Writing Equations in Two Variables - By Anywhere Math
Transcript
| 00:0-1 | Welcome to anywhere . Math . I'm Jeff , Jacobson | |
| 00:02 | and Well let's see . We've written equations with one | |
| 00:06 | variable . We've solved those equations using addition and subtraction | |
| 00:11 | . We solve them using multiplication and division . Now | |
| 00:15 | it's time to write equations with two variables . Let's | |
| 00:19 | get started . So today we're writing equations in two | |
| 00:41 | variables first . What exactly are we talking about when | |
| 00:44 | we're saying equations in two variables ? Well uh equations | |
| 00:49 | in two variables that represents two quantities that change in | |
| 00:53 | relationship to one another . This word relationships really important | |
| 00:57 | . What that means is as one of the variables | |
| 01:00 | change . So does the other variable . They're related | |
| 01:04 | to each other . You can't change one and not | |
| 01:06 | the other um Or you can't change one and the | |
| 01:09 | other one not be affected I should say . So | |
| 01:12 | now . Well what exactly would a solution to an | |
| 01:15 | equation like that look like ? Well you've got two | |
| 01:18 | variables so you're gonna have to values in your solution | |
| 01:22 | and that solution to an equation two variables is an | |
| 01:26 | ordered parent . Okay . So commonly like an X | |
| 01:34 | . Y . Okay . Where each one of these | |
| 01:38 | uh values would be would work together as a solution | |
| 01:42 | to your to your equation . Um Let's talk a | |
| 01:46 | little bit more about what these values are called and | |
| 01:50 | what they look like . So the two variables in | |
| 01:53 | these types of equations have names . 1st 1 we | |
| 01:56 | call the independent variable and that's just the quantity that | |
| 02:00 | can change freely . Basically we choose what that value | |
| 02:04 | is for that variable . Okay now the second variable | |
| 02:07 | we call the dependent variable and just like the name | |
| 02:12 | . The value depends on what the independent variable is | |
| 02:17 | . Now that might be a little bit confusing but | |
| 02:19 | for example here's my favorite mug . Uh If I | |
| 02:24 | have coffee in this mug and I'm drinking some okay | |
| 02:28 | and I ask you well how much coffee is left | |
| 02:32 | you would say ? Well it depends it depends on | |
| 02:35 | how much I drank already . Right ? So in | |
| 02:40 | that situation uh the dependent variable would be , what | |
| 02:47 | is it how much I drink or how much is | |
| 02:49 | left ? Well the dependent variable would be how much | |
| 02:52 | is left because how much is left depends on how | |
| 02:57 | much I already drank , right ? The independent variable | |
| 03:01 | would be how much I drank , right ? I | |
| 03:03 | can decide that on my own . I can take | |
| 03:05 | one sip , I could take two , I could | |
| 03:07 | do the whole thing . Okay so how much I | |
| 03:10 | drink would be independent variable . How much is left | |
| 03:13 | would be the dependent variable because it depends on how | |
| 03:17 | much I drink . So hopefully that helps keep them | |
| 03:19 | clear . Now we can graph uh these types of | |
| 03:25 | these variables and the solutions as an ordered pair , | |
| 03:28 | right ? We've graphed ordered pairs before if you're wondering | |
| 03:31 | which one would be the X . Axis . Which | |
| 03:33 | would be the Y . Typically uh the independent variable | |
| 03:38 | , the one that you choose freely . That would | |
| 03:41 | represent your ex value on the X axis . Independent | |
| 03:46 | yes . Would be like your ex value and you're | |
| 03:49 | dependent . Would then be your y depend . Okay | |
| 03:56 | so if you think you have an order pair typically | |
| 03:58 | you would say you're independent value first and then you're | |
| 04:01 | dependent . Okay let's look at example . Alright example | |
| 04:05 | one tell whether the order pair is a solution . | |
| 04:08 | So for my first one why it was two X | |
| 04:11 | . My order pair is 36 . So I'm gonna | |
| 04:13 | see if that's a solution . If it's a solution | |
| 04:15 | it should make this equation true . Just like a | |
| 04:18 | solution to uh an equation with just one variable . | |
| 04:22 | So to check all I have to do is substitute | |
| 04:26 | this three is my ex value . So I'm going | |
| 04:30 | to substitute that three in there and this six is | |
| 04:33 | my why value ? So I'm gonna substitute in for | |
| 04:36 | why ? So when I do that I'm gonna get | |
| 04:40 | I'll do it in red six . And the question | |
| 04:45 | is that equal to uh two times substitute ? I | |
| 04:52 | didn't blue the three in for X . So two | |
| 04:54 | times three . Right ? That's the question . Well | |
| 04:58 | two times three is six so we have six is | |
| 05:01 | equal to six . So yes 36 is a solution | |
| 05:07 | to that . Uh that equation . Now is it | |
| 05:10 | the only solution ? Right ? That's another question . | |
| 05:14 | We won't get into that yet . Um But three | |
| 05:16 | sixes a solution . So let's do the next one | |
| 05:19 | . Why equals four X minus three . We're asking | |
| 05:22 | is 4 12 that ordered pair . Is it a | |
| 05:24 | solution ? You can pause the video and try it | |
| 05:27 | on your own first . Um Here we go . | |
| 05:30 | So four again I'm gonna substitute at that in for | |
| 05:33 | my ex 12 . I'm gonna substitute in for my | |
| 05:35 | why ? So I get 12 is equal to . | |
| 05:40 | Well that's the question we're seeing . If it is | |
| 05:42 | Four times four , make sure you use your parentheses | |
| 05:47 | , right ? If you don't have them it's gonna | |
| 05:49 | look like 44 uh minus three . Again . 12 | |
| 05:54 | . Is that equal to ? Well four times four | |
| 05:56 | is 16 minus 3 . 16 minus three is 13 | |
| 06:00 | . So is that equal to 12 ? No they | |
| 06:03 | are not equal . Which means 4 12 is not | |
| 06:08 | a solution . Okay let's do another example . Alright | |
| 06:11 | here we go . With example too . The equation | |
| 06:14 | y equals 128 -8 x . gives the amount why | |
| 06:19 | in fluid ounces of milk left in a gallon jug | |
| 06:23 | after you pour X amount of cups . Okay uh | |
| 06:27 | So first part A . Is identified the independent and | |
| 06:30 | dependent variable . So again independent . That's the thing | |
| 06:34 | that changes freely . That's the thing that we would | |
| 06:36 | decide , dependent variables , depend on what you decide | |
| 06:42 | with the independent what what you do first with the | |
| 06:44 | independent variable ? Uh So sometimes when you're doing this | |
| 06:48 | it's easier to find out the dependent variable first . | |
| 06:52 | So in this situation uh First what are two variables | |
| 06:56 | ? Well we've got Y . And X . Um | |
| 06:59 | What does that X . Represent for X . Represents | |
| 07:02 | the number of cups yeah . Of milk that we | |
| 07:09 | pour out of the jug . Why represents how much | |
| 07:14 | is left the amount why in food ounces of milk | |
| 07:16 | left ? So I just write milk milk left . | |
| 07:23 | So if I think about that Um you might notice | |
| 07:27 | . Well then if we're subtracting eight X . Where | |
| 07:31 | did that eight come from ? Right . For example | |
| 07:34 | if we have one , we poured one cup . | |
| 07:37 | We multiply by eight . How why would we multiply | |
| 07:40 | by it ? If you look here why isn't fluid | |
| 07:43 | ounces ? This isn't cups were multiplying the amount of | |
| 07:47 | cups times eight . That's because there's eight fluid ounces | |
| 07:50 | in a cup . Okay Um where is that ? | |
| 07:53 | 128 come from ? We're starting with that . We're | |
| 07:57 | subtracting out how many cups . So if you think | |
| 07:59 | well what if I didn't pour any any cups of | |
| 08:03 | milk out ? Right ? So if that was zero | |
| 08:07 | Um eight times zero is just zero . So we're | |
| 08:09 | subtracting zero . That basically goes away and we have | |
| 08:12 | 128 . So that would be the milk left is | |
| 08:15 | 128 fluid ounces . That 128 represents how much is | |
| 08:20 | in the jug in a full jug ? Right so | |
| 08:23 | 128 fluid ounces in one gallon jug . Okay um | |
| 08:28 | So that's where those come from , that's where those | |
| 08:30 | numbers come from , it . Sometimes it helps to | |
| 08:32 | know that . So anyway let's get back to independent | |
| 08:35 | dependent variables . What's the thing that depends on the | |
| 08:39 | other thing ? Do the amount of cups that we | |
| 08:43 | choose that we pour out ? Does that depend on | |
| 08:45 | anything ? No that's we choose that up to ourselves | |
| 08:49 | . How about how much milk is left ? Does | |
| 08:50 | that depend on anything ? Well yeah , the amount | |
| 08:53 | of milk left depends on how many cups of milk | |
| 08:56 | we pour out . So that should tell you that | |
| 08:59 | the dependent variable is the why ? Yeah . Uh | |
| 09:05 | huh . Equals the Y . Which is the uh | |
| 09:09 | the milk left ? Okay . And the independent , | |
| 09:16 | what we choose freely is how many cups we pour | |
| 09:19 | out . So independent then . Yeah , that variables | |
| 09:25 | the X . Variable . And that's the number of | |
| 09:29 | cops that we pour out . Okay so that's part | |
| 09:32 | A . Now part B . How much milk is | |
| 09:35 | left after 10 cups ? Well again 10 cups that's | |
| 09:39 | represented by X . In my variables . So If | |
| 09:43 | X . is equal to 10 , all I need | |
| 09:44 | to do to find out how much milk is left | |
| 09:47 | is substitute . So I'm gonna have y . is | |
| 09:50 | equal to 128 -8 . I'm gonna use my parentheses | |
| 09:56 | . Uh eight times 10 cups . Well , order | |
| 10:01 | of operations . I'm gonna do my multiplication first . | |
| 10:04 | Why equals 1 . 28 minus eight times 10 is | |
| 10:07 | 80 . Now I've got my subtraction . Y . | |
| 10:10 | Equals 48 . And units . Remember why was in | |
| 10:16 | fluid ounces ? So 48 fluid ounces of milk left | |
| 10:23 | . Okay . As pop . You can't I'm sorry | |
| 10:25 | you can't see that . 48 fluid ounces left . | |
| 10:31 | Okay so there's my final answer for being here is | |
| 10:35 | something to try on your own . Thank you so | |
| 10:44 | much for watching . And if you like this video | |
| 10:46 | please subscribe |
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