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Production possibilities curve

The production possibilities curve (PPC) is a graph that shows all of the different combinations of output that can be produced given current resources and technology. Sometimes called the production possibilities frontier (PPF), the PPC illustrates scarcity and tradeoffs. We can model tradeoffs and scarcity using the example of a hunter-gatherer who can split their time between two activities. Created by Sal Khan.

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  • purple pi purple style avatar for user Adam Staples
    Can't trading get you outside the curve?
    (61 votes)
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  • blobby green style avatar for user Timo.Willemsen
    I don't see why the amount of berries and rabbits couldn't go above the curve, but they could fall below it. You are assuming ceteris paribus. So all variables are the same, if you fall below the curve, Sall said that could be because you're not using equipment efficiently. But that's not assuming ceteris paribus. And if you're not assuming ceteris paribus, then you can get above the curve because you could find a way to work more efficiently.
    (24 votes)
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    • blobby green style avatar for user turnandfall
      What you need to consider is that the frontier is assuming that you are working in the most efficient way. You simply cannot work harder, faster or more effectively with the resources you have. If you hold efficiency constant, when you are being as efficient as possible, then the only things you can change is how many berries or rabbits you get. If you get more rabbits you have to forgo some berries. This is known as Pareto efficiency or productive efficiency. You have to give something up to get something else.
      (113 votes)
  • leaf green style avatar for user metabraid
    Why were the number of berries he got decreasing?
    (30 votes)
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    • purple pi purple style avatar for user PatriciaRomanLopez
      Or you can think of it this way: Say there is a limited number of berries to pick within your village's area. As you pick more and more berries, there will be less berries out in the field for you to find so even though you spend more time looking for berries, you won't find more because there's only a set number of berries per area and the more you find the harder you have to look to find the remainder. That's one way of looking at it. Hope that helps.
      (47 votes)
  • male robot donald style avatar for user Geoff Walsh
    So far the PPF assumes a "two-goods" economy. If we wanted to visualize a "three-goods" economy, would the PPF have 3 axes (X, Y and Z) and the PPF would become a 3D curved surface originating from X=0, Y=0 and Z=0?
    (14 votes)
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    • female robot amelia style avatar for user Narahari Grama
      This almost certainly begs the question, "What if a car maker such as Ford or GM wanted to decide how much of each car to produce?" They obviously have more than 3 models currently in production. Given that we do not have access to higher dimensions, how do these companies make such decisions?

      As I ask this question, I realize that the model described above is extremely simplified. I'm just curious to know how this model is practically applied.
      (12 votes)
  • blobby green style avatar for user belskie
    Trying to take this another step. If you knew something about the relative values or weights of the two goods, could you determine the slope of the line you would need to find the curve at to find the optimal point you would want to be?
    (6 votes)
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    • male robot johnny style avatar for user Andrew Scott
      Typically speaking, distances on the axis are of the same relative value. In this scenario, assuming the distance between 0 and 5 rabbits along the X axis is equal to the distance of 0 and 300 berries on the Y axis, it would mean that 5 rabbits is equal in value (also known as "utility" in the business world) to 300 berries. Accordingly, when creating a PPF for a real life scenario, the distances on the axes between two different options, be they products, projects, etc. should represent an equality in their relative worth, or "utility". When this is properly done, you can use the PPF to find which combination of the two options would maximize utility.
      (9 votes)
  • blobby green style avatar for user Niloy Rahman
    How would unemployment in both industries/axes affect the PPF?
    (10 votes)
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  • blobby green style avatar for user Lucas Medina
    I don't understand what kind of scenario would give you half of a rabbit, or a quarter of a rabbit. Wouldn't the amount of rabbits/berries have to be natural numbers? He said that you could, for example, get 4.5 rabbits, and that would be on the graph. I don't understand how this is even possible.
    (5 votes)
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    • mr pants teal style avatar for user Wrath Of Academy
      What's tricky is that on the one hand he's graphing a single day's work, but on the other hand he alludes to it being an average day's work. (The problem is that if you did nothing but berry-picking every day you would quickly pick ever berry there is, and then there would be no more. Vice-versa if you did nothing but rabbit-hunting, you would hunt the local stock to extinction.)

      So you really have to think of it as the probable outcome of a single day's work for this one day. Ie, if we're going to toss a coin one time, only 0 or 1 heads or tails could happen, but you could still describe it fractionally as a .5 chance of heads and a .5 chance of tails. Likewise it's a probability of 4.5 rabbits today. But it's not really an average of 4.5 rabbits/day for the next year, because that might not be sustainable.

      (Sal sort of glossed over things to try to make it simpler, but using hunter-gathering as the example makes the reality a bit odd, IMO.)
      (13 votes)
  • starky seedling style avatar for user Syrex
    you could also just get someone to do it for you
    (10 votes)
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    • blobby green style avatar for user daniella
      The idea of getting someone else to do the gathering or hunting for you introduces specialization and trade into the model. In real economic systems, individuals or groups specialize in certain tasks and trade with others, potentially leading to an outcome where everyone can consume more than if they tried to do everything themselves. This could effectively shift the PPF outward, reflecting a higher level of productivity due to specialization.
      (1 vote)
  • piceratops seed style avatar for user Saif Ali
    what are some assumptions made by the ppf?
    (4 votes)
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  • piceratops ultimate style avatar for user jair.p90
    What things would take us to the "impossible Point" I know that a new technology( new technique of hunting) would put us outside of the PPF but what else would put us there?
    (5 votes)
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    • orange juice squid orange style avatar for user Owen Sechrist
      Keep in mind that the PPF has a time component to it, so to reach a point outside the PPF we have to have a change in the future that increases our possible production.

      One you already mentioned would be technology which increases the productivity of our existing resources.

      The other would be if our available resources actually increased, e.g.:
      A new worker shows up (increase in labor)
      Rabbits become more plentiful (increase in "land")
      We spend some time making a hunting weapon (investment that creates new capital)
      (4 votes)

Video transcript

Let's say you're some type of a hunter gatherer and you're trying to figure out how much of your time to spend hunting and how much of your time to spend gathering. So let's think about the different scenarios here and the tradeoffs that they involve. And just for simplicity we're going to assume that when you're talking about hunting, the only animal around you to hunt for are these little rabbits. And when we're talking about gathering, the only thing you can gather are some type of berries. That'll keep our conversation a little bit simpler. So let's think about all of the scenarios. So first, let's call this first scenario Scenario A. And let's say-- so let's call this the number of rabbits you can get and then let's call this the number of berries. Let's do this column as the number of berries that you can get. So if you were to spend your entire day going after rabbits, all your free time out-- making sure you have time to sleep, and get dressed, and all those type of things. Let's say that you can actually get five rabbits, on average, in a given day. But if you spend all your time getting rabbits you're not going to have any time to get berries. So you're going to be able to get 0 berries. Now let's say that you were to allocate a little bit more time to get berries and a little bit less time to get rabbits. So we'll call that Scenario B. We'll call scenario B the reality where you have enough time to get 4 rabbits on average. And when you do that, all of a sudden you're able to get 100 berries. And when we do these different scenarios, we're assuming that everything else is equal. You're not changing the amount of time you have either hunting or gathering. You're not changing the amount of sleep. You're not changing your techniques for hunting rabbits, or hunting berries, or you're not somehow looking to do other things with your time. So all other things are equal. And the general term for this, and it sounds very fancy if you were to say it in a conversation, is ceteris paribus. Which literally means-- so any time someone says, oh ceteris parabus, we assume this variable changes or whatever else-- they're saying we're assuming everything else is being held equal. So ceteris means all other things. You're probably familiar with et cetera. It's the same word, essentially. Other things in paribus, other things equal. So when you're going from Scenario A to Scenario B you're not changing the amount of time you're sleeping. You're not changing somehow the geography where you are in a dramatic way. You're not changing the tools you use or the technology. Everything else is equal. The only variable you're changing is how much time you allocate to finding rabbits versus finding berries. So let's do some more scenarios assuming ceteris paribus. So let me do Scenario C. You could, on average, have enough time to get 3 rabbits. But if you get 3 rabbits then all of a sudden you will to get-- or if you're only getting 3 rabbits, you're now able to get 180 berries. And let's do a couple more. I'm going to do two more scenarios. So let's say Scenario D, if you reduce the amount of time you spend getting rabbits so you get 2 rabbits, now all of a sudden you have enough time on average to get 240 berries. And then, let's say you spend even less time hunting for rabbits, on average. Then you have even more time for berries. And so you're able to get to 280 berries and I'll do one more scenario here. So let's say Scenario F-- and let's call these the scenarios. Scenarios A through F. So Scenario F is you spend all your time looking for berries. In which case, on average, you're going to be able to get 300 berries a day. But since you have no time for rabbits you aren't going to get any rabbits. So what I want to do is plot these. And on one axis I'll have the number of rabbits. And on the other axis I'll have the number of berries. So let me do it right over here. So this axis, I will call this my rabbit axis, rabbits. And we'll start. That will be 0. And then this will be 1, 2, 3, 4, and then that will be 5 rabbits. And then in this axis I will do the berries. So this right over here, let's make this 100 berries. This is 200 berries. And then this is 300 berries. And so this is my berries axis. Now let's plot these points, these different scenarios. So first we have Scenario A. Maybe I should've done all these colors in that Scenario A color. Scenario A, 5 rabbits, 0 berries. We are right over there. That is Scenario A. Scenario B, 4 rabbits, 100 berries. That's right over there. That's 100 berries. So that is Scenario B. Scenario C, 3 rabbits, 180 berries. 3 rabbits, 180. Let's see this would be 150. 180 will be like right over there. So 3, if you have time for 3 rabbits you have time for about 180 berries on average. So this is Scenario C. And then Scenario D we have in white. If you have time for 2 rabbits, you have time for 240 berries. So that is right around there. So this is Scenario D. Actually, a little bit lower. So this would be 250, so 240 is a little bit lower than that. So it'll be right over there. That is Scenario D. Scenario E, if you have time for 1 rabbit, you have time for 280 berries. So that gets us right about there. That is Scenario E. And then finally Scenario F. You are spending all of your time looking for berries. You have no time for rabbits. So all of your time for berries, no time for rabbits. 0 rabbits, 300 berries. That's right over there. So this is Scenario F. So what all of these points represent, these are all points-- now this is going to be a fancy word, but it's a very simple idea. These are all points on you, as a hunter gatherer, on your production possibilities frontier. Because if we draw a line-- I just arbitrarily picked these scenarios. Although I guess you could on average get 4 and 1/2 rabbits on average, on average get 3 and 1/2 rabbits, and then you'd have a different number of berries. So these are all points on the different combinations between the trade offs of rabbits and berries. So let me connect all of these. Let me connect them in a color that I haven't used it. So let me connect them. And do you see-- this should just be one curve. So I'll do it as a dotted line. It's easier for me to draw a dotted curve than a straight curve. So this right over here, this curve right over here, represents all the possible possibilities of combinations of rabbits and berries. I've only picked certain of them, but you could have a scenario right over here. Maybe we could call that Scenario G, where on average the amount of time you've allocated, on average you would get 4 and 1/2 rabbits. So some days you would get 4 rabbits and every other day you would get 5 rabbits, so maybe it averages out to 4 and 1/2 rabbits. And then maybe it looks like you would get about 50 berries in that situation. So all of these are possibilities. You don't have to just jump from 4 rabbits to 5 rabbits. Or maybe in this scenario you're spending 7 hours and in this scenario you spend 8 hours. But you could spend 7 hours and a minute, or 7 hours and a second. So anything in between is possible and all of those possibilities are on this curve. So these five scenarios, actually these six scenarios that we've talked about so far these are just scenarios on this curve. And that curve we call, once again-- fancy term, simple idea-- our production possibilities frontier. Because it shows all of the different possibilities we can do, we can get. 3 rabbits, and 180 berries. 2 rabbits and 240 berries. What we cannot do is something that's beyond this. So for example, we can't get a scenario like this. So this right over here would be impossible Let me scroll over to the right a little bit. Let me scroll, see my scrolling thing. OK, so this right over here is impossible, this point right over here where I'm getting 5 rabbits and 200 berries. If I'm getting five rabbits, I'm spending all my time on rabbits. I have no time for berries. Or another way to think about it, if I'm getting 200 berries I don't have enough time to get 5 rabbits. So this point is impossible. This point would be impossible. Any point that's on this side of the curve is impossible. Now any point that's on this side of the curve, you can kind of view it as inside the curve, or below the curve, or to the left of the curve-- all of these points right over here are possible. All of these points right over here are-- these points, for example, it is very easy for me to get 1 rabbit and 200 berries. So that right over there is possible. Now, is that optimal? No, because if I were to really work properly, I could get many more berries. Or I could get more rabbits. If I have 200 berries, I could get more rabbits. Or if I'm concerned, if I only want one rabbit, I can get more berries. So this is possible. All of the points down here are possible. But they aren't optimal. They are not efficient. So the points in here, we'll say that they are not efficient. Maybe somehow I'm not using my resources optimally to do this type of thing, when I'm over here. Or maybe I'm just not being optimally focused, or whatever it might be. If you're talking about a factory setting, when you're talking about maybe deciding to make one thing or another, then maybe you just aren't using the resources in an optimal way. Now all the points on the frontier-- these are efficient. You're doing the most you can do. Right now we're not making any judgment between whether any of these possibilities are better than any other possibility. All we are saying is that you are doing the most that you can do. Any of these things, you are making the most use of your time.