CIE Surd (2020)


1 (CIE 0606/2018/w/13/q3)
Do not use a calculator in this question.
In this question, all lengths are in centimetres.
A triangle $A B C$ is such that angle $B=90^{\circ}, A B=5 \sqrt{3}+5$ and $B C=5 \sqrt{3}-5$.
(i) Find, in its simplest surd form, the length of $A C$.
(ii) Find $\tan B C A$, giving your answer in the form $a+b \sqrt{3}$, where $a$ and $b$ are integers. [3]


2 (CIE 0606/2018/w/21/q3)
Do not use a calculator in this question.
(a) Simplify $(\sqrt{2}+2 \sqrt{5})(4 \sqrt{2}-3 \sqrt{5})$, giving your answer in the form $a+b \sqrt{c}$, where $a, b$ and $c$ are integers.
(b) Simplify $\frac{4-3 \sqrt{6}}{\sqrt{3}+\sqrt{2}}$, giving your answer in the form $p \sqrt{3}+q \sqrt{2}$, where $p$ and $q$ are integers.


3 (CIE 0606/2018/w/22/q7)
Solve the quadratic equation $(1-\sqrt{3}) x^{2}+x+(1+\sqrt{3})=0$, giving your answer in the form $a+b \sqrt{3}$, where $a$ and $b$ are constants.


4 (CIE 0606/2019/w/11/q8)
Do not use a calculator in this question.
In this question, all lengths are in centimetres. 


The diagram shows the trapezium $A B C D$ in which angle $A D C$ is $90^{\circ}$ and $A B$ is parallel to $D C$. It is given that $A B=4+3 \sqrt{5}, \quad D C=11+2 \sqrt{5}$ and $A D=7+\sqrt{5}$.
(i) Find the perimeter of the trapezium, giving your answer in simplest surd form.
(ii) Find the area of the trapezium, giving your answer in simplest surd form.


5 (CIE 0606/2019/m/12/q7)
Do not use a calculator in this question.
All lengths in this question are in centimetres. 


The diagram shows the trapezium $A B C D$, where $A B=2+3 \sqrt{5}, D C=6+3 \sqrt{5}, A D=10-2 \sqrt{5}$ and angle $A D C=90^{\circ}$.
(i) Find the area of $A B C D$, giving your answer in the form $a+b \sqrt{5}$, where $a$ and $b$ are integers.
(ii) Find $\cot B C D$, giving your answer in the form $c+d \sqrt{5}$, where $c$ and $d$ are fractions in their simplest form. [3]


6 (CIE 0606/2019/s/13/q7)
Do not use a calculator in this question.
In this question, all lengths are in centimetres. 


The diagram shows the triangle $A B C$ such that $A B=2 \sqrt{5}-1, B C=2+\sqrt{5}$ and angle $A B C=90^{\circ}$.
(i) Find the exact length of $A C$.
(ii) Find $\tan A C B$, giving your answer in the form $p+q \sqrt{r}$, where $p, q$ and $r$ are integers.
(iii) Hence find $\sec ^{2} A C B$, giving your answer in the form $s+t \sqrt{u}$ where $s, t$ and $u$ are integers. [2]


7 (CIE 0606/2019/s/21/q4)
Without using a calculator, express $\frac{(\sqrt{5}-3)^{2}}{\sqrt{5}+1}$ in the form $p \sqrt{5}+q$, where $p$ and $q$ are integers.


8 (CIE $0606 / 2019 / \mathrm{w} / 22 / \mathrm{q} 11$ )
Do not use a calculator in this question.
Solve the quadratic equation $(\sqrt{5}-3) x^{2}+3 x+(\sqrt{5}+3)=0$, giving your answers in the form $a+b \sqrt{5}$, where $a$ and $b$ are constants.


9 (CIE 0606/2019/w/23/q6)
Do not use a calculator in this question.

(i) Find $\tan ACB$ in the form $r+s\sqrt 3$, where $r$ and $s$ are integers. [3]
(ii) Find $A C$ in the form $t \sqrt{u}$, where $t$ and $u$ are integers and $t \neq 1$. [3]


10 (CIE $0606 / 2020 / \mathrm{s} / 11 / \mathrm{q} 4$ )
DO NOT USE A CALCULATOR IN THIS QUESTION.
Find the positive solution of the equation $(5+4 \sqrt{7}) x^{2}+(4-2 \sqrt{7}) x-1=0$, giving your answer in the form $a+b \sqrt{7}$, where $a$ and $b$ are fractions in their simplest form.


11 (CIE $0606 / 2020 / \mathrm{m} / 12 / \mathrm{q} 5$ )
DO NOT USE A CALCULATOR IN THIS QUESTION.
In this question all lengths are in centimetres. 


The diagram shows the isosceles triangle $A B C$, where $A B=A C$ and $B C=2+4 \sqrt{3}$. The height, $A D$, of the triangle is $5-\sqrt{3}$.
(a) Find the area of the triangle $A B C$, giving your answer in the form $a+b \sqrt{3}$, where $a$ and $b$ are integers.
(b) Find $\tan A B C$, giving your answer in the form $c+d \sqrt{3}$, where $c$ and $d$ are integers.
(c) Find $\sec ^{2} A B C$, giving your answer in the form $e+f \sqrt{3}$, where $e$ and $f$ are integers.


12 (CIE $0606 / 2020 / \mathrm{w} / 21 / \mathrm{q} 6)$
DO NOT USE A CALCULATOR IN THIS QUESTION.
In this question all lengths are in centimetres. 




In the diagram above $A C=\sqrt{3}-1, A B=\sqrt{3}+1$, angle $A B C=15^{\circ}$ and angle $C A B=90^{\circ}$.
(a) Show that $\tan 15^{\circ}=2-\sqrt{3}$.
(b) Find the exact length of $B C$.



13 (CIE 0606/2020/s/22/q2)
DO NOT USE A CALCULATOR IN THIS QUESTION.
The point $(1-\sqrt{5}, p)$ lies on the curve $y=\frac{10+2 \sqrt{5}}{x^{2}}$, Find the exact value of $p$, simplifying your answer.


14 $(\mathrm{CIE} 0606 / 2020 / \mathrm{w} / 22 / \mathrm{q} 8)$
DO NOT USE A CALCULATOR IN THIS QUESTION.
In this question lengths are in centimetres.
 
(a) Given that the area of the triangle $A B C$ is $5.5 \mathrm{~cm}^{2}$, find the exact length of $A C$. Write your answer in the form $a+b \sqrt{3}$, where $a$ and $b$ are integers.
(b) Show that $B C^{2}=c+d \sqrt{3}$, where $c$ and $d$ are integers to be found.


15 (CIE $0606 / 2020 / \mathrm{w} / 23 / \mathrm{q} 11)$
DO NOT USE A CALCULATOR IN THIS QUESTION.
Solve the quadratic equation $(\sqrt{7}-2) x^{2}-4 x+(\sqrt{7}+2)=0$, giving each of your answers in the form $a+b \sqrt{7}$, where $a$ and $b$ are constants. [7]


16 (CIE 0606/2020/s/23/q5)
DO NOT USE A CALCULATOR IN THIS QUESTION.
(a) Simplify $\frac{\sqrt{128}}{\sqrt{72}}$
(b) Simplify $\frac{1}{1+\sqrt{3}}-\frac{\sqrt{3}}{3+2 \sqrt{3}}$, giving your answer as a fraction with an integer denominator. [4]


Answer 
1. (i) $A C=10 \sqrt{2}$
(ii) $\tan B C A=2+\sqrt{3}$
2. (a) $5 \sqrt{10}$
(b) $10 \sqrt{3}-13 \sqrt{2}$
3. $x=1+\sqrt{3}$ or $x=-\frac{1}{2}-\frac{\sqrt{3}}{2}$
4. (i) $P=22+6 \sqrt{5}+6 \sqrt{3}$
(ii) $A=65+25 \sqrt{5}$
5. (i) $10+22 \sqrt{5}$
(ii) $\frac{1}{2}+\frac{\sqrt{5}}{10}$
6. (i) $A C=\sqrt{30}$ (ii) $\tan A C B=12-5 \sqrt{5}$ (iii) $\sec ^{2} A C B=270-120 \sqrt{5}$
7. $6 \sqrt{5}-11$
8. $\quad x=3+\sqrt{5}, x=\frac{-(3+\sqrt{5})}{4}$
9. (i) $\tan A C B=2+\sqrt{3}$
(ii) $A C=2 \sqrt{6}$
10. $\quad x=\frac{6}{2 !}+\frac{1}{29} \sqrt{7}$
11. (a) $A=9 \sqrt{3}-1$
(b) $\sqrt{3}-1$
(c) $5-2 \sqrt{3}$
12. (a) proof
(b) $B C=2 \sqrt{2}$
13. $p=5+2 \sqrt{5}$
14. (a) $A C=4 \sqrt{3}-2$
(b) $B C^{2}=65-34 \sqrt{3}$
15. $x=2+\sqrt{7}, x=\frac{2}{3}+\frac{1}{3} \sqrt{7}$
16. (a) $\frac{4}{3}$
(b) $\frac{9 \sqrt{3}-15}{6}$

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