Math Antics - Number Patterns

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Hi, I’m Rob. Welcome to Math Antics!

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By now you probably know that math involves a lot of calculations using arithmetic.

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But math is about more than just calculations.

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In fact, one important type of math that sometimes gets overlooked involves number patterns.

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When you hear the word “pattern”, you might think of a shirt.

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Yep! And I’ll bet ya wish you had some fine threads like these, don’t ya?

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Oh… Actually…I’m good with this shirt, thanks….

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I get it… not everyone can pull off a look this rad.

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That’s… that’s true.

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The reason you might think of a shirt is because the word “pattern” often describes repeating images or objects.

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Like if I show you this pattern, “dog, cat, bird, dog, cat, blank”.

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What animal do you think should fill in the blank to complete the pattern?

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A bunny!

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Why would you think it was a bunny?

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Because I like bunnies.

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Well… It’s not a bunny. It’s a bird!

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See how the pattern repeats?

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“dog, cat bird, dog, cat, bird”.

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Well Mr. Whiskers and I prefer the pattern,

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“dog, cat, bunny, dog cat, bunny”.

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Anyway, number patterns can be formed by repeating numbers like this:

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1, 4, 7, 1, 4, 7

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Notice how the order of the pattern really matters?

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If you switch any of the numbers, it becomes a different pattern.

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In math, when you have a set of numbers or elements where the order matters, it’s called a “Sequence”.

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For example, the sequence 1, 2, 3 is different than the sequence 3, 2, 1

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even though they each contain the same “set” of numbers.

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And in math, the word “Set” refers to a group of numbers or elements

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where the order doesn’t matter AND where any duplicates are left out.

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For example, if you had the sequence 1, 2, 3, 3, 2, 1

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the set of numbers in that sequence is just 1, 2, 3 even though each number occurred twice in the sequence.

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Both sets and sequences use the same notation in math.

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Each number or element is separated by a comma, and the whole group is put inside curly braces like this.

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Some sequences of numbers repeat, like the sequence {0, 1, 0, 1, 0, 1}

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but some don’t repeat, like the sequence {1, 2, 3, 4, 5, 6}.

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But think about both of those sequences for a second…

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Right now, each of them contains a limited or “finite” number of elements.

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They each have 6.

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But each of these sequences could be continued forever if we wanted to.

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We could just keep repeating 0,1,0,1 forever

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or we could just keep counting, 7, 8, 9, 10, forever too.

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In other words, sequences can be finite OR they can be “infinite”.

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If a sequence or set is finite, it means that you can say there are a specific number of elements in it,

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like 6 or 20 or a million.

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But when something is infinite, it means that no matter how much time you have,

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you could never finish counting how many elements are in it.

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You can’t give it a specific number so you just say it goes on forever.

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Of course, we can’t actually write numbers forever on a piece of paper,

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so we need to use a special notation for infinite sets or infinite sequences.

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You just put three dots at the end of the list to show that it keeps on going forever like this.

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The three dots are an abbreviation that means the sequence continues in the same way.

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They can be used in the middle of a sequence to save writing.

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Like this means the sequence of all counting numbers from 1 to 100.

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But you can also use them at the end of a sequence to show that it goes on forever.

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So this sequence is repeating and finite because it has just 6 elements.

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This sequence is non-repeating and finite because it also has just 6 elements.

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This sequence is repeating and infinite.

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And this sequence is non-repeating and infinite. …make sense?

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For these last two infinite sequences, what’s the set of numbers that each contains?

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Well, the first keeps on repeating two numbers forever, so even though the sequence is infinite,

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the set it uses is finite because it only contains 0 and 1.

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But in the second infinite sequence, none of the elements are ever repeated,

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so the set of numbers is exactly the same as the sequence itself. It’s also infinite.

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Okay, so now you know that some number patterns are repeating and some aren’t.

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You also know that some number patterns are finite and some are infinite.

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We got our first non-repeating infinite sequence simply by counting.

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Let’s see if we can think of some others that way too.

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Suppose you start counting at the number 1 but then skip every other number.

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You’d end up with the sequence {1, 3, 5, 7, 9,…} and so on.

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In other words, you’d end up with the infinite, non-repeating sequence

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that we call “odd numbers” because none divide evenly by 2.

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Or, suppose you start counting at the number 2 instead, but still skip every other number.

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You’d end up with the sequence {2, 4, 6, 8, 10,…} and so on.

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That’s the infinite, non-repeating sequence of numbers we call “even numbers” because all divide evenly by 2.

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And you could make other sequences by skip counting by different amounts.

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Like you could start with 0 and skip every 2 numbers to get the sequence {0, 3, 6, 9, 12…} and so on.

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If you think about it, counting (and skip counting) are really just ways of making a number sequence by following a “Rule”.

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In the case of regular counting, that rule happens to be ‘Add 1’ to get each new number in the sequence.

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And when you skip count every other number, the rule you’re following is ‘Add 2’ each time.

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You can see that by looking at the sequence we called “odd numbers”.

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You could get from the 1st element to the 2nd by adding 2 (1 + 2 = 3),

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and you could get from the 4th element to the 5th by adding 2 (7 + 2 = 9)

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In other words, if you know the rule that a particular sequence is based on,

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you can use it to find any other number in the sequence.

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If you want to know what number comes next in the sequence of odd numbers, just add 2 to the last element you know.

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Like 11 + 2 = 13

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All four arithmetic operations can be used as rules for generating sequences.

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You’ve already seen how addition rues produce sequences that count up (or increase)

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but what do you think you’d get if you based a sequence on a subtraction rule, like ‘subtract 1’?

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Yep, you’d get a sequence that counts down (or decreases).

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5, 4, 3, 2, 1, Liftoff!

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The rule for this simple countdown sequence is to start with 5 and then subtract 1 each time.

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Oh, and some of you who are familiar with negative numbers will realize that

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this countdown sequence really doesn’t’ have to stop at zero.

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It could continue on forever in the negative direction,

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but we’re just gonna focus on positive numbers in this video.

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Another example of a subtraction sequence is to start with 50 and use the rule ‘subtract 5’.

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In that case you’d get {50,45,40,35, 30,…} and so on.

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Each element in the sequence is 5 less than the one before it.

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So it’s pretty easy to see how addition and subtraction can be the rule for a sequence…

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but what about multiplication and division?

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What number sequence would you get from the rule ‘multiply by 2’?

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Well, if we start with 1 as the first element,

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The next would be 1 x 2 which is 2.

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The next would be 2 x 2 which is 4.

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And the next would be 4 x 2 which is 8.

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Then the next would be 8 x 2 which is 16, and so on.

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Notice that the numbers in this sequence are getting big pretty fast.

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That’s one of the clues that a sequence might be based on a multiplication rule.

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When you keep multiplying a previous result by the same factor,

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the values can grow much faster than if you just added a fixed amount each time.

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You’ll see that if we compare the sequence we just made by multiplying by 2 each time,

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with the sequence we previously made by adding 2 each time.

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Even though both sequences start at the same number,

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when we added 2 each time, we got up to 13 by the 7th element,

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but when we multiplied by 2 each time we got up to 64 by the 7th element.

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That’s quite a difference!

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And it works in a similar way with division.

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Suppose you’re asked to make a sequence by starting with 40 and then dividing by 2 each time.

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The first number is 40.

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The next is 40 divided by 2 which is 20.

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The next is 20 divided by 2 which is 10.

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The next is 10 divided by 2 which is 5.

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The next is 5 divided by 2 which is 2.5

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And we could keep on going, dividing by 2 forever to get smaller and smaller fractions

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but we’ll stop there so we can compare that to the sequence you’d get if you start with 40 but subtract 2 each time.

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In that case you’d get 40, then 38, then 36, then 34, then 32 and so on.

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Notice how the sequence that’s based on the division rule gets smaller much faster

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than the sequences that’s based on the subtraction rule.

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…just like the sequence that’s based on multiplication got bigger much faster than the one based on addition.

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That’s because when you keep adding or subtracting the same amount,

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the sequence changes by a constant amount each step.

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…just like going up or down a normal flight of stairs.

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But if you multiply or divide each time,

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the sequence changes by an increasing or decreasing amount each step.

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That would be a tough set of stairs to climb!

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In fact, there’s such a big difference in the way these types of sequences increase or decrease

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that mathematicians have different names for them.

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Sequences that are based on addition or subtraction rules are called “Arithmetic Sequences”

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while sequences that are based on multiplication or division rules are called “Geometric Sequences”.

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Those maybe aren’t the most intuitive names, but since they’ve been used for so long,

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it’s important to know what people mean when they say them.

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Okay, by now you’ve probably realized that there are LOTS of different kinds of number sequences and patterns in math

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…far too many to cover in just one video.

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So instead of trying to do that, we’re gonna end this video with some tips you can use

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to figure out if a sequence is based on a simple rule involving addition, subtraction, multiplication or division.

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When you’re given a sequence, first try to determine if it’s repeating or non-repeating.

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For example, in this sequence, you can see that part of the sequence keeps repeating.

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That means that you’d need to use the pattern to fill in any missing elements instead of a rule.

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But if the sequence isn’t repeating, like this one,

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the next thing you’d want to check is if the sequence is increasing or decreasing.

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Not all sequences increase or decrease,

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but increasing sequences could be based on an addition or multiplication rule,

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while decreasing sequences could be based on a subtraction or division rule.

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This sequence is increasing since each new element is bigger than the one before it,

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but how can we tell if it’s based on an addition or a multiplication rule?

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To do that, we need to look for either a “common difference” or a “common ratio” in the sequence.

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Here’s what that means…

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Start by picking any two adjacent numbers in the sequence and find the difference between them by subtracting.

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For example, the difference between 4 and 8 is 4.

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Then, pick any other two adjacent numbers and do the same thing.

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I’m gonna pick these last two: 20 minus 16 is also 4.

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Are the differences the same?

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In this case yes!

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That means that we have found what’s called a “common difference” for the sequence.

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The common difference is a constant amount that’s either added or subtracted to each new element.

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Since the common difference here is 4 and the sequence is increasing,

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that means the rule for this sequence is probably ‘add 4’.

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You can check to make sure all the other elements are following that rule just to be sure.

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But what if we don’t find a common difference for a sequence? …like this one.

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If we take the first two elements and subtract them, we get 4,

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but if we take the next two elements and subtract them we get 12.

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That means that there’s NOT a common difference for this sequence

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so it’s not based on a simple addition or subtraction rule.

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But, maybe we can find a common ratio instead. Let’s see what that means.

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To find a common ratio, we also take two adjacent pairs of elements,

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but instead of subtracting them, we divide them.

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For example, if we take the first two elements and divide them like this (6 divided by 2) we get 3.

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And if we take the next two adjacent elements and divide them like this (18 divided by 6) we also get 3.

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Ah Ha! That’s what we call a common ratio.

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And it means that this sequence is likely based on either a simple multiplication or division rule.

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Since this is an increasing sequence, we know that the rule is probably ‘multiply by 3’.

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Again, you can double check that on other pairs.

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So even though not all sequences are based on simple arithmetic rules, checking for a common difference or a common ratio can help you identify the ones that are.

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Alright, so now you know a little it about number sequences.

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You know the difference between a sequence and a set.

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You know that some sequences repeat while others don’t.

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You know that some sequences are finite while others are infinite.

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And you know that sequences can be based on arithmetic rules.

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If a sequence’s rule involve adding or subtracting a constant amount each time,

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that means you’ve got an “Arithmetic Sequence”

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and you’ll be able to figure out that constant or “common difference” by subtracting pairs of adjacent numbers.

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But if a sequence’s rule involve multiplying or dividing by the same factor each time,

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that means that you’ve got a “Geometric Sequence”

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and you’ll be able to identify its “common ratio” by dividing pairs of adjacent numbers.

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We covered a lot in this video, so be sure to rewatch it later if it didn’t all sink in the first time.

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And remember, the best way to get good at math is to practice what you’ve learned.

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As always, thanks for watching Math Antics and I’ll see ya next time.

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Learn more at www.mathantics.com

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