Grade 6 (Virginia)
Introduction to proportional relationships
Proportional relationships are relationships between two variables where their ratios are equivalent. Another way to think about them is that, in a proportional relationship, one variable is always a constant value times the other. That constant is known as the "constant of proportionality".
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- Why is math so annoying(56 votes)
- i need more help with this, i don't understand(20 votes)
- Well, a proportional relationship means that the ratio between two variables stayed the same.
4 eggs = 2 cups of milk
8 eggs = 4 cups of milk
30 eggs = 15 cups of milk
As you can see, this is a proportional relationship because the ratio between the number of egg and cup of milk is 2:1 through out the table.
A non-proportional relationship os when the two variables have different ratio
4 eggs = 4 cups of milk
5 eggs = 6 cups of milk
13 eggs = 12 cups of milk
This is not a proportional relationship because there is no same ratio in the table.
Hope that help.(19 votes)
- it's not that annoying, it's pretty cool!(8 votes)
- math. why is math created? Whyyyyyyyyyyyyyyyyy(6 votes)
- At4:06, what if the cost of cake for 40 servings is $50. Even if the pattern is not x2, we can see it as another way. We can see it as +10, or +20. Wouldn't that still count?(1 vote)
- There could be a relationship between number of servings and cost, but it wouldn't be proportional because the price per serving is not constant.
$20 for 10 servings ⇒ $2/serving
$30 for 20 servings ⇒ $1.50/serving
$50 for 40 servings ⇒ $1.25/serving(14 votes)
- im crying inside(6 votes)
- maths would be so much harder without this(5 votes)
- this is hard but kinda understand it little bit.(5 votes)
- I understand it take notes and it help you a little(4 votes)
- [Instructor] In this video, we are going to talk about proportional relationships, and these are relationships between two variables where the ratio between the variables is equivalent. Now that sounds complex or a little bit fancy. It'll hopefully seem a little bit more straightforward once we look at some examples. So let's say I'm looking at a recipe for some type of baked goods, maybe it's some type of pancakes, I've been making a lot of those lately, and we know that for a certain number of eggs how many cups of milk we need. So we have number of eggs, and then we're also going to have cups of milk. And in this recipe, we know that if we're going to use one egg, then we would use two cups of milk, and if we use three eggs, then we're gonna use six cups of milk, and if we use, let's say, 12 eggs, then we're going to use 24 cups of milk. So is this a proportional relationship where the two variables are the cups of milk and the number of eggs? Well, to test that we just have to think about the ratio between these two variables. And you can say that the ratio of the number of eggs to the cups of milk, or the ratio of the cups of milk to the number of eggs. But you just need to ensure that they are always equivalent in these scenarios. So let me make another column here, and I'm gonna think about the ratio of the eggs to the cups of milk. Well, in this first scenario one egg for two cups of milk. This second scenario is three to six. This third scenario is 12 to 24. Are these equivalent ratios? Well, to go from one to three you multiply by three, and also, to go from two to six, you multiply by three. So you multiplied both the variables by three. Similarly, if you multiply the number of eggs by four, then you multiply the number of cups of milk by four as well. So these indeed are all equivalent ratios, one to two, three to six, 12 to 24. In every scenario you have twice as much cups of milk as you have number of eggs. So this would be proportional. So check. Now what would be an example of a non-proportional relationship? We'll stay in this baked goods frame of mind. Let's say you're going to a cake store and you're curious about how much it would cost to buy a cake for different numbers of people. So let's say number of servings, number of servings in one column, and then the cost of the cake. And let me set up two columns right over here. And so let's say if you have 10 servings, the cake costs $20. If you have 20 servings, the cake costs $30. And if you have 40 servings, the cake costs $40. Pause this video and see if you can figure out whether this is a proportional relationship. If it is, why? If it isn't, why not? Alright, well let's just think about the ratios again. And here our two variables are the number of servings and the cost of cake. So if we look at the ratio of the servings, servings, to cost, in this first situation it is 10 to 20, and then it is 20 to 30, and then it is 40 to 40. And so to see if these are equivalent ratios, when we go from 10 to 20 on the number of servings, we're multiplying by two. But when we go from 20 to 30 on the cost of the cake, we aren't multiplying by two, we're multiplying by 1.5, or one and a half. And similarly, when we go from 20 to 40, we are multiplying by two again, but to go from 30 to 40 we aren't multiplying by two, we're multiplying by one and one third. By one and one third. When we multiply our servings by a given amount, we're not multiplying our cost of cake by the same amount. This tells us that this is not proportional. One way to think about proportional relationships, we already said, that the ratio between the variables will be equivalent. Another way to think about it is one variable will always be some constant times the first variable. So in our first example right over here we said the cups of milk is always two times the number of eggs. We can write that down. So cups of milk is always going to be equal to two times the number of eggs. And this number right over here, we call that the constant of proportionality. And you wouldn't be able to set up an equation like this in this scenario. It would have to be more complicated. And so a proportional relationship, the ratios are equivalent between the two variables and you can set it up with an equation like this where you have a constant of proportionality.