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Guide to Leaving Certificate Mathematics Ordinary Level Dr. Aoife Jones Paper 1 For the Leaving Cert 2013, Paper 1 is divided into three sections. Section A is entitled Concepts and Skills and contains four questions, all of which must be completed. These are designed to test the student’s understanding of basic mathematical concepts. In Paper 1, this corresponds to an understanding of the basics of algebra and number systems. Questions that appear here tend to be on topics that do not lend themselves to the larger-scale problems that occur later on in the exam. Topics that can appear in this section include, but are not limited to: (i) prime numbers and factors (ii) inequalities and numberlines (iii) indices and scientific notation (iv) profit and loss, compound interest, income tax (v) quadratic equations and simultaneous equations (vi) and also topics that may appear in Section B. [See Example 1.] Section B is entitled Contexts and Applications and contains two questions. Again, no choice is given and both questions must be answered. These questions allow for more extensive testing of a student’s understanding of particular subjects. It is important to note that the questions asked here may span over a number of topics that were traditionally asked in separate questions. As a result, students must be vigilant when approaching 1 these questions; they must now keep to mind their entire armoury of mathematical approaches when attempting any one question. Topics that can appear in this section include, but are not limited to: (i) complex numbers (ii) patterns (iii) series and sequences On this latter topic, students are expected to be able to identify patterns that are described in words or in diagrams, and to express the pattern in algebraic form. This topic is new to the syllabus with the introduction of Project Maths and aims to enable students to better understand the role that maths plays in natural world [see Example 2.] Section C is entitled Functions and Calculus (old syllabus) and contains three questions, of which students must answer two. This topic remains unchanged from previous years for the Leaving Cert in 2013 only, and so the questions closely follow those asked in the past exam papers. Students should look at Questions 6, 7 and 8 from Paper 1 of the old exam papers, as the content has not changed and the questions still follow the same outline. 2 Example 1 - Paper 1 Section A Concepts and Skills 2011 (Project Maths Trial Schools) Paper 1 Q1 (a) Explain what a prime number is. Definitions are being given a new emphasis with the introduction Project Maths. It is no longer sufficient to know whether a number is prime, but we must understand why. Solution A prime number is any number whose only factors are 1 and itself. (b) Express 2652 as a product of prime numbers. All numbers can be written as a product of prime numbers. It is just a matter of breaking the factors down until they are all prime. Solution 2652 2652 2652 2652 = = = = 2 × 1326 2 × 2 × 663 2 × 2 × 3 × 221 2 × 2 × 3 × 13 × 17 (c) The number 261 −1 is a prime number. Using your calculator, or otherwise, express its value, correct to two significant figures, in the form a×10n , where 1 ≤ a < 10 and n ∈ N. Most calculators will do this for you. Solution 261 − 1 = 2.305843 × 1018 = 2.3 × 1018 , correct to two significant figures. (d) Use your answer to part (c) to state how many digits there are in the exact value of 261 − 1. Tip: If having difficulties with hard questions, we can try to think of a simple example and solve that. For example, 2.3 × 101 is 23, which has two digits. 2.3 × 102 = 230, which has 3 digits. It is always one more than the power of the ten. Solution 261 − 1 = 2.3 × 1018 has 18 + 1 = 19 digits. 3 Example 2 - Paper 1 Section B Contexts and Applications 2011 (Project Maths Trial Schools) Sample Paper 1 Q5 Sı́le is investigating the number of square grey tiles needed to make patterns in a sequence. The first three patterns are shown below, and the sequence continues in the same way. In each pattern, the tiles form a square and its two diagonals. There are no tiles in the white areas in the patterns there are only the grey tiles. Figure 1: (taken from the Leaving Cert paper, available from the State Examinations Commission website) (a) In the table below, write the number of tiles needed for each of the first five patterns. Patterns 1 2 3 No. of tiles 21 33 4 5 The number of tiles for the 3rd pattern can simply be counted. We should recognise that the first pattern is of width 5, the next of width 7 and the next of width 9. Therefore the next two will be of width 11 and 13. For the 4th and 5th patterns, a good approach is to actually draw out the tiles: 4 Figure 2: 4th pattern 5th pattern Solution Patterns 1 2 3 4 5 No. of tiles 21 33 45 57 69 (b) Find, in terms of n, a formula that gives the number of tiles needed to make the nth pattern. We note that the number of tiles goes up by 12 each time. This means it is an arithmetic sequence, where the common difference is d = 12. We then use the formula for the nth term of an arithmetic sequence Tn . For this we must know a, the first term of the sequence. Solution Tn = = = = a + (n − 1)d 21 + (n − 1)12 21 + 12n − 12 9 + 12n 5 (c) Using your formula, or otherwise, find the number of tiles in the tenth pattern. When a question offers the choice of solving a problem by “using a previous solution“ or “otherwise”, then the use of the previous solution is always preferable. The exception is if we have been unable to find the previous solution, in which case this phrasing is explaining that the problem can still be solved using an alternative method. In this case, that could involve either adding the 12 tiles to the number of tiles required for each pattern until reaching the tenth pattern. Alternatively, we could try to draw the pattern of width 23 tiles. Tn ⇒ T10 T10 T10 = = = = 9 + 12n 9 + 12(10) 9 + 120 129 (d) Sı́le has 399 tiles. What is the biggest pattern in the sequence that she can make? This question clearly requires a whole number as the solution. Also, it is not possible to simply round the answer using the standard rounding-off convention. If we find it is possible to make the 3.6th pattern, for example, then clearly she can only make the third pattern and not the fourth. For this reason, the number must be rounded down. Solution We use Tn = 9 + 12n and we are told that Tn ≤ 399. Therefore: Tn 399 399 − 9 390 390 12 n = ≥ ≥ ≥ 9 + 12n 9 + 12n 12n 12n ≥ n ≤ 32.5 So Sı́le can make the 32nd pattern (and not the 33rd ). 6 (e) Find, in terms of n, a formula for the total number of tiles in the first n patterns. When the terms of a sequence are added, this is known as a series. In this case, we have an arithmetic sequence where d = 12 and a = 21 as before, but we use the formula for the sum of n terms of an arithmetic sequence: Sn = = = = = = n [2a + (n − 1)d] 2 n [2(21) + (n − 1)(12)] 2 n [42 + 12n − 12] 2 n [30 + 12n] 2 30n 12n2 + 2 2 15n + 6n2 (f) Sı́le starts at the beginning of the sequence and makes as many of the patterns as she can. She does not break up the earlier patterns to make the new ones. For example, after making the first two patterns, she has used up 54 tiles, (21 + 33). How many patterns can she make in total with her 399 tiles? This question simply requires using the formula we found in the previous section but with Sn = 399. Sn ⇒ 399 0 0 0 2n + 19 = 0 2n = −19 19 n=− 2 n = = = = = 15n + 6n2 15n + 6n2 6n2 + 15n − 399 2n2 + 5n − 133 , dividing both sides by 3 (2n + 19)(n − 7) or or n−7=0 n=7 or n=7 = 7 , (as we disregard negative answers here) 7 So Sı́le can make the 1st , 2nd , 3rd , 4th , 5th , 6th and 7th patterns, which is 7 patterns in total. 8 Paper 2 For the Leaving Cert 2013, Paper 2 is divided into just two sections. The entire of Paper 2 has had a Project Maths re-lift, and there are no questions that follow the previous syllabus. As in Paper 1, Section A is entitled Concepts and Skills. It contains six questions, all of which must be completed. There is one choice given, as students are allowed the option of answering Question 6A or 6B. These six questions are designed to test the student’s understanding of the basic mathematical concepts for examination in Paper 2. For the first five questions, topics that can appear include, but are not limited to: (i) coordinate geometry of the line and circle (ii) enlargements (iii) area and volume (iv) permutations (v) and also topics that may appear in Section B. [See Example 3.] Question 6 currently offers a choice of two topics, and will continue to do so for the duration of the three year roll-out of the new syllabus (2012, 2013, 2014). After this time, there will be no choice given. Question 6A is based on synthetic geometry, which consists of being able to use certain terms related to logic and deductive reasoning (theorem, proof, axiom, corollary, converse, implies), as well as being able to carry out a number of geometric constructions (angle of 60◦ without using a protractor or set square, tangent to a given circle at a given point on it, parallelogram given the length of the sides and the measure of the angles, circumcentre and circumcircle of a given triangle using only straight-edge and compass, incentre and incircle of a given triangle using only straight-edge and compass, centroid of a triangle). Question 6B consists of answering a problem-solving question based on the geometry theorems studied for the Junior Certificate. In Paper 2, Section B is entitled Contexts and Applications and contains two questions, both of which must be answered. Again, these questions allow for more extensive testing of a student’s understanding of particular subjects, and each question is likely to span a number of topics. In particular, students should be aware of the links 9 between probability and statistics and the strong possibility of these being tested together in one question. Topics that can appear in this section include, but are not limited to: (i) probability (ii) statistics (iii) trigonometry [See 2011 (Project Maths Trial Schools) Paper 2 Q7 as an example.] 10 Example 3 2011 (Project Maths Trial Schools) Paper 2 Q3 A plastic toy is in the shape of a hemisphere. When it falls on the ground, there are two possible outcomes: it can land with the flat side facing down or with the flat side facing up. Two groups of students are trying to find the probability that it will land with the flat side down. (a) Explain why, even though there are two outcomes, the answer is not necessarily equal to 12 . For questions like this that are asked in words, it is suitable for us to give an answer in words. Solution The answer would only be equal to 12 if both outcomes are equally likely, which we cannot know for definite. The two sides of the toy are shaped differently which may affect the outcome. (b) The students estimate the probability by experiment. Group A drops the toy 100 times. From this, they estimate that it lands flat side down with probability 0.76. Group B drops the toy 500 times. From this, they estimate that it lands flat side down with probability 0.812. (i) Which groups estimate is likely to be better, and why? Students are expected to know that probabilities estimated from experiments improve in accuracy as the number of trials increases. Solution Group B’s estimate will be better as they have carried out more trials, leading to better accuracy. (ii) How many times did the toy land flat side down for Group B? If students get confused about what to do with the numbers, it is good practice to imagine what we would do if the numbers were easier. For example, if the toy was dropped 6 times and it was found to have a probability of 0.5 of landing flat side down, we would know it landed flat side down 3 times. This is because 0.5 is equal to 12 , and a half of 6 is 3. Or, in other words, 0.5 × 6 = 3. 11 Solution 0.812 × 500 = 406 times (iii) Using the data from the two groups, what is the best estimate of the probability that the toy lands flat side down? Etimates are improved by using the most number of trials. Therefore the best estimate that can be made here is when we include the results from both experiments. Solution Group B found the toy landed flat side down 0.812 × 500 = 406 times. Group A found the toy landed flat side down 0.76 × 100 = 76 times. In total, the toy landed flat side down 406 + 76 = 482 times out of 600 times. Best estimate of probability of landing flat side down = 12 482 . 600