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What is a sequence?
A sequence is an ordered set of (usually) numbers.
In the context of sequences, what is a term?
A term is one of the numbers in a sequence.
In the context of sequences, what is n?
n is the position of a term in a sequence.
E.g. when n = 3, it is referring to the third term of the sequence.
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What is a sequence?
A sequence is an ordered set of (usually) numbers.
In the context of sequences, what is a term?
A term is one of the numbers in a sequence.
In the context of sequences, what is n?
n is the position of a term in a sequence.
E.g. when n = 3, it is referring to the third term of the sequence.
True or False?
For the first term, n = 0.
False.
For the first term, n = 1.
What is subscript notation for sequences?
Subscript notation is used to talk about a particular term.
For example
is the 1st term
is the 7th term
is the nth term
What is a position-to-term rule?
A position-to-term rule gives the nth term of a sequence as a formula in terms of n.
How would you find the first three terms of a sequence using a position-to-term rule?
To find the first three terms of a sequence using a position-to-term rule, substitute , and into the position-to-term formula.
What is a term-to-term rule?
A term-to-term rule tells you how to find a term from the term before it.
I.e., it gives the (n+1)th term in terms of the nth term.
True or False?
The term-to-term rule for a linear sequence is to add the same amount each time.
True.
The term-to-term rule for a linear sequence is to add the same amount each time.
True or False?
The term-to-term rule for a geometric sequence is to multiply by the term before each time.
False.
The term-to-term rule for a geometric sequence is to multiply by the same amount each time (called a common ratio), not by the term before.
True or False?
is a Fibonacci sequence.
False.
is not a Fibonacci sequence.
The sum of the two terms before the 16 is 0 + 8, which equals 8 (not 16).
Explain how to find the common ratio of the geometric sequence 4, 14, 49, ...
The common ratio of a geometric sequence is the amount you multiply by each time.
Find out what you multiply 4 by to get 14. This is .
Check that this works for the next two terms: (correct).
The common ratio is 3.5.
True or False?
is a geometric sequence.
True.
is a geometric sequence.
It helps to use surds to simplify the 3rd term: .
Now the sequence is
Remember that so the common ratio is .
You can check this by writing it as
True or False?
is a Fibonacci sequence.
True.
is a Fibonacci sequence.
Add the first two terms to get (the correct 3rd term).
Add the 2nd and 3rd term to get which gives (the correct 4th term).
What is a linear sequence?
A linear sequence is a sequence of numbers that increase or decrease by the same amount from one term to the next.
A linear sequence is often called an arithmetic sequence.
Define the common difference of a linear sequence.
The common difference is the amount that a linear sequence increases or decreases by from one term to the next.
What is the notation for in the context of linear sequences?
is the notation for the common difference of a linear sequence.
E.g. for a sequence 3, 7, 11, 15, 19, ...
.
What is the notation for in the context of linear sequences?
is the value before the first term (sometimes known as the zero term).
E.g. for a sequence 3, 7, 11, 15, 19, ...
The common difference is +4, so imagine going back from the first term by subtracting 4. So .
What is the position-to-term formula for a linear sequence in terms of , and ?
The position-to-term formula (also known as the nth term rule) for a linear sequence in terms of , and is: .
What is a quadratic sequence?
A quadratic sequence has an n th term formula that involves n2 .
True or False?
The first differences in a quadratic sequence are constant.
False.
The first differences in a quadratic sequence are not constant.
The first differences form a linear sequence, which means that the second differences of a quadratic sequence are constant.
How do you find the nth term rule for a quadratic sequence?
E.g. 3, 6, 11, 18, 27, ...
To find the nth term rule for a quadratic sequence, compare the original sequence to the sequence of square numbers.
E.g. each value in the sequence, 3, 6, 11, 18, 27, ... is 2 more than the sequence of square numbers, 1, 4, 9, 16, 25, ...
So if the sequence of square numbers is n2, the original sequence is n2 + 2.
True or False?
For a simple quadratic sequence of the form , the value of is twice the value of the second difference.
False.
For a simple quadratic sequence of the form , the value of is half the value of the second difference.
E.g. for the quadratic sequence: 5, 11, 21, 35, 53, ...
The first differences are: 6, 10, 14, 18
The second differences are: 4, 4, 4
Therefore, .
To find , compare the original sequence to the sequence given by .
The nth term rule for the original sequence is .