Algebra Basics: Exponents In Algebra - Math Antics - By Mathantics
Transcript
| 00:03 | Uh huh . Hi , I'm rob . Welcome to | |
| 00:07 | Math Antics . We've already learned a little about how | |
| 00:10 | exponents and roots are used in arithmetic and now it's | |
| 00:13 | time to learn the basics of how they're used in | |
| 00:15 | algebra . As you know , one of the main | |
| 00:18 | differences between arithmetic and algebra is that algebra involves unknown | |
| 00:23 | values and variables in arithmetic . You might have the | |
| 00:26 | exponent for squared , but in algebra you're more likely | |
| 00:30 | to see the exponent X squared and when it comes | |
| 00:33 | to roots instead of seeing the square root of 16 | |
| 00:36 | , you might see the square root of X . | |
| 00:39 | Of course . One of the main goals in algebra | |
| 00:41 | is to figure out what those unknown values are and | |
| 00:44 | we're going to learn a bit about how to do | |
| 00:46 | that in a minute . But first we're going to | |
| 00:48 | learn something about exponents by looking at an important pattern | |
| 00:51 | in algebra . It's the pattern formed by the expression | |
| 00:55 | X to the 10th power . Where in is any | |
| 00:58 | integer in this expression X could be any number but | |
| 01:02 | in can only be an integer . And to keep | |
| 01:05 | things simple in this video we're only going to consider | |
| 01:07 | non negative integers . That is will limit in to | |
| 01:11 | be this set of numbers 0123 and so on . | |
| 01:15 | If n is zero then we have X to the | |
| 01:18 | zero with power . If n is one then we | |
| 01:21 | have X to the first power . If n is | |
| 01:24 | two , then we have X to the second power | |
| 01:26 | or X squared if n is three then we have | |
| 01:29 | X to the third power or X cubed . And | |
| 01:32 | we could keep on going with this pattern . X | |
| 01:34 | to the fourth . X to the fifth to infinity | |
| 01:37 | . Okay . But what do these exponents mean ? | |
| 01:40 | Well X squared is pretty easy to understand . We | |
| 01:43 | know from our definition of exponents that X squared would | |
| 01:46 | be the same as X times X . We also | |
| 01:49 | know that X cubed would be X times X times | |
| 01:52 | X and going up to higher values of in would | |
| 01:55 | just means multiplying more exes together . But what about | |
| 01:58 | X to the first power ? Well if X to | |
| 02:01 | the second power means multiplying two exes together , then | |
| 02:05 | X to the first power should mean multiplying one X | |
| 02:08 | together . Which sounds kind of funny when we say | |
| 02:10 | it like that . But as you can see that | |
| 02:13 | pattern makes sense . X to the first power would | |
| 02:16 | just be X . And that helps us see an | |
| 02:18 | important rule about exponents . Any number raised to the | |
| 02:22 | first power is just itself . This rule or property | |
| 02:26 | is similar to the identity property of multiplication that says | |
| 02:29 | any number multiplied by one is just itself . Okay | |
| 02:33 | , so X to the first power makes sense . | |
| 02:35 | But what about X To the zero with power ? | |
| 02:38 | Does that mean no excess multiplied together ? That seems | |
| 02:41 | even stranger . And the rule about the zeroth power | |
| 02:44 | may surprise you . It seems like X to the | |
| 02:47 | zero power should be zero . But it's actually one | |
| 02:50 | which will make a lot more sense if we modify | |
| 02:52 | our pattern a little . Do you remember that because | |
| 02:55 | of the identity property of multiplication , there is always | |
| 02:58 | a factor of one in any multiplication problem Or is | |
| 03:02 | the same as one times 4 ? five is the | |
| 03:05 | same as one times 5 and so on . Well | |
| 03:09 | , that means we can also include a factor of | |
| 03:11 | one . And our pattern of exponents X to the | |
| 03:13 | first is one times X . X to the second | |
| 03:17 | is one times X times X . X to the | |
| 03:19 | third is one times X times X times X and | |
| 03:22 | so on . And if we continue that pattern , | |
| 03:25 | the other direction , you'll see that there will be | |
| 03:27 | a one left there , even when all the exes | |
| 03:29 | are gone . So now , you know , another | |
| 03:31 | important rule about exponents , Any number raised to the | |
| 03:35 | zeroth power is just one . Knowing these rules about | |
| 03:39 | exponents is important in algebra and will help us when | |
| 03:42 | we talk about polynomial is in the next video . | |
| 03:44 | Before the rest of this video , we're going to | |
| 03:46 | learn how to solve some really basic algebraic equations that | |
| 03:49 | involve exponents and roots . Let's start off with this | |
| 03:53 | equation , The square root of X equals three . | |
| 03:56 | How do we solve for X . And this equation | |
| 03:58 | , in other words , how do we figure out | |
| 03:59 | the value of X without just guessing the answer ? | |
| 04:02 | Well , we know that the key to solving an | |
| 04:05 | algebraic equation is to get the unknown value all by | |
| 04:08 | itself on one side of the equal sign . And | |
| 04:11 | you might be thinking that in this equation , the | |
| 04:13 | X looks like it's already by itself after all , | |
| 04:16 | there's no other numbers with it . But getting an | |
| 04:19 | unknown by itself means we need to isolate it from | |
| 04:21 | any other numbers and operators so that it's completely by | |
| 04:25 | itself in this equation , that means we need to | |
| 04:28 | somehow get rid of the square root sign that the | |
| 04:30 | X is under . Ha need to get rid of | |
| 04:33 | that pesky square root sign . Do you ? Let's | |
| 04:36 | see . I'll just use my magic wand and that | |
| 04:41 | usually works . I know . Uh huh . This | |
| 04:51 | is gonna be harder than I thought , wow . | |
| 04:55 | 1 2 . Whoa , hold on . Now that | |
| 04:59 | seems a bit extreme and it won't even help . | |
| 05:02 | I mean this is a math operation . And to | |
| 05:04 | get rid of a math operation , you need to | |
| 05:06 | use its inverse operation . Well , I was gonna | |
| 05:09 | try that next in the video called exponents and square | |
| 05:14 | roots . We learn that . Exponents and roots are | |
| 05:17 | inverse operations . If we want to undo an exponent | |
| 05:20 | , we need to use a route and if we | |
| 05:22 | want to undo a route we need to use an | |
| 05:23 | exponent . So in this equation to undo the second | |
| 05:27 | route or square root of X , we're going to | |
| 05:30 | need to raise it to the second power or square | |
| 05:33 | it . If we square the square root of X | |
| 05:36 | , those operations will cancel out and we'll be left | |
| 05:40 | with just X . But why does that work ? | |
| 05:43 | Well , you can see why it works . If | |
| 05:45 | you remember what the square root of X really means | |
| 05:48 | , The square root of X is a number that | |
| 05:50 | we can multiply together twice to get X . For | |
| 05:54 | example , the square root of four is too , | |
| 05:57 | because if you multiply two times two , you get | |
| 06:00 | four . So since the square root of four is | |
| 06:03 | the same as to , We could also just say | |
| 06:06 | that the square root of four times the square root | |
| 06:08 | of four is 4 . And do you see how | |
| 06:11 | the square root of four times the square root of | |
| 06:14 | four is the same as the square root of four | |
| 06:17 | squared ? And this is true for any number , | |
| 06:20 | which is why squaring the square root of X just | |
| 06:23 | leaves us with X . The exponent and the route | |
| 06:26 | operations cancel each other out . Okay , so we | |
| 06:30 | can undo the square root by squaring that side of | |
| 06:33 | the equation . But remember to keep our equation and | |
| 06:36 | balance , we need to do the same thing to | |
| 06:39 | both sides . So we need to square the three | |
| 06:41 | also three squared is three times three , which is | |
| 06:45 | nine there . By squaring both sides of the equation | |
| 06:49 | . We changed it into X equals nine . We | |
| 06:51 | solve for X . That was pretty easy . Let's | |
| 06:54 | try solving another simple problem with the root . This | |
| 06:57 | one is the cube root of x equals five . | |
| 07:01 | Just like before . We need to get X all | |
| 07:03 | by itself by undoing the route . But since it's | |
| 07:07 | a cube root this time , we can't undo that | |
| 07:09 | by squaring both sides . Instead , we need to | |
| 07:12 | cube both sides . You always need to undo a | |
| 07:15 | route with the corresponding exponent , third root , third | |
| 07:19 | power , fourth root , fourth power and so on | |
| 07:23 | . So to solve this equation , we need to | |
| 07:25 | raise each side of the equation to the third power | |
| 07:28 | . On the first side , the operations cancel leaving | |
| 07:31 | X all by itself . On the other side we | |
| 07:34 | have five to the third power , which is five | |
| 07:37 | times five times five or 125 . So x equals | |
| 07:42 | 125 . All right . So that's how you saw | |
| 07:46 | very simple one step equations with roots . What about | |
| 07:49 | simple equations that have exponents instead of roots like this | |
| 07:53 | ? One X squared equals 36 . Again , we | |
| 07:57 | need to get the X all by itself , which | |
| 07:59 | means we need to deal with the exponent on this | |
| 08:01 | side of the equation . How do we undo an | |
| 08:03 | exponent , yep . We use a route since the | |
| 08:07 | X is being squared . If we take the square | |
| 08:09 | root of X squared , the operations will cancel out | |
| 08:13 | leaving X all by itself . But why does that | |
| 08:16 | work ? Well , think for a minute about what | |
| 08:18 | the square root of X squared would mean ? It | |
| 08:22 | means that you need to figure out what number you | |
| 08:24 | can multiply together twice in order to get X squared | |
| 08:28 | . But that's easy . X times X is X | |
| 08:31 | squared . So that means that the square root of | |
| 08:34 | X squared is just X . So to solve this | |
| 08:37 | equation , we take the square root of both sides | |
| 08:40 | of the equation to keep things in balance on the | |
| 08:42 | first side , the operations cancel out leaving X all | |
| 08:46 | by itself . And on the other side We have | |
| 08:49 | the square root of 36 , which is six . | |
| 08:52 | So the answer to this problem is x equals six | |
| 08:56 | . Well , that's half of the answer anyway . | |
| 08:59 | This problem is actually a little more complicated than it | |
| 09:01 | looks at first . Thanks to negative numbers . Do | |
| 09:05 | you remember in our video about multiplying and dividing integers | |
| 09:09 | ? We learned that if you multiply two negative numbers | |
| 09:11 | together , the answer is actually positive . That turns | |
| 09:15 | out to be really important when it comes to roots | |
| 09:19 | because it means that there's often more than one answer | |
| 09:22 | . For example , we know that the square root | |
| 09:24 | of 36 is six because multiplying six times six gives | |
| 09:28 | us 36 . But because of that rule about negative | |
| 09:32 | numbers negative six times negative six is also 36 . | |
| 09:37 | So it would be just as correct to say that | |
| 09:39 | the square root of 36 is -6 . So which | |
| 09:43 | is it is the square root of 36 6 or | |
| 09:46 | -6 ? The answer is both . This is an | |
| 09:50 | example of a simple algebraic equation that has two solutions | |
| 09:55 | . X could be six or X could be negative | |
| 09:57 | six . X can't be both six and negative six | |
| 10:00 | at the same time . But you could substitute either | |
| 10:03 | value into the equation and it would make the equation | |
| 10:06 | true . So in algebra , when we have a | |
| 10:09 | situation like this where the answer could be positive or | |
| 10:12 | negative , use a special plus or minus sign that | |
| 10:15 | looks like this X equals plus or -6 . And | |
| 10:19 | we use it when we're finding even roots of a | |
| 10:22 | number . Since we know that the answer could be | |
| 10:24 | positive or negative . But what about odd routes like | |
| 10:28 | the cube root of a number ? Like what if | |
| 10:31 | we have to solve the equation X cubed equals 27 | |
| 10:35 | to solve this equation for X . We need to | |
| 10:37 | take the cube root of both sides . On the | |
| 10:40 | first side of the equation , the cube root will | |
| 10:42 | cancel out the cube operation that's being done to X | |
| 10:45 | . Leaving X all by itself . And on the | |
| 10:48 | other side we need to figure out the cube root | |
| 10:50 | of 27 . Using a calculator . Or just by | |
| 10:53 | knowing about the factors of 27 . We see that | |
| 10:56 | the cube root of 27 is three Because three times | |
| 11:00 | 3 times three is 27 . So in this equation | |
| 11:03 | we know that x equals three . But what about | |
| 11:06 | negative numbers ? Is X equals negative three . Also | |
| 11:09 | a valid solution to this equation , nope . And | |
| 11:12 | here's why if you multiply negative three times negative three | |
| 11:16 | times negative three , the answer would be negative . | |
| 11:18 | 27 not 27 . So the cube root of 27 | |
| 11:22 | is three but not negative three . In this case | |
| 11:26 | there is only one solution . Alright . In this | |
| 11:29 | video we learned two important rules about exponents . We | |
| 11:33 | learned that any number raised to the zeroth power equals | |
| 11:36 | one and that any number raised to the first power | |
| 11:39 | is just itself . We also learned how to solve | |
| 11:43 | very simple one step equations involving exponents and roots . | |
| 11:47 | Since their inverse operations to undo a route , you | |
| 11:50 | use its corresponding exponent and to undo an exponent you | |
| 11:54 | use its corresponding route . Of course there's a lot | |
| 11:57 | more to learn about exponents in algebra . But those | |
| 12:00 | are the basics and to make sure you really understand | |
| 12:02 | them , it's important to practice by doing some exercise | |
| 12:05 | problems , as always . Thanks for watching Math Antics | |
| 12:08 | and I'll see you next time learn more at Math | |
| 12:12 | Antics dot com . |
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