Direct and inverse relationship formula 1

What Is the Difference Between a Direct and an Inverse Relationship? | Sciencing

direct and inverse relationship formula 1

Work more hours, get more pay; in direct proportion. This could be Inversely Proportional: when one value decreases at the same rate that the other increases . Equations with direct and inverse variation sound a little intimidating, but really, they're just two In direct variation, as one number increases, so does the other. An example of this is relationship between age and height. Two values are said to be in direct proportion when increase in one results in an increase in the other. Similarly, they are said to be in indirect proportion when.

We could write y is equal to 2x. We could write y is equal to negative 2x. We are still varying directly.

direct and inverse relationship formula 1

We could have y is equal to pi times x. We could have y is equal to negative pi times x. I don't want to beat a dead horse now. I think you get the point. Any constant times x-- we are varying directly.

  • Direct, Inverse, Joint and Combined Variation
  • Direct and inverse proportions
  • Intro to direct & inverse variation

And to understand this maybe a little bit more tangibly, let's think about what happens. And let's pick one of these scenarios. Well, I'll take a positive version and a negative version, just because it might not be completely intuitive. So let's take the version of y is equal to 2x, and let's explore why we say they vary directly with each other.

So let's pick a couple of values for x and see what the resulting y value would have to be. So if x is equal to 1, then y is 2 times 1, or is 2. If x is equal to 2, then y is 2 times 2, which is going to be equal to 4.

So when we doubled x, when we went from 1 to so we doubled x-- the same thing happened to y. So that's what it means when something varies directly. If we scale x up by a certain amount, we're going to scale up y by the same amount. If we scale down x by some amount, we would scale down y by the same amount. And just to show you it works with all of these, let's try the situation with y is equal to negative 2x. I'll do it in magenta.

Direct and inverse proportion

Let's try y is equal to negative 3x. So once again, let me do my x and my y. When x is equal to 1, y is equal to negative 3 times 1, which is negative 3. When x is equal to 2, so negative 3 times 2 is negative 6. So notice, we multiplied. So if we scaled-- let me do that in that same green color. If we scale up x by it's a different green color, but it serves the purpose-- we're also scaling up y by 2.

To go from 1 to 2, you multiply it by 2. To go from negative 3 to negative 6, you're also multiplying by 2. So we grew by the same scaling factor. To go from negative 3 to negative 1, we also divide by 3. We also scale down by a factor of 3. So whatever direction you scale x in, you're going to have the same scaling direction as y.

That's what it means to vary directly. Now, it's not always so clear. Sometimes it will be obfuscated. So let's take this example right over here. And I'm saving this real estate for inverse variation in a second. You could write it like this, or you could algebraically manipulate it.

Or maybe you divide both sides by x, and then you divide both sides by y.

Direct and inverse relationships - Math Central

These three statements, these three equations, are all saying the same thing. So sometimes the direct variation isn't quite in your face. But if you do this, what I did right here with any of these, you will get the exact same result. Or you could just try to manipulate it back to this form over here. And there's other ways we could do it. We could divide both sides of this equation by negative 3. And now, this is kind of an interesting case here because here, this is x varies directly with y.

Or we could say x is equal to some k times y.

direct and inverse relationship formula 1

And in general, that's true. If y varies directly with x, then we can also say that x varies directly with y. It's not going to be the same constant. It's going to be essentially the inverse of that constant, but they're still directly varying.

Now with that said, so much said, about direct variation, let's explore inverse variation a little bit. Whether you have a specific scientific question in mind such as: What happens to the global temperature if the amount of carbon dioxide in the atmosphere increases, or how does the strength of gravity vary when you move further away from the source, or you are more interested in an abstract mathematical setting, finding out the difference between direct and inverse relationships is essential if you want to describe these relationships.

In short, direct relationships increase or decrease together, but inverse relationships move in opposite directions. A bigger diameter means a bigger circumference. In an inverse relationship, an increase in one quantity leads to a corresponding decrease in the other. Faster travel means a shorter journey time. How Does y Vary with x? Scientists and mathematicians dealing with direct and inverse relationships are answering the general question, how does y vary with x?

Here, x and y stand in for two variables that could be basically anything.

direct and inverse relationship formula 1

By convention, x is the independent variable and y is the dependent variable. So the value of y depends on the value of x, not the other way around, and the mathematician has some control over x for example, she can choose the height from which to drop the ball.

direct and inverse relationship formula 1

When there is a direct or inverse relationship, x and y are proportional to each other in some way. Direct Relationships A direct relationship is proportional in the sense that when one variable increases, so does the other. Using the example from the last section, the higher from which you drop a ball, the higher it bounces back up.

A circle with a bigger diameter will have a bigger circumference. If you increase the independent variable x, such as the diameter of the circle or the height of the ball dropthe dependent variable increases too and vice-versa.