Algebra Basics: Laws Of Exponents - Math Antics - By Mathantics
Transcript
| 00:03 | Do you know why I pulled you over today somewhat | |
| 00:06 | ? That's right . A law , this law to | |
| 00:08 | be exact laws of exponents ? I've never even heard | |
| 00:12 | of these . How was I supposed to know ? | |
| 00:14 | You must have never heard of math antics . There's | |
| 00:16 | this really cool math video series . They have all | |
| 00:19 | sorts of basic math videos and the host is really | |
| 00:22 | funny . Is this some sort of add , can | |
| 00:25 | I skip this ? No , I think you'll really | |
| 00:26 | like it , check it out . Mhm . Mm | |
| 00:32 | Hi , this is rob . Welcome to Math Antics | |
| 00:35 | in this video . We're going to learn about the | |
| 00:37 | laws of exponents . If you look up the laws | |
| 00:39 | of exponents online or in a math book , you'll | |
| 00:42 | probably see a long list of equations that looks something | |
| 00:44 | like this , wow , That's kind of overwhelming when | |
| 00:48 | you see them all at once . But don't worry | |
| 00:50 | , we'll take them one step at a time and | |
| 00:52 | you'll see that they're not that complicated after all . | |
| 00:54 | But before we get going , if you're not confident | |
| 00:57 | with the basics of exponents , I highly recommend watching | |
| 01:00 | our previous videos about them . Before moving on in | |
| 01:02 | this video . Okay , let's start with just the | |
| 01:05 | first two laws on our list . Which should look | |
| 01:07 | familiar . If you watched our video called exponents in | |
| 01:10 | algebra , they're just the two rules we learned in | |
| 01:13 | that video . You know , rules laws , same | |
| 01:16 | difference . So you probably already know them . They | |
| 01:19 | simply tell us that anything raised to the first power | |
| 01:21 | is itself and anything raised to the zero with power | |
| 01:24 | is just one . And because we already know about | |
| 01:27 | exponents that are higher energy values like X . To | |
| 01:30 | the second X to the third . That means we've | |
| 01:32 | pretty much got things covered , right ? Ah Not | |
| 01:35 | so fast . Don't forget that integers can have negative | |
| 01:38 | values too . For example what if we had the | |
| 01:40 | expression X . To the power of negative one or | |
| 01:44 | negative two ? Or negative three ? We know that | |
| 01:47 | exponents are a way of doing repeated multiplication . But | |
| 01:50 | how in the world could you multiply something together ? | |
| 01:52 | A negative number of times ? Well you can't fortunately | |
| 01:57 | . The next law on our list tells us how | |
| 01:58 | to interpret a negative exponent . That law says X | |
| 02:01 | to the negative and power equals one divided by X | |
| 02:05 | to the power . And if you think about it | |
| 02:07 | , that kind of makes sense . A negative number | |
| 02:10 | is the inverse of its positive counterpart . And division | |
| 02:13 | is the inverse operation of multiplication . Right ? So | |
| 02:16 | a negative exponents is basically repeated , division X to | |
| 02:20 | the negative one would be one divided by X . | |
| 02:23 | X . To the negative two would be one divided | |
| 02:25 | by X divided by X . X . To the | |
| 02:28 | negative three would be one divided by X divided by | |
| 02:30 | X divided by X . And so on . Seeing | |
| 02:33 | it like this makes the pattern clear . But mathematicians | |
| 02:36 | prefer to express negative exponents infraction form where one is | |
| 02:40 | divided by the same number of X is multiplied together | |
| 02:43 | . But since those multiplied exes are all on the | |
| 02:45 | bottom of the fraction you're actually dividing by all of | |
| 02:48 | them . Here's an example that will help you see | |
| 02:51 | that that's true To to the negative 3rd power . | |
| 02:54 | Let's first try that as a repeated division problem . | |
| 02:56 | Like our pattern chose us . We always start with | |
| 02:59 | a one so we would have one divided by two | |
| 03:02 | divided by two divided by two . If we do | |
| 03:04 | those operations from left to right using a calculator we | |
| 03:07 | get 0.125 as the answer . Now let's write an | |
| 03:11 | infraction for him . Like our law of exponents tells | |
| 03:13 | us we can to to the negative third power would | |
| 03:16 | be the same as one divided by two to the | |
| 03:19 | third power . And that's the same as 1/2 times | |
| 03:22 | two times two . Which simplifies to 1/8 and 1/8 | |
| 03:26 | simplifies to 0.125 See whether you write it as a | |
| 03:30 | pattern of repeated division or infraction form . Like our | |
| 03:33 | inverse law shows you get the same answer . And | |
| 03:36 | now you know how to handle any expression with a | |
| 03:38 | negative exponents . It's just one over the same expression | |
| 03:42 | with a positive exponent X . To the negative one | |
| 03:45 | is one over X . To the positive one . | |
| 03:47 | Or just one over X . X . To the | |
| 03:49 | negative two is one over X . To the positive | |
| 03:52 | too X to the -3 is one over X to | |
| 03:55 | the positive three and so on . All right . | |
| 03:58 | Three laws down five more to go . And these | |
| 04:01 | next five show us how we can do various math | |
| 04:03 | operations involving exponents . In fact , the next law | |
| 04:07 | tells us how we can take a number raised to | |
| 04:09 | a power and then raise that to a power . | |
| 04:12 | As you can see . It shows an expression X | |
| 04:14 | to the power of them grouped inside parentheses . And | |
| 04:17 | then that whole group is being raised to the end | |
| 04:19 | power . It's a nesting situation . Kind of like | |
| 04:22 | those Russian nesting dolls . So what if someone asked | |
| 04:25 | you to simplify the expression X squared cubed ? Which | |
| 04:29 | means the entire X squared term is raised to the | |
| 04:31 | third power ? Well , our law tells us that | |
| 04:34 | we can simplify that by multiplying the exponents together . | |
| 04:37 | See how it equals X . To the power of | |
| 04:39 | Mn . Which means M . Times in that means | |
| 04:43 | X squared raised to the third power would be the | |
| 04:46 | same as X to the power of two times three | |
| 04:48 | , which is six . I want to see why | |
| 04:50 | that's true . Well , think about what it would | |
| 04:53 | mean to raise X squared to the third power . | |
| 04:56 | It would mean multiplying three X squared terms together like | |
| 04:59 | this . And each one of those X squared terms | |
| 05:02 | simplifies to X times X . Right ? So we | |
| 05:05 | end up with six X is being multiplied together which | |
| 05:08 | is just X to the sixth power . See our | |
| 05:11 | law works great . If you have a number raised | |
| 05:13 | to a power and that's all raised to another power | |
| 05:16 | . You can just multiply the two exponents together to | |
| 05:18 | simplify it . And it works for negative exponents to | |
| 05:21 | like what if we had X squared raised to the | |
| 05:24 | negative third power . Well , our law tells us | |
| 05:26 | that that's the same as X to the power of | |
| 05:29 | two times negative three Which is X to the -6 | |
| 05:33 | . To see if that's true . We'll need to | |
| 05:35 | use the law . We just learned about negative exponents | |
| 05:38 | and rewrite this as one over X squared to the | |
| 05:41 | positive third power . That simplifies to one over X | |
| 05:44 | squared times X squared times X squared . Which in | |
| 05:47 | turn simplifies to 1/6 X . Is being multiplied together | |
| 05:51 | . And that all checks out because one over X | |
| 05:54 | to the sixth would be the same as X . | |
| 05:56 | To the negative sixth power . Pretty cool . Huh | |
| 05:59 | ? Okay . We're halfway through our list of laws | |
| 06:02 | and we're going to look at the next to as | |
| 06:03 | a set because they tell us how we can multiply | |
| 06:06 | and divide expressions that have the same base . And | |
| 06:09 | that's important because we can simplify them to have a | |
| 06:11 | single exponents if the bases were different . The first | |
| 06:14 | law says that if we have the base X with | |
| 06:17 | exponents m being multiplied by the same base X With | |
| 06:21 | exponents in , we can combine them simply by adding | |
| 06:24 | the exponents together . And the second law says if | |
| 06:28 | we have the base X . With exponents M . | |
| 06:30 | Being divided by the same base X with exponent N | |
| 06:34 | . We can combine them simply by subtracting the exponents | |
| 06:38 | . Let's see some examples of each like this 12 | |
| 06:41 | to the third times two to the fourth . Does | |
| 06:44 | that fit the pattern of our first law ? Yep | |
| 06:46 | . The base of both expressions is the same but | |
| 06:49 | they happen to have different exponents . The law would | |
| 06:52 | still work if the exponents were the same but they | |
| 06:54 | don't have to be just the bases have to be | |
| 06:56 | the same . Our law tells us that this would | |
| 06:59 | equal two to the power of three plus four or | |
| 07:03 | two to the seventh power . But does it well | |
| 07:05 | let's break it down and see two to the third | |
| 07:08 | is two times two times two . And that's being | |
| 07:10 | multiplied by two to the fourth which is two times | |
| 07:13 | two times two times two . That's a lot of | |
| 07:15 | two is being multiplied together . 72 is to be | |
| 07:18 | exact ha ha . So that is what you get | |
| 07:20 | by just adding the exponents together . Since three plus | |
| 07:23 | four equals seven . And this law makes total sense | |
| 07:26 | . If you think about what an exponent really means | |
| 07:29 | . The exponent is telling you to do repeated multiplication | |
| 07:32 | of the base . Right ? So this first part | |
| 07:35 | is telling you to multiply three twos together . And | |
| 07:37 | the second part is telling you to multiply four twos | |
| 07:40 | together . So that's why you can add the exponents | |
| 07:43 | together if the base is the same or think about | |
| 07:46 | it like this . If we had 10 X . | |
| 07:49 | Is all being multiplied together . We could form different | |
| 07:52 | groups of them and combine them using exponents . Like | |
| 07:54 | we could combine the first four exes into X to | |
| 07:57 | the fourth and combine the remaining six . X . | |
| 07:59 | Is into X to the sixth . And of course | |
| 08:02 | those expressions would be multiplied together since all of the | |
| 08:05 | exes were being multiplied . But you'd probably never want | |
| 08:08 | to do that , would you ? I mean why | |
| 08:10 | not just combine all 10 X is into the expression | |
| 08:12 | X to the 10th . Ah But there you see | |
| 08:15 | that our law holds true . X to the fourth | |
| 08:17 | times X . To the sixth . Would equal X | |
| 08:20 | to the power of four plus six or X to | |
| 08:22 | the 10th . Okay now let's move on and see | |
| 08:25 | some examples of the second law in this set which | |
| 08:27 | tells us how to divide expressions with the same base | |
| 08:30 | . Suppose we have the expression five to the third | |
| 08:33 | power divided by five to the second power . Our | |
| 08:36 | law says that we can simplify this by subtracting the | |
| 08:39 | exponents . Specifically we take the exponent on the top | |
| 08:42 | and subtract the exponents on the bottom from it . | |
| 08:45 | If we do that , the simplified version would be | |
| 08:47 | five to the power of 3 -2 or five to | |
| 08:50 | the first power . But is that right to see | |
| 08:54 | let's write the expression out in expanded form on the | |
| 08:57 | top of our division problem . We have five to | |
| 08:59 | the third which is five times five times five . | |
| 09:01 | And on the bottom we have five to the second | |
| 09:04 | which is five times five . Does this look like | |
| 09:06 | something you've seen while simplifying fractions , yep . Since | |
| 09:09 | all the bases are the same , they form pairs | |
| 09:12 | of common factors on the top and bottom . That | |
| 09:14 | can be cancelled out . This 5/5 cancels and this | |
| 09:17 | 5/5 cancels . If you don't know why that works | |
| 09:20 | . Be sure to watch our video about simplifying fractions | |
| 09:23 | and what do we end up with ? Well all | |
| 09:25 | the factors on the bottom cancelled out . Which leaves | |
| 09:27 | one since there is always a factor of one and | |
| 09:30 | there's only 15 left on the top . So our | |
| 09:32 | expression simplified to 5/1 or just five . Following our | |
| 09:37 | law , we got a simplified version of five to | |
| 09:39 | the first power which is also just five . So | |
| 09:41 | it really did work . But to make sure you've | |
| 09:44 | really got it , Let's try using this law again | |
| 09:46 | with the expression X . to the fourth power over | |
| 09:48 | X to the 6th power . This one's interesting . | |
| 09:52 | Our law says that we can simplify it by subtracting | |
| 09:54 | the bottom X moment from the top right . But | |
| 09:57 | in this case that will give us a negative exponents | |
| 09:59 | . Because the bottom exponent is bigger than the top | |
| 10:02 | 4 -6 would be negative too . So according to | |
| 10:05 | our law , this expression should be equal to X | |
| 10:08 | to the negative too . Let's try writing it out | |
| 10:11 | in expanded form to see if that's true . On | |
| 10:13 | the top X to the fourth would be the same | |
| 10:16 | as four X is multiplied together and on the bottom | |
| 10:18 | X to the sixth would be the same as six | |
| 10:20 | . X is multiplied together . Once again , we | |
| 10:23 | see that there are pairs of common factors that we | |
| 10:25 | can cancel or pairs to be precise . And when | |
| 10:28 | we cancel them all , we're left with a one | |
| 10:30 | on the top because there's always a factor of one | |
| 10:33 | and only two Xs multiplied together on the bottom . | |
| 10:36 | If we recombine these two exes , we get one | |
| 10:38 | over X squared . And if you remember the law | |
| 10:40 | we learnt earlier about negative exponents . You'll see that | |
| 10:43 | one over X squared is exactly the same as X | |
| 10:46 | . To the power of negative two . So these | |
| 10:49 | laws really do work okay . It's finally time to | |
| 10:52 | look at the last two laws on our list and | |
| 10:54 | fortunately there pretty easy ones , so we're not going | |
| 10:57 | to spend too much time on them . These laws | |
| 10:59 | look kind of similar to the last pair , just | |
| 11:01 | like before . The first one involves multiplication and the | |
| 11:04 | second one involves division . But notice that in these | |
| 11:07 | laws the bases are different , but the exponents are | |
| 11:09 | the same . That's the exact opposite of the situation | |
| 11:12 | with the last pair of laws . It turns out | |
| 11:14 | that these laws aren't about simplifying exponents there about how | |
| 11:17 | you can distribute or un distribute a common exponent to | |
| 11:20 | different bases . The first law shows this group X | |
| 11:24 | times Y . That's being raised to the power of | |
| 11:26 | em . And it says that you can rewrite it | |
| 11:28 | as X . To the M times why to the | |
| 11:30 | M . In other words you can distribute the exponent | |
| 11:33 | to each factor in the group . And the second | |
| 11:36 | law shows the group X divided by Y . That's | |
| 11:38 | being raised to the power of in . And it | |
| 11:40 | says that you can rewrite it as X to the | |
| 11:42 | in divided by Y . To the in in other | |
| 11:45 | words you can distribute the exponents to each part of | |
| 11:47 | the fraction . Of course these laws would work in | |
| 11:50 | reverse too and you could undistributed exponents if they're the | |
| 11:53 | same . For example , if you're given the expression | |
| 11:57 | X squared times y squared , you could rewrite that | |
| 12:00 | as the quantity X times Y squared . And if | |
| 12:03 | you have the expression X squared divided by Y squared | |
| 12:06 | , you could rewrite that as the quantity X over | |
| 12:08 | Y squared . There are two expressions that will help | |
| 12:12 | you see why you can distribute or un distribute exponents | |
| 12:15 | like our laws show in the first expression we have | |
| 12:18 | the quantity X times Y squared and that's the same | |
| 12:21 | as X times Y times X times Y . And | |
| 12:24 | the community of property says that we can rearrange those | |
| 12:27 | factors like this , X times X times Y times | |
| 12:30 | Y . But look , we can simplify that into | |
| 12:33 | X squared times Y squared . So that checks out | |
| 12:36 | in the second expression we have the quantity X over | |
| 12:39 | Y squared . That's the same as X over Y | |
| 12:42 | times X over Y . To multiply these fractions . | |
| 12:45 | We just multiply the tops and multiply the bottoms . | |
| 12:48 | Which gives us X times X over Y times Y | |
| 12:51 | . And that simplifies to X squared over white square | |
| 12:54 | . So that one checks out too . All right | |
| 12:57 | . So now , you know about the so called | |
| 12:59 | laws of exponents and there's a good chance that you'll | |
| 13:01 | see them explained in slightly different forms or different orders | |
| 13:05 | or even using different terminology in other math videos or | |
| 13:08 | books . But the basic ideas will be the same | |
| 13:11 | . Some people like to try to memorize this list | |
| 13:14 | of laws and you can do that if you want | |
| 13:15 | to , but it's an even better idea to focus | |
| 13:18 | on knowing how exponents really work , because if you | |
| 13:21 | truly understand that , you can actually figure out a | |
| 13:23 | lot of these laws for yourself and what's the best | |
| 13:26 | way to understand how exponents really work , yep , | |
| 13:29 | you gotta practice . So be sure to do some | |
| 13:31 | problems with exponents on your own . As always . | |
| 13:34 | Thanks for watching Math Antics and I'll see you next | |
| 13:36 | time learn more at Math Antics dot com . So | |
| 13:41 | what do you think ? I thought you said the | |
| 13:43 | guy was going to be funny . |
Summarizer
DESCRIPTION:
OVERVIEW:
Algebra Basics: Laws Of Exponents - Math Antics is a free educational video by Mathantics.
This page not only allows students and teachers view Algebra Basics: Laws Of Exponents - Math Antics videos but also find engaging Sample Questions, Apps, Pins, Worksheets, Books related to the following topics.
GRADES:
STANDARDS:
