BobC YES. I'm guessing another fellow probabilist. 🙌

They are very closely related though. I mean statistics is basically applied probability. You use the tools developed in probability theory almost exclusively. And probability theory without statistics would be half as interesting, as you wouldn't have an application of it. But I guess mathematics is also closely related to physics and IT in that sense, so I see where you are coming from. I wonder though if that episode was understandable without already knowing about probability theory. The explanation of random variables for example was extremely short. I doubt anyone could understand random variables from that short comment.

Statistics is usually a tool for constructing a probability sample. Hail the dice!

In what sense is statistic the inverse of probability? That would imply that they cancel out in some sense. Which doesn't make any sense so it seems like you just threw words around. While statistics is heavily dependent on probability theory. You use the models and axioms of probability theory like Random variables, stochastic processes, etc. And you use the theorems of probability theory like the different central limit theorems, law of large numbers, Bayes, measurable mappings of independent random variables are still independent, etc. to base all your theorems of statistic on. Or you can justify using the central limit theorem that you assume something is normal distributed. Everything in statistics is based on probability theory. You could probably say statistics is to probability theory, what probability theory is to measure theory

KEine Ahnung Probability gives you information about future data/events based on a known underlying process. Statistics already has data/events from which an unknown underlying process can be discovered. That's why they're considered the inverse of each other since they start with what the other lacks and attempt to figure out what the other already has.

MineWarz imagine that, but going to math camps and competitions during the summer. that's me

So there are people who go to those math camps, interesting...

MineWarz well, they wouldn't exist if nobody went to them

relevancy 100

Guess who’s doing that 4 years later

+Daniel Flores You only look bald because the probability of a photon bouncing off your hair has probability 0.

You are bald because you only have finitely many hair follicles

Should have asked for a fat cantor set.

I should still have an infinitely uncountable number of hairs if i have the cantor set as a haircut

+Daniel Flores So the barber added hairs.

It is important to remember when applying any math to real world that it's just a concept, meaning it could easily be not compatible with what we see.

Egor Zvorykin Fair enough. Though I never claimed that Math could be successfully applied to everything (and if I did, it was unintentional), I totally agree that not all things can be abstracted in a mathematical sense. What I wanted to highlight, and apparently failed to do so, was that probability is not as fast in discarding intuition as other parts of math (for example, topology), and still maintaining the proper rigour in its proofs, leading to sometimes unexpected but yet interesting results. Then, that's only my personal opinion and perception.

Do you mean that the video is mirrored? The ring appears to be in her right hand.

Its hard to say. different images of her show that freckle on her neck on different sides. the ones that seem more professional, match up with the freckles location on the vid so i would tepidly assume the vid is mirrored.

Joshua Sherwin probably

More interesting, if she were to describe the constant variable.

Pascal's Wager has a lot of problems and there are many ways in which it is nonsense. One very obvious issue is that it doesn't account for the probability of the existence of other gods with other possibly contradictory conditions that you need to fulfill in order to earn the "reward" and in fact fulfilling one god's conditions may have earned you "punishment" by another one. Any one or even several out of the set of all gods that are imaginable may be the right one(s). The likelihood of picking the right one(s) and earning reward is zero since any finite number of gods has measure zero in the infinity of possibilities, but the likelihood of picking the wrong one and earning punishment is 100% since there is an infinity of wrong choices.

Dustin Rodriguez The only fundamental law on the universe is that change is the only constant, that means literaly anything can happen even if there is almost a zero chance.

@Juan Engazado I don't see what that has to do with what I said. If your system of determining truth permits fundamental logical paradoxes, things like "A is true. A is also not true." then you are incapable of determining the truth of literally anything. And in order to admit the possibility of an omnipotent being, you are required to accept those paradoxes, dismantling every single facet of understanding the world ever created. Neither formal systems of understanding nor intuitive systems based simply on a gut understanding of things can stand if you take away ALL ability to reason consistently as you must for an omnipotent entity to be able to exist. They must be able to create effects which have no cause. They must be able to do all of the things you allude to which do have zero chance of being possible. It is in their inherent nature. You don't have to believe they exist, but if you do its important to realize that it instantly becomes the only thing you can claim to believe. No other knowledge is possible in a universe where an omnipotent being exists.

Dustin Rodriguez Yeah i don't want to argue that much, however i find the implications of the classic problem of Godels (Second) Incompleteness theory is that or we may simply never know everything or our entire sets of rules of the universe cannot be proven with the rules of the universe itself which i don't agree so i stick with the first rule that if we will never know everything and something new is discovered every day for an infinite amount of time then everything that can happen or be discovered is possible so yeah its weird but existence itself is weird too so yeah i hope you understand me cause this topics are fun to discuss but i don't like really long discussions so take this as my last argument.

The probability is a number. As such, it either is zero or isn't, we're not dealing with sequences/series, so limits don't really enter the question. The "probability of hitting a specific point", i.e. "the (uniform) measure of the set consisting of only that point", IS zero, no ifs and buts about it. As for how that arises... I don't really have an answer. In a sense, it's because there are so many points on the board, uncountably infinitely many, to be specific. There are a few similar paradoxes that appear when you're dealing with discrete points and the continuum simultaneously.

Well, series aren't completely out of the question when it comes to probabilities, it just depends on the case. In this particular situation they don't really enter the picture... And yeah, I remember having to think about the inifities/zeroes arising from looking at single points on e.g. number lines and such before. [EDIT: I mean if the dart board was shaped more weirdly and you couldn't determine the area with simple geometry, that'd be one instance where calculus immediately enters the picture]

The area of the point is exactly zero. The reason for this comes about by how we define "area" (specifically, Lebesgue measure). We define the area of a square to be s^2 where s is the side length. Also, we create the following rule: If an object A is encapsulated by object B, then the area of A is less than the the area of B. From these two assumptions, the area of a point *must* be 0. If we assume that the point has a nonzero area, then we could make a square smaller than this area which encapsulates the point. Our only option is to assign the point zero area.

A probability of zero does not mean something cannot happen. That is not because our model is not perfect or anything, but rather due to the fact that measures do not care for events that are possible, but so rare that betting on them repeatedly would lose you all your money no matter how good the odds or how much of your money you were betting. There is a similar notion to "probability of hitting a point" that works for points, though: the *density* (or density function) of a distibution, which is in a way the "derivative" of a distribution, since you can get the probability of hitting any area (no matter the shape) by integrating the density of the distribution in question over the area you want to know about (if it has a density: like derivatives of functions, a density does not always exist for a given distribution). When Kelsey talks about modifying the area of the dart board in such a way that you can still get the probability of hitting an area by calculating the area on the modified dart board, she is taking a similar, but different approach to the mathematicians who came up with densities: Not every distribution is uniform, so in general, certain areas are "worth more probability" than others. Kelsey just made the area that was "worth more" bigger until it was as big in proportion to its probability as every other area. The usual way of tackling this same problem is by defining a density function, that gives every point a certain weight. The probability of hitting that point is still zero, but if you integrate over that point, it will be worth more than a point where the density is lower. For example: the density of a uniform distribution is a constant function (well, duh, it's uniform, so every point has the same weight) on the area that can be hit, and either zero or non-defined anywhere else. The density of any discrete distribution is the same function as its probability function (since you don't run into the problem densities are supposed to solve in a discrete sample space). The density of a standard normal distribution is the function x |-> e^(-x^2) (a little "bump" around zero that tapers off towards higher values). The nice thing about the density is: Actual samples might be random, but if you have enough independent samples, they will start forming clusters around the areas that have highest density.

Yeah, I'm familiar with probability density functions and the like, but the notion of zero probability not being equivalent to impossible sounds weird to me. I could almost recall being told the opposite, though running through the math in my head it does seem to be the case. [EDIT: Then again, I don't think my uni course in probabilities and statistics utilized measure theory, so some simplifications might have been employed. I did skim a book on bayesian probability theory in the library once and it ran the same concepts by the reader in a more rigorous, measure theoretical way but I can't remember a whole lot of it (maybe the initial introduction of probability as measure/line segment or whatever) because all the jargon made my head spin and I only had an hour or so to look at it...]

Kevin Kim Note: it doesn't mean it's *not* impossible either - actually impossible things also have 0 measure. When talking about 0-measure-but-possible things, it's common to say it "almost never" happens. Same with measure 1 things that aren't guaranteed - they "almost always" happen. These phrases have specific meanings when probabilists talk. 😀

I don't agree with this claim. Saying something has zero probability actually DOES imply it's impossible! It's easy to see there's some funny-business going on here. Simply add-up all the probabilities of hitting any point. If these are all zero then the total probability of hitting any point is zero. So it's impossible to hit any point on the board. (My answer to this conundrum is in another thread above).

That "add up all the probabilities" part is the funny business here, but it's well-defined mathematical funny business. How many, exactly, is "all"? There's an *infinite* number of points. If each point has a non-zero probability, then when you "add them all up", you get a value of infinity! But probabilities have to sum to 1, so clearly there's something wrong in what we stated before - either there's not an infinite number of points, or the probability isn't non-zero. We know the first is true (if the points aren't infinite, you can tell me how many there are, and list them out; but I can always find another point that you missed), so it must have been the second assumption that's false - the probability of each point is indeed zero. This is no more paradoxical than asking what the "density" of the integers are in the rationals - it's also zero, even tho integers definitely exist in the rationals. There's just infinitely more rationals. ^_^

>If each point has a non-zero probability, then when you "add them all up", you get a value of infinity! Not if it's "infinitesimal" probability.

"Infinitesimals" don't exist in the reals. If you're using a number system with infinitesimals, then yeah, you're right - the probability of hitting a point on the dartboard is an infinitesimal. In systems without those, tho, it's just 0, and the math still works out fine. (Because in real limits, ∞×0 is an undefined form; it can evaluate to any number, and you can't tell which it is from the expression. You have to do some transform to get at the value some other way. In this particular case, the expression evaluates to 1.)

I used to play XCOM.

The probability of hitting the board is 1, which is equal to the sum of all probabilities. If the probability of hitting an exact point is not zero, then the sum of all probabilities would become essentially infinitely large so it wouldn't work. See 3Blue1Brown's probability vids and his appearance on numberphile.

not a stupid question at all! In calculus, when you are taking a tiny element of length dx to integrate over, you take the limit as dx becomes infinitesimal. Contrast with this situation - a point can be APPROACHED by the limit of a vanishingly small element of area, but the point itself has 0 area, not an infinitesimal one. This next analogy might be wrong, but it's how I understand this: when integrating, you are "summing" COUNTABLY infinite length elements. With this dartboard, the area is a countable infinity of infinitesimal area elements, but it is an UNCOUNTABLE infinity of points. I hope this helps!!

@@ronshvartsman7630 Thanks man :) I'd just accepted it at this point but you bring up a nice way to think about it

Using units as a descriptor for a number is a good way to not lose the context of what the number was supposed to represent. Units can be used just like equations, in what is called "dimensional analysis". For consistency the units ought to match the equations. One result can be compared to the other as a way of "checking your work".

Bruh...

lmao Didnt expect this comment coz LIKE LITERALLY 5 SECONDS AGO IT HAPPENED LOUD

You should mention that this certain type is Sigma algebra

Haven't heard it either. People do call 3 dimensional objects squares, like a square of cardboard, but that seems to be just because they approximate 2 dimensional objects.

You have been responded!

That's part of the answer: en.wikipedia.org/wiki/Free_probability

Pascal's wager is logically flawed. It only works if there is only one possible god that can be imagined. But in fact quite the opposite is the case, there is an infinity of possible imaginable gods. So any probabilistic reasoning has to take all of them into account and many are mutually exclusive - what earns you reward with one may earn you punishment with another.

Linkmario Fan a lot of stats is in probability though.

+Francisco Roy De Mare You can't ignore the history of the scenario. If I ask you what the probability is that the top card in a 52 card standard deck is the 3 of clubs, the answer is obviously 1/52. But if I show you the bottom card in that deck and it is the 3 of clubs, then ask you what the probability is that the top card is the 3 of clubs, the probability is clearly 0. In both cases you have a 52 card deck, but the fact that the current state is the same in both situations is irrelevant. You have 2 doors, but those 2 doors took different paths to get where they are. The door you chose has a 1/3 chance of having the prize behind it. It had a 1/3 chance when you chose it and, as far as you know, nothing has happened to it or the prize since then. The 2 doors you didn't choose had a 2/3 chance of having the prize behind one of them. That too has not changed. The 2 doors you didn't choose still have a 2/3 chance of having the prize behind one of them. But, because you know for certain that the prize is not behind the door that was opened, the entire 2/3 chance of having the prize is with the other door.

Yes, I understand that. And probably a sample test (repeat this scenario 10000 times would confirm), but I still cant see the objective logical demostration. Your card example makes no sense, its like hes showing me that one the other doors has the price. Like I said, the revelead door is ALWAYS empty, its not random. So theres only 2 doors in the game, one with price and one without.

Its very counter intuitive, thats why the problem is famous (?) My problem is that if I was watching the show the previous day, my first choice of door is irrelevant, whatever I choose the winning door or a empty door, Im still picking between two at the end. So "Is it wise to change it?" makes no sense for me, 2 doors, 1 choice... maybe "Is it more likely you get the right door twice?" 3 doors, 2 choices.

Bayes theorem arises naturally (ot, to be more precise, it is a natural definition for the intuitive notion of a conditional probability). Assume you have a probability measure space X (meaning you defined a measure/"size" P for subsets of X and X has measure/probability 1, ergo P(x)=1) and a subset A of X. Then you natually also get a a new measure for subsets B of X by taking P(intersection of A and B). This new measure has one problem though: The new measure of X is no longer 1, but the smaller P(intersection of A and X)=P(A). To once again get a probability of 1 for X, you need to "normalize" the measure by the factor P(A). So in total the new measure then reads "new measure of B" is "P(intersection of A and B)/P(A)". This new measure is called the probability of B under the condition A. As a stochastic explanation: A and B are the events (as subsets of the set of all results). You know know that A already happened, so you only need to consider points in A and want to know the measure of points in B. So you take set of all the points who lie in both A and B the intersection). But because you want to model the fact that A already happened, A must have probability 1, so you need to normalize the whole thing

Raphael Schmidpeter Ah! Not only a prompt response but a clear one. Cheers!

How are you defining Planck area? You seem to treating Planck area as an object, rather than a unit of measure. If Planck area is a unit of measure, each dart lands in uncountably many circular disks each with a area of 1 Planck area.

Steve's Mathy Stuff, OK let me rephrase it. Probability of hitting any given point must be (Area of 1 Plank Area)/(Area of the dart board).

Why? If the probability that the dart will hit point A is (Area of 1 Plank Area)/(Area of the dart board), then hitting A must mean hitting the unique subset of the dartboard with area 1 Planck that contains A But there is no such subset. Uncountably many subsets of the dartboard have area 1 Planck and contain A. You could select a finite subset of all the mathematical points on the board and designate the disks centered on those points as physical points. (Mathematical points in overlapping disks can be assigned to one or the other somehow.) If you chose wisely, the finite set of k disks covers the board and the probability of hitting a point could be said to be 1/k. k would always be larger than (Area of the dart board)/(Area of 1 Plank Area) due to overlap. There are uncountably many finite subsets of the set of points on the dartboard. For any of those, there is always one that makes the probability distribution more uniform. (That's based on my method of assigning mathematical points to physical ones in ambiguous cases. There might be an assignment method that does not skew the distribution.) Do we have any reason to believe that any one set is the right one?

My logic is when the dart is actually hitting any point within the Planck area circle around point A, it is also simultaneously hitting point A. Any measurement system will give same response for the events of dart hitting Point A & dart hitting some other point within the Planck area circle around Point A. So dart hitting any Point within the Planck area circle around point A should also be considered as hitting Point A.

Let r be the radius of a circle with an area equal to 1 Planck area. Suppose point B is hit by the dart. The dart is treated as if it hit point A, a point within r of B. But uncountably many points are within r of B. Which one is point A?

+You Tube Two points. First, many scientists and mathematicians held and hold absurd beliefs. Second, I think Pascal only said the loss was small in comparison to the possible gain. I think if Pascal had understood measure theory he might have reached a different conclusion. He assumed without proof that, in the absence of an afterlife, his lifespan had finite measure.

Well he's either laughing at you or doesn't care, you on the other hand look stupid in both cases. Scientists are just people, although science pretends to be an absolute truth it'll always be just a concept

that's because any finite number divided by any infinity is equal to zero. At first glance it might seem paradoxical until you realize we are talking about a freakin' infinity....

But you ought to remember that what you're calling "infinity" and "zero" in this case have a product equal to 1.

+Graham Henry, I agree. As I understand it, limit functions are needed to define "infinity" , and to define or evaluate "1/infinity". But this seems to get lost to the confusing vagaries of so called "Real Numbers". It's perhaps more clear to stay within a 2-Dimensional space based on areas, and then apply limits if necessary.

Physically there's a finite number of points with each atom on the surface of the board representing a point. So there's 1/# of atoms. And if you want to be practical and not as precise, just split the board into hundreds of equal parts and throw the dart. Now the probability is 1/# of equal parts, which is more useful

Quantum mechanics, which determines the behavior of the tiny particles that make up everything, is fundamentally probabilistic. Wave functions and particle interactions in quantum mechanics and quantum field theory are most accurately described as a set of probabilities, and are capable of describing nature more accurately than classical physics. And although the randomness diminishes as the scale gets bigger, it's still there. In other words, there is a 99.99999999999999999999999999999999999999999999999999999999999999999999999999999% (perhaps even higher) chance that the dart will land in the spot predicted by factoring in every aspect of the air around it, the way it was thrown, the mass distribution of the dart, and the gravity of every last particle around the dart, but you cannot say with complete absolute certainty that it will land in the spot you think it will. Also, Heisenberg's uncertainty principle says that you cannot know the position or the momentum of a particle with exact certainty, and the more accurately you know its momentum the less accurately you can know its position. These effects diminish at larger scales because the relation between these uncertainties only becomes relevant at the atomic scale. So probability isn't real in an absolute sense when dealing with classical physics, which is mostly relevant on the scale of darts and scoreboards, but in the complete picture of the fundamental workings of the universe, probability is "real" in the sense that you are talking about as there are things that can only be described (or are most accurately described) as probabilities.

yes that happened to me

No the radius of the point is zero not just infinitely small. Remember you're hitting at an exact point so the radius has to be zero