Transcript Sequences
KS3 Mathematics A4 Sequences 1 of 27 © Boardworks Ltd 2004 Contents A4 Sequences A4.1 Introducing sequences A4.2 Describing and continuing sequences A4.3 Generating sequences A4.4 Finding the nth term A4.5 Sequences from practical contexts 2 of 27 © Boardworks Ltd 2004 Sequences from geometrical patterns We can show many well-known sequences using geometrical patterns of counters. Even Numbers 2 4 6 8 10 5 7 9 Odd Numbers 1 3 of 27 3 © Boardworks Ltd 2004 Sequences from geometrical patterns Multiples of Three 3 6 9 12 15 15 20 25 Multiples of Five 5 4 of 27 10 © Boardworks Ltd 2004 Sequences from geometrical patterns Square Numbers 1 4 9 16 25 6 10 15 Triangular Numbers 1 5 of 27 3 © Boardworks Ltd 2004 Sequences with geometrical patterns How could we arrange counters to represent the sequence 2, 6, 12, 20, 30, . . .? The numbers in this sequence can be written as: 1 × 2, 2 × 3, 3 × 4, 4 × 5, 5 × 6, . . . We can show this sequence using a sequence of rectangles: 1 × 2 = 2 2 × 3 = 6 3 × 4 = 12 4 × 5 = 20 6 of 27 5 × 6 = 30 © Boardworks Ltd 2004 Powers of two We can show powers of two like this: 21 = 2 22 = 4 23 = 8 24 = 16 25 = 32 26 = 64 Each term in this sequence is double the term before it. 7 of 27 © Boardworks Ltd 2004 Powers of three We can show powers of three like this: 31 = 3 32 = 9 33 = 27 34 = 81 35 = 243 36 = 729 Each term in this sequence is three times the term before it. 8 of 27 © Boardworks Ltd 2004 Sequences that increase in equal steps We can describe sequences by finding a rule that tells us how the sequence continues. To work out a rule it is often helpful to find the difference between consecutive terms. For example, look at the difference between each term in this sequence: 3, 7, +4 11, +4 15 +4 19, +4 23, +4 27, +4 31, . . . +4 This sequence starts with 3 and increases by 4 each time. Every term in this sequence is one less than a multiple of 4. 9 of 27 © Boardworks Ltd 2004 Sequences that decrease in equal steps Can you work out the next three terms in this sequence? 22, –6 16, 10, –6 –2, 4, –6 –6 –8, –14, –20, . . . –6 –6 –6 How did you work these out? This sequence starts with 22 and decreases by 6 each time. Each term in the sequence is two less than a multiple of 6. Sequences that increase or decrease in equal steps are called linear or arithmetic sequences. 10 of 27 © Boardworks Ltd 2004 Sequences that increase in increasing steps Some sequences increase or decrease in unequal steps. For example, look at the differences between terms in this sequence: 2, 6, +1 8, +2 11, +3 15, +4 20, +5 26, +6 33, . . . +7 This sequence starts with 5 and increases by 1, 2, 3, 4, … The differences between the terms form a linear sequence. 11 of 27 © Boardworks Ltd 2004 Sequences that decrease in decreasing steps Can you work out the next three terms in this sequence? 7, 6.9, –0.1 6.7, –0.2 6.4, –0.3 6, –0.4 5.5, –0.5 4.9, 4.2, . . . –0.6 –0.7 How did you work these out? This sequence starts with 7 and decreases by 0.1, 0.2, 0.3, 0.4, 0.5, … With sequences of this type it is often helpful to find a second row of differences. 12 of 27 © Boardworks Ltd 2004 Using a second row of differences Can you work out the next three terms in this sequence? 1, 3, +2 8, +5 +3 16, +8 +3 27, +11 +3 41, +14 +3 58, +17 +3 78, . . . +20 +3 Look at the differences between terms. A sequence is formed by the differences so we look at the second row of differences. This shows that the differences increase by 3 each time. 13 of 27 © Boardworks Ltd 2004 Sequences that increase by multiplying Some sequences increase or decrease by multiplying or dividing each term by a constant factor. For example, look at this sequence: 2, 4, ×2 8, ×2 16, ×2 32, ×2 64, ×2 128, 256, . . . ×2 ×2 This sequence starts with 2 and increases by multiplying the previous term by 2. All of the terms in this sequence are powers of 2. 14 of 27 © Boardworks Ltd 2004 Sequences that decrease by dividing Can you work out the next three terms in this sequence? 512, 256, ÷4 ÷4 64, 16, ÷4 4, ÷4 1, ÷4 0.25, 0.125, . . . ÷4 ÷4 How did you work these out? This sequence starts with 512 and decreases by dividing by 4 each time. We could also continue this sequence by multiplying by each time. 15 of 27 1 4 © Boardworks Ltd 2004 Fibonacci-type sequences Can you work out the next three terms in this sequence? 1, 1, 2, 3, 5, 8, 13, 21, 34, 1+1 1+2 3+5 5+8 8+13 13+21 21+13 55, . . . 21+34 How did you work these out? This sequence starts 1, 1 and each term is found by adding together the two previous terms. This sequence is called the Fibonacci sequence after the Italian mathematician who first wrote about it. 16 of 27 © Boardworks Ltd 2004 Describing and continuing sequences Here are some of the types of sequence you may come across: Sequences that increase or decrease in equal steps. These are called linear or arithmetic sequences. Sequences that increase or decrease in unequal steps by multiplying or dividing by a constant factor. Sequences that increase or decrease in unequal steps by adding or subtracting increasing or decreasing numbers. Sequences that increase or decrease by adding together the two previous terms. 17 of 27 © Boardworks Ltd 2004 Continuing sequences A number sequence starts as follows 1, 2, . . . How many ways can you think of continuing the sequence? Give the next three terms and the rule for each one. 18 of 27 © Boardworks Ltd 2004 Finding missing terms 19 of 27 © Boardworks Ltd 2004 Name that sequence! 20 of 27 © Boardworks Ltd 2004