begin{array}{l} Substitute α = - \frac{3}{2} into (3), \\ β = \frac{3}{- \frac{3}{2}} = 3 (- \frac{2}{3}) = - 2 \end{array}

Substitute α = –2 into (3),

\begin{array}{l} β = - \frac{3}{2} \\ ∴ p = 1, and \\ when α = - \frac{3}{2}, β = - 2 and α = - 2, β = - \frac{3}{2} . \end{array}

Quadratic Equations, SPM Practice (Paper 2)

Posted on April 18, 2020 by user

2.10.1 Quadratic Equations, SPM Practice (Paper 2)

Question 1:

(a) Find the values of k if the equation (1 – k) x²– 2(k + 5)x + k + 4 = 0 has real and equal roots.

Hence, find the roots of the equation based on the values of k obtained.

(b) Given the curve y = 5 + 4x – x²has tangen equation in the form y = px + 9. Calculate the possible values of p.

Solutions:

(a)

For equal roots,

b²– 4ac = 0

[–2(k + 5)]² – 4(1 – k)( k + 4) = 0

4(k + 5)²– 4(1 – k)( k + 4) = 0

4(k² + 10k + 25) – 4(4 – 3k – k²) = 0

4k² + 40k + 100 – 16 + 12k + 4k² = 0

8k² + 52k + 84 = 0

2k² + 13k + 21 = 0

(2k + 7) (k + 3) = 0

k = - \frac{7}{2}, - 3

k = - \frac{7}{2}

, the equation is

\begin{array}{l} (1 + \frac{7}{2}) x^{2} - 2 (- \frac{7}{2} + 5) x - \frac{7}{2} + 4 = 0 \\ \frac{9}{2} x^{2} - 3 x + \frac{1}{2} = 0 \end{array}

9x² – 6x + 1 = 0

(3x – 1) (3x – 1) = 0

x = ⅓

If k = –3, the equation is

(1 + 3)x²– 2(–3 + 5)x – 3 + 4 = 0

4x² – 4x + 1 = 0

(2x – 1) (2x – 1) = 0

x = ½

(b)

y = 5 + 4x – x²----- (1)

y = px + 9 ---------- (2)

(1) = (2), 5 + 4x – x²= px + 9

x² + px – 4x + 9 – 5 = 0

x² + (p – 4)x + 4 = 0

Tangen equation only has one intersection point with equal roots.

b²– 4ac = 0

(p – 4)² – 4(1)(4) = 0

p² – 8p + 16 – 16 = 0

p² – 8p = 0

p (p – 8) = 0

Therefore, p = 0 and p = 8.

2.2a Solving Quadratic Equations – Factorisation

Posted on April 18, 2020 by user

2.4.1 Solving Quadratic Equations – Factorisation

1. If a quadratic equation can be factorised into a product of two factors such that

(x – p)(x – q) = 0

Hence

x – p = 0 or x – q = 0

x = p or x = q

p and q are the roots of the equation.

Notes
1.The equation must be written in general form ax² + bx+ c = 0 before factorisation.

2. This method can only be used if the quadratic expression can be factorised completely.

Example 1:
Find the roots of the quadratic equations
(a) x (2x − 8) = 0
(b) x² −16x = 0
(c) 3x² − 75x = 0
(d) 5x² − 100x = 25x

Solution:

(a)

x (2x − 8) = 0

x = 0 or 2x − 8 = 0

2x − 8 = 0

2x = 8

x= 4

x = 0 or x = 4

(b)

x² −16x = 0

x (x − 16) = 0

x = 0 or x − 16 = 0

x = 0 or x = 16

(c)

3x² − 75x = 0

3x (x − 25) = 0

3x = 0 or x − 25 = 0

x = 0 or x = 25

(d)

5x² − 100x = 25x

5x² − 100x − 25x = 0
5x² − 125x = 0

x (5x − 125) = 0

x = 0 or 5x − 125 = 0

5x = 125

x = 25

x = 0 or x = 25

Example 2:

Solve the following quadratic equations
(a) x² − 4x – 5 = 0
(b) 1 − 5x + 2x² = 4

Solution:

(a)

x² − 4x – 5 = 0
(x – 5) (x + 1) = 0

x – 5 = 0 or x + 1 = 0

x = 5 or x = –1

(b)

1 − 5x + 2x² = 4

2x² − 5x + 1 – 4 = 0

2x² − 5x – 3 = 0

(2x + 1) (x – 3) = 0

2x + 1= 0 or x – 3 = 0

2x = –1 or x = 3

x = –½ or x = 3

Roots of Quadratic Equations

Posted on April 18, 2020 by user

Roots of Quadratic Equations

Roots of a quadratic equation are the values of variables/unknowns that satisfy the equation.

Example:
Determine whether 1, 2, and 3 are the roots of the quadratic equation

x^{2} - 5 x + 6 = 0

.

Answer:
When x = 1,

\begin{array}{l} x^{2} - 5 x + 6 = 0 \\ (1)^{2} - 5 (1) + 6 = 0 \\ 2 = 0 \end{array}

x = 1 does not satisfy the equation

When x = 2,

\begin{array}{l} x^{2} - 5 x + 6 = 0 \\ (2)^{2} - 5 (2) + 6 = 0 \\ 0 = 0 \end{array}

x = 2 satisfies the equation.

When x = 3

\begin{array}{l} x^{2} - 5 x + 6 = 0 \\ (3)^{2} - 5 (3) + 6 = 0 \\ 0 = 0 \end{array}

x = 3 satisfies the equation.

Conclusion:

2 and 3 satisfy the equation $x^{2} - 5 x + 6 = 0$ , hence there are the roots of the equation.
1 does not satisfy the equation $x^{2} - 5 x + 6 = 0$ , hence it is NOT the root of the equation.

SPM Practice (Long Question)

Posted on April 18, 2020 by user

Question 3:
Given that f : x → hx + k and f² : x → 4x + 15.
(a) Find the value of h and of k.
(b) Take the value of h > 0, find the values of x for which f (x² ) = 7x

Solution:
(a)
Given f (x) = hx + k
f² (x) = ff (x) = f (hx + k)
= h (hx + k) + k
= h² x + hk + k

f² (x) = 4x + 15
h² x + hk + k = 4x + 15
h² = 4
h = ± 2
when, h = 2
hk + k = 15
2k + k = 15
k = 5

When, h = –2
hk + k = 15
–2k + k = 15
k = –15

(b)
h > 0, h = 2, k = 5
Given f (x) = hx + k
f (x) = 2x + 5 f (x² ) = 7x
2 (x² ) + 5 = 7x
2x² – 7x + 5 = 0
(2x – 5)(x –1) = 0
2x – 5 = 0 or x –1= 0
x = 5/2 x = 1

SPM Practice (Long Question)

Posted on April 18, 2020 by user

Question 1:
The function f and g is defined by

\begin{array}{l} f : x \mapsto 2 x - 3 \\ g : x \mapsto \frac{2}{x}; x \neq 0 \end{array}

Find the expression for each of the following functions
(a) ff,
(b) gf,
(c) f^-1 ,
Calculate the value of x such that ff(x) = gf(x).

Solution:
(a)

\begin{array}{l} f f (x) = f [f (x)] \\ = f (2 x - 3) \\ = 2 (2 x - 3) - 3 \\ = 4 x - 9 \\ f f : x \mapsto 4 x - 9 \end{array}

(b)

\begin{array}{l} g f (x) = g [f (x)] \\ = g (2 x - 3) \\ = \frac{2}{2 x - 3} \\ g f : x \mapsto \frac{2}{2 x - 3} \end{array}

(c)

\begin{array}{l} Let f^{- 1} (x) = y, \\ thus f (y) = x \\ 2 y - 3 = x \\ y = \frac{x + 3}{2} \\ ∴ f^{- 1} (x) = \frac{x + 3}{2} \\ f^{- 1} : x \mapsto \frac{x + 3}{2} \\ When f f (x) = g f (x), \\ 4 x - 9 = \frac{2}{2 x - 3} \\ (4 x - 9) (2 x - 3) = 2 \\ 8 x^{2} - 30 x + 27 = 2 \\ 8 x^{2} - 30 x + 25 = 0 \\ (4 x - 5) (2 x - 5) = 0 \\ 4 x - 5 = 0 or 2 x - 5 = 0 \\ x = \frac{5}{4} or x = \frac{5}{2} \end{array}

SPM Practice (Short Question)

Posted on April 18, 2020 by user

Question 1:
Given the function g : x → 3x – 2, find
(a) the value of x when g(x) maps onto itself,
(b) the value of k such that g(2 – k) = 4k.

Solution:
(a)

\begin{array}{l} g (x) = x \\ 3 x - 2 = x \\ 3 x - x = 2 \\ 2 x = 2 \\ x = 1 \end{array}

(b)

\begin{array}{l} g (x) = 3 x - 2 \\ g (2 - k) = 4 k \\ 3 (2 - k) - 2 = 4 k \\ 6 - 3 k - 2 = 4 k \\ - 7 k = - 4 \\ k = \frac{4}{7} \end{array}

Question 2:
Given the functions f : x → px + 1, g : x → 3x – 5 and fg(x) = 3px + q.
Express p in terms of q.

Solution:

\begin{array}{l} f (x) = p x + 1, g (x) = 3 x - 5 \\ f g (x) = p (3 x - 5) + 1 \\ = 3 p x - 5 p + 1 \\ Given f g (x) = 3 p x + q \\ 3 p x - 5 p + 1 = 3 p x + q \\ - 5 p + 1 = q \\ - 5 p = q - 1 \\ 5 p = 1 - q \\ p = \frac{1 - q}{5} \end{array}

Question 3:
Given the functions h : x → 3x + 1, and gh : x → 9x² + 6x – 4, find
(a) h^-1 (x),
(b) g(x).

Solution:
(a)

\begin{array}{l} Let h^{- 1} (x) = y, \\ thus h (y) = x \\ 3 y + 1 = x \\ 3 y = x - 1 \\ y = \frac{x - 1}{3} \\ ∴ h^{- 1} (x) = \frac{x - 1}{3} \\ h^{- 1} : x \mapsto \frac{x - 1}{3} \end{array}

(b)

\begin{array}{l} g [h (x)] = 9 x^{2} + 6 x - 4 \\ g (3 x + 1) = 9 x^{2} + 6 x - 4 \\ Let y = 3 x + 1 \\ thus x = \frac{y - 1}{3} \\ g (y) = 9 {(\frac{y - 1}{3})}^{2} + 6 (\frac{y - 1}{3}) - 4 \\ = \frac{9 {(y - 1)}^{2}}{9} + 2 (y - 1) - 4 \\ = y^{2} - 2 y + 1 + 2 y - 2 - 4 \\ = y^{2} - 5 \\ ∴ g (x) = x^{2} - 5 \end{array}

Inverse Function Example 4

Posted on April 18, 2020 by user

Example 4:

(a) If f : x \to x - 2, find f^{- 1} (5),

(b) if f : x \to \frac{x + 9}{x - 5}, x \neq 5, find f^{- 1} (3) .

Solution:

(a)

f (x) = x– 2

Let y = f ^-1(5)

f (y) = 5

y – 2 = 5

y = 7

therefore, f ^-1(5) = 7

(b)

\begin{array}{l} f (x) = \frac{x + 9}{x - 5} \\ Let y = f^{- 1} (3) \\ f (y) = 3 \\ \frac{y + 9}{y - 5} = 3 \\ y + 9 = 3 y - 15 \\ 2 y = 24 \\ y = 12 \\ ∴ f^{- 1} (3) = 7 \end{array}