Question 4:
Solutions by scale drawing will not be accepted.
Diagram below shows a triangle PRS. Side PR intersects the y-axis at point Q.

(a) Given PQ : QR = 2 : 3, find
(i) The coordinates of P,
(ii) The equation of the straight line PS,
(iii) The area, in unit², of triangle PRS.
(b) Point M moves such that its distance from point R is always twice its distance from point S.
Find the equation of the locus M.

Solution:
(a)(i) 
$\begin{array}{l}P=\left(\frac{2\left(6\right)+3h}{2+3},\frac{2\left(12\right)+3k}{2+3}\right)\\ \left(0,6\right)=\left(\frac{12+3h}{5},\frac{24+3k}{5}\right)\\ \frac{12+3h}{5}=0\\ 3h=-12\\ h=-4\\ \\ \frac{24+3k}{5}=6\\ \text{3}k=30-24\\ k=2\\ \\ P=\left(-4,2\right)\end{array}$

(a)(ii) 
$\begin{array}{l}{m}_{PS}=\frac{2-\left(-6\right)}{-4-2}\\ =-\frac{8}{6}\\ =-\frac{4}{3}\\ \\ \text{Equation of }PS:\\ y-y_1=-\frac{4}{3}\left(x-2\right)\\ y-\left(-6\right)=-\frac{4}{3}x+\frac{8}{3}\\ 3y+18=-4x+8\\ 3y=-4x-10\end{array}$

(a)(iii) 
$\begin{array}{l}\text{Area of }△PRS\\ =\frac{1}{2}|\begin{array}{l}-\text{4 2 6 }\\ \text{2 }-6\text{ 12 }\end{array}\begin{array}{l}-\text{4}\\ 2\end{array}|\\ =\frac{1}{2}|\left(24+24+12\right)-\left(4-36-48\right)|\\ =\frac{1}{2}|60-\left(-80\right)|\\ =70{\text{ unit}}^2\end{array}$

(b) 
$\begin{array}{l}\text{Let }P=\left(x,y\right)\\ MR=2MS\\ \sqrt{{\left(x-6\right)}^2+{\left(y-12\right)}^2}=2\sqrt{{\left(x-2\right)}^2+{\left(y+6\right)}^2}\\ {\left(x-6\right)}^2+{\left(y-12\right)}^2=4\left[{\left(x-2\right)}^2+{\left(y+6\right)}^2\right]\\ x^2-12x+36+y^2-24y+144=4\left[x^2-4x+4+y^2+12y+36\right]\\ x^2-12x+y^2-24y+180=4x^2-16x+4y^2+48y+160\\ 3x^2+3y^2-4x+72y-20=0\end{array}$

Question 3:


Solution:
(a)
$\begin{array}{l}\text{Ratio }LK:KN\\ \text{Equating the }x\text{ coordinates,}\\ \frac{LK(10)+KN(0)}{LK+KN}=4\\ 10LK=4LK+4KN\\ 6LK=4KN\\ \frac{LK}{KN}=\frac{4}{6}\\ \frac{LK}{KN}=\frac{2}{3}\\ \text{Ratio }LK:KN=2:3\end{array}$

Question 2:
(c) the coordinates of the point of intersection between lines PQ and ST produced.


Solution:
(a)
$\begin{array}{l}R=\left(\frac{3+7}{2},\frac{2+6}{2}\right)\\ R=\left(5,4\right)\end{array}$

(b)
$\begin{array}{l}QR:RT=1:3\\ \text{Lets coordinates of }T=(x,y)\\ \left(\frac{\left(1\right)\left(x\right)+\left(3\right)\left(4\right)}{1+3},\frac{\left(1\right)\left(y\right)+\left(3\right)\left(5\right)}{1+3}\right)=\left(5,\text{ 4}\right)\\ \frac{x+12}{4}=5\\ x+12=20\\ x=8\\ \\ \frac{y+15}{4}=4\\ y+15=16\\ y=1\\ \\ T=(8,1)\end{array}$

(c)
$\begin{array}{l}\text{Gradient of }PQ=\frac{5-2}{4-3}=3\\ \text{Equation of }PQ,\\ y-2=3\left(x-3\right)\\ y-2=3x-9\\ y=3x-7----(1)\\ \\ \text{Gradient of }ST=\frac{6-1}{7-8}=-5\\ \text{Equation of }ST,\\ y-1=-5\left(x-8\right)\\ y-1=-5x+40\\ y=-5x+41----(2)\end{array}$

Question 1:

Solution:
(a)
$\begin{array}{l}\text{Equation of }PQ\\ 2y-x-5=0\\ 2y=x+5\\ y=\frac{1}{2}x+\frac{5}{2}\\ \therefore m_{PQ}=\frac{1}{2}\\ \\ \text{In a trapizium, }{m}_{PQ}=m_{SR}\\ \frac{1}{2}=\frac{0-(-3)}{w-4}\\ w-4=6\\ w=10\end{array}$

(b)
$\begin{array}{l}{m}_{PQ}=\frac{1}{2}\\ m_{PS}=-\frac{1}{m_{PQ}}=-\frac{1}{\frac{1}{2}}=-2\end{array}$


(c)
$\begin{array}{l}\text{Let }M=\left(x,y\right)\\ \text{Given that }△QMS\text{ is perpendicular at }M\\ \text{Thus }△QMS={90}^{\circ }\\ \left(m_{QM}\right)\left(m_{MS}\right)=-1\\ \left(\frac{y-5}{x-5}\right)\left(\frac{y-\left(-3\right)}{x-4}\right)=-1\\ \left(y-5\right)\left(y+3\right)=-1\left(x-5\right)\left(x-4\right)\\ y^2+3y-5y-15=-1\left(x^2-4x-5x+20\right)\\ y^2-2y-15=-x^2+9x-20\\ x^2+y^2-9x-2y+5=0\end{array}$

Hence, the equation of locus of the moving point M is

Question 6:

Solution:
$\begin{array}{l}\text{Let }P=\left(x,y\right)\\ PM:PN=2:3\\ \frac{PM}{PN}=\frac{2}{3}\\ 3PM=2PN\\ 3\sqrt{{\left(x-\left(-3\right)\right)}^2+{\left(y-5\right)}^2}=2\sqrt{{\left(x-4\right)}^2+{\left(y-7\right)}^2}\end{array}$

Question 7:
Solution:

Question 3:

Solution:

$\begin{array}{l}\frac{x}{7}-\frac{y}{h}=1\\ m_{EF}=-\left(\frac{y\text{-intercept}}{x\text{-intercept}}\right)=-\left(\frac{-h}{7}\right)=\frac{h}{7}\\ m_{CD}=m_{EF}\\ -5=\frac{h}{7}\\ h=-35\end{array}$

Question 4:

Solution:
$\begin{array}{l}\text{Given y-intercept of the straight line }\frac{x}{5}+\frac{y}{p}=1\text{ is }3,\\ \therefore p=3\\ \text{Gradient of the straight line = }-\frac{3}{5}\\ \\ \text{For another straight line }y+qx=0,y=-qx\\ \text{As two parallel lines have same gradient,}\\ -q=-\frac{3}{5}\\ q=\frac{3}{5}\end{array}$

Question 5:

Solution:
$\begin{array}{l}\text{For the straight line }\frac{y}{7}+\frac{x}{4}=1,\text{ gradient }=-\frac{7}{4}\\ \\ \text{For the straight line }7y=4x+21,\\ y=\frac{4}{7}x+3,\text{ gradient }=\frac{4}{7}\\ \\ -\frac{7}{4}\times \frac{4}{7}=-1\end{array}$

Question 1:
Solution:
$\begin{array}{l}\text{Area of }△PQR\text{ = }31\\ \\ \frac{1}{2}|\begin{array}{l}\text{6 5 }m\\ \text{1 6}-1\end{array}\begin{array}{l}6\\ \text{1}\end{array}|=31\\ \\ |\left(6\right)\left(6\right)+\left(5\right)\left(-1\right)+\left(m\right)\left(1\right)\\ -\left(1\right)\left(5\right)-\left(6\right)\left(m\right)-\left(-1\right)\left(6\right)|=62\\ \\ |36-5+m-5-6m+6|=62\\ |32-5m|=62\\ 32-5m=\pm 62\\ \\ -5m=62-32\text{ or }-5m=-62-32\\ m=-6\text{ or }m=\frac{94}{5}\end{array}$

Question 2:
Solution:
$\begin{array}{l}\left(\frac{\left(3m\right)\left(2\right)+\left(3t\right)\left(3\right)}{3+2},\frac{\left(m\right)\left(2\right)+\left(2u\right)\left(3\right)}{3+2}\right)=\left(t,u\right)\\ \frac{6m+9t}{5}=t\\ 6m+9t=5t\\ 6m=-4t\\ m=-\frac{2}{3}t\to (1)\\ \\ \frac{2m+6u}{5}=u\\ 2m+6u=5u\\ 2m=-u\\ \text{From (1),}\\ \text{2}\left(-\frac{2t}{3}\right)=-u\\ t=\frac{3}{4}u\end{array}$

Example 1

Example 2
$\begin{array}{l}\text{Given }PA=PB\\ \sqrt{{\left(x-\left(-2\right)\right)}^2+{\left(y-3\right)}^2}=\sqrt{{\left(x-4\right)}^2+{\left(y-\left(-1\right)\right)}^2}\\ \text{Square both sides to eliminate the square roots}\text{.}\\ {\left(x+2\right)}^2+{\left(y-3\right)}^2={\left(x-4\right)}^2+{\left(y+1\right)}^2\\ x^2+2x+4+y^2-6y+9=x^2-8x+16+y^2+2y+1\\ 10x-8y-4=0\\ \text{Hence, the equation of the locus of point }P\text{ is}\\ 10x-8y-4=0\end{array}$

Example 3
$\begin{array}{l}AP:PB=1:2\\ \frac{AP}{PB}=\frac{1}{2}\\ 2AP=PB\\ 2\sqrt{{\left(x-2\right)}^2+{\left(y-0\right)}^2}=\sqrt{{\left(x-0\right)}^2+{\left(y-\left(-2\right)\right)}^2}\\ \text{Square both sides to eliminate the square roots}\text{.}\\ 4\left[{\left(x-2\right)}^2+y^2\right]=x^2+{\left(y+2\right)}^2\\ 4\left(x^2-4x+4+y^2\right)=x^2+y^2+4y+4\\ 4x^2-16x+16+4y^2=x^2+y^2+4y+4\\ 3x^2+3y^2-16x-4y+12=0\\ \text{Hence, the equation of the locus of point }P\text{ is}\\ 3x^2+3y^2-16x-4y+12=0\end{array}$

6.5 Parallel Lines and Perpendicular Lines

(A) Parallel Lines
1. If two straight lines are parallel, they have same gradient.

$\boxed{m_1=m_2}$
$\begin{array}{l}x+8y=40\\ 8y=-x+40\\ y=-\frac{1}{8}x+5\\ \text{gradient }{m}_1=-\frac{1}{8}\\ \text{Given a straight line passes through }\\ \text{point }A\text{ and point }B\text{ is parallel to }x+8y=40,\\ \therefore m_1=m_2\\ -\frac{1}{8}=\frac{4k^2-3k}{-6-2}\\ 8=32k^2-24k\\ 1=4k^2-3k\\ 4k^2-3k-1=0\\ \left(4k+1\right)\left(k-1\right)=0\\ 4k+1=0\text{ or }k-1=0\\ k=-\frac{1}{4}\text{ or}k=1\end{array}$

(B) Perpendicular Lines
1. If two lines are perpendicular to each other, the product of their gradients is –1.


In the above diagram, if straight line L₁ is perpendicular to straight line L₂,
$\boxed{m_1\times m_2=-1}$

Example 2:
$\begin{array}{l}{m}_{PQ}=\frac{2-4}{4-\left(-2\right)}=-\frac{1}{3}\\ m_{RS}=\frac{6-\left(-3\right)}{2-\left(-1\right)}=3\\ \left(m_{PQ}\right)\left(m_{RS}\right)=\left(-\frac{1}{3}\right)\left(3\right)=-1\end{array}$