Irrational Numbers - Math Antics Extras
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0:02 Have you ever thought that irrational numbers
0:04 are called irrational because they’re insane?
0:07 Well they’re not. They’re actually really cool
0:09 and really amazing.
0:10 To understand what an irrational number is,
0:13 it helps to know what a rational number is.
0:15 A rational number is any number that can
0:17 be written as a ratio of two integers.
0:20 Does that sound familiar? Yup, a ratio of two integers
0:24 is a fraction, like 1/2 or 2/3.
0:27 So any number that can be written
0:29 as a fraction is a rational number.
0:31 But can’t all numbers be written as a fraction?
0:34 Surprisingly the answer is no.
0:37 Sure, any whole number can be written as a
0:39 fraction by giving it 1 as the denominator.
0:41 And any decimal number that you can write,
0:43 can be written as a fraction by having the
0:45 proper power of 10 as the denominator.
0:48 So all of these are rational numbers.
0:50 And there are a lot more… infinitely more.
0:53 Any number that can be accurately written
0:55 as a fraction or a decimal number is a rational number.
0:59 But there are numbers that can’t be written
1:01 accurately as a fraction, or even as a decimal number.
1:04 Those numbers are called irrational numbers
1:06 because they are not rational numbers.
1:09 One of the most famous irrational numbers is pi.
1:12 And you might be confused because you may
1:13 have heard that you can represent pi with a
1:15 fraction like 22/7 or 355/113, but those are just
1:21 approximations for pi. Which means they get close
1:23 to the value of pi but they are not exactly equal.
1:26 You can’t get the exact value of pi with a fraction
1:29 no matter what numbers you use.
1:31 And you’ve probably seen pi written as a decimal number
1:34 like 3.14 or 3.14159 but those aren’t completely accurate
1:40 values of pi either. Again, they’re approximations.
1:44 If you tried to write a completely accurate decimal number
1:47 for pi or any other irrational number, the decimal digits
1:50 would never end and won’t repeat.
1:53 The statement that the decimal digits would never end
1:56 might be hard to believe, but it’s true
1:59 they just keep going and going—forever.
2:02 But the statement that the decimal digits won’t repeat
2:04 might be hard to understand.
2:06 It might even make you think something that’s not true.
2:10 You might think it means that you could never have 2
2:12 of the same digit next to each other.
2:14 Or you might think that a particular pattern of digits,
2:16 like 123, won’t appear more than once.
2:19 Or that it at least won’t be followed immediately
2:22 by the same pattern. But that’s not what it means.
2:25 To see that, let’s take a look at the first 500 digits of pi.
2:29 There are many places where there are 2 or more of
2:31 the same digit next to each other.
2:33 And here’s the pattern 360 and then a little further along
2:36 we have 360 again. And look at this, here we have
2:40 the digits 209 followed immediately by 209!
2:44 So if that’s not what’s meant by the
2:47 decimal digits not repeating then what is?
2:50 Well, remember that fraction that’s
2:51 often used to approximate pi? 22/7?
2:55 Let’s look at the first 500 digits of that number.
2:58 Notice how the sequence ‘142857’ keeps repeating?
3:03 Well, it keeps on going like this,
3:04 repeating that same sequence forever.
3:07 The digits of a rational number either end
3:09 or keep repeating like this.
3:11 And because of that, you can know exactly what all
3:13 of those decimal digits are, even when they go on forever.
3:17 Since this sequence of 6 digits repeats, you already know
3:21 what the 501st digit is going to be: ’4’.
3:24 But for pi, you don’t know what the 501st digit
3:27 is going to be until you calculate it.
3:29 So one way to understand the difference between
3:31 rational and irrational numbers is that the digits of a
3:34 rational number can be completely known,
3:36 but an irrational number always has
3:38 more digits that you don’t know…
3:40 they’re kind of mysterious that way!
3:42 There’s another cool thing about
3:44 irrational numbers that I want to show you.
3:46 In our video lesson about the Number Line we learned
3:48 that you can subdivide the space between
3:50 two consecutive marks on the number line.
3:52 And you can subdivide the smaller space between
3:54 two of those new marks.
3:56 And you can keep doing that, forever!
3:59 So let’s look at the value of pi on the number line.
4:01 It’s right about here, between the 3 and the 4.
4:04 And now let's zoom in. As we zoom in we keep
4:07 dividing the spaces into smaller and smaller spaces.
4:10 It might seem that if we kept zooming in,
4:13 eventually the value of pi would line up
4:15 exactly with one of our marks. But it won’t.
4:18 Since pi is an irrational number,
4:20 even if we could zoom in forever,
4:22 we would never get to a point where pi exactly lines up
4:24 with a mark on the number line.
4:26 It might get really close, but as we keep zooming in
4:29 we’ll see that it doesn’t quite line up and it never will.
4:33 Pretty cool, huh?
4:35 There’s one last thing I want to tell you
4:36 about irrational numbers.
4:38 It might seem like there are just a few special numbers
4:40 that happen to be irrational, but in reality,
4:43 there are infinitely many irrational numbers.
4:46 In fact there are more irrational numbers
4:48 than there are rational numbers!
4:50 I don’t know about you, but I find that amazing!!
4:54 Alright, hopefully you now understand
4:56 irrational numbers a bit better.
4:58 And you realize they aren’t called irrational
5:00 because they’re insane, they’re called
5:01 irrational because they are not rational.
5:04 They can’t be represented as a ratio of two integers.
5:07 So they can’t be accurately represented as a fraction.
5:10 And their decimal digits go on forever
5:12 and don’t end in a repeating pattern.
5:14 Alright, that’s it for this video.
5:16 Keep practicing and I’ll catch you in the next one.
5:19 And for better access to all of our material,
5:21 check out mathantics.com