Are entanglement correlations truly random?

In summary: And yes, there could be regions of varying sizes within the universe in which there "less-than-maximum" entanglement between member particles. I would guess them as being small, although I guess there is no specific way to check that. If the member particles within the hypothetical region follow some kind of monogamy rule whereby they are only entangled with each other, then they would be considered to be maximally entangled.
  • #71
entropy1 said:
P(X=1) in the binary case is the ratio of the #bits equal to 1 relative to the total #samples.
P(A=1,B=1) is the ratio of pairs of bits that are both 1 compared to the total #samples (pairs).

Ok. But "pairs of bits" here means (or should mean--if you are defining it differently, you are doing it wrong) "pairs of bits measured in the same run of the experiment". So these probabilities, to be meaningful, require a certain way of "lining up" the two bit sequences next to each other: bits 0 and 0, bits 1 and 1, bits 2 and 2, etc., of each sample. Otherwise you are making meaningless comparisons; there is no physical meaning to comparing bit 0 from one sample and bit 1 of the other, because they are from different runs of the experiment.

Similarly, if you pick only the "1" bits out of each sample and match them up with each other, you are making a meaningless comparison.

entropy1 said:
I ment it as example of a non-random cause.

How you meant it doesn't change the fact that it's meaningless. See above.

entropy1 said:
You can claim that the entropy of the random content decreases in fractional bits

I have said no such thing. You are confused.

What I said was that if you have a pair of bits that are correlated, the entropy of that pair of bits, as a system, will be less than the entropy of two random uncorrelated bits; and if the correlation is only partial, the entropy of the two-bit system will not be an integral number of bits. But that doesn't mean we made the correlated pair of bits out of the two random uncorrelated bits and thereby decreased their entropy.
 
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  • #72
PeterDonis said:
Ok. But "pairs of bits" here means (or should mean--if you are defining it differently, you are doing it wrong) "pairs of bits measured in the same run of the experiment". So these probabilities, to be meaningful, require a certain way of "lining up" the two bit sequences next to each other: bits 0 and 0, bits 1 and 1, bits 2 and 2, etc., of each sample. Otherwise you are making meaningless comparisons; there is no physical meaning to comparing bit 0 from one sample and bit 1 of the other, because they are from different runs of the experiment.

Similarly, if you pick only the "1" bits out of each sample and match them up with each other, you are making a meaningless comparison.
If a random string x0..xn-1 is random, then the string x1..xn-1x0 is random too, right? So, what I meant to illustrate is that, since rotating a string does not change its randomness, finding a (strong) correlation with another random string could deny its total randomness.

I understand that in an experimental setting the correlation is linked to the physical setup, which has restrictions to its operation. That is what I mean by 'non-random elements'.

My approach may be seen more theoretical, abstract, for which I hold the reasoning valid (not inflating it needlessly :biggrin: ).
PeterDonis said:
What I said was that if you have a pair of bits that are correlated, the entropy of that pair of bits, as a system, will be less than the entropy of two random uncorrelated bits; and if the correlation is only partial, the entropy of the two-bit system will not be an integral number of bits. But that doesn't mean we made the correlated pair of bits out of the two random uncorrelated bits and thereby decreased their entropy.
AFAICS I agree. :biggrin:
 
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  • #73
entropy1 said:
If a random string x0..xn-1 is random, then the string x1..xn-1x0 is random too, right?

It is true that P(A) and P(B) are unchanged by reordering the string. That's obvious, because those probabilities only depend on the total numbers of 0 or 1 bits, not on their order. However, just knowing P(A) and P(B), by itself, does not tell you whether a string is "random". In fact, you have not given, anywhere in this thread that I can see, a definition of what you mean by "random".

Also, if we have two strings, and we reorder only one of them, that will, in general, change P(A, B), since that probability relies on comparing corresponding bits of each string. But only one such comparison is actually meaningful: the one that compares bits from each string that came from the same run of the experiment. Any other comparison is meaningless.

entropy1 said:
I understand that in an experimental setting the correlation is linked to the physical setup, which has restrictions to its operation. That is what I mean by 'non-random elements'.

What "restrictions to its operation" are you talking about? And why do you think such restrictions would be appropriately called "non-random elements"? (Note that this depends on what you mean by "random", which, as I noted above, you have not specified.)
 
  • #74
By random I mean that, in the binary case, the limit of l to ∞ of the probability of getting a fragment of n identical bits in a random string of length l is ##(\frac{1}{2})^{n-1}##. There are probably standard deviations one could run on this. My own knowledge of mathematics is too limited for that.
PeterDonis said:
What "restrictions to its operation" are you talking about? And why do you think such restrictions would be appropriately called "non-random elements"?
This is probably an example of my limited knowledge of English. Maybe "operating conditions" is a better term?
PeterDonis said:
But only one such comparison is actually meaningful: the one that compares bits from each string that came from the same run of the experiment. Any other comparison is meaningless.
Good point. But on what grounds would you call the results 'random'?
 
  • #75
entropy1 said:
P(X=1) in the binary case is the ratio of the #bits equal to 1 relative to the total #samples.
P(A=1,B=1) is the ratio of pairs of bits that are both 1 compared to the total #samples (pairs).

P(A=1,B=1)=P(A=1|B=1)P(B=1), where P(A=1|B=1)=1 in case of total correlation. That is: P(A=1,B=1)=P(A=1)=P(B=1).

@Mentz114: It could be my limited mastering of the english language, but, with all due respect, I am afraid I don't understand what you mean.

Yes. I ment it as example of a non-random cause.

You can claim that the entropy of the random content decreases in fractional bits, but that could also mean that the amount of randomness decreases in favor of non-randomness.
There are many criteria one can use to define the randomness of bit string. The most important is that P(1)=P(0)= 1/2. There is also the auto-correlation which measures how many times a 1 is followed by a 1, and a 0 is followed by a 0. The formula is the same as the correlation between two strings and also has expectation 0.

I have to say that I don't follow what point you are trying to make so I'll leave it there.
 
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  • #76
Mentz114 said:
I have to say that I don't follow what point you are trying to make so I'll leave it there.
To put it simply: I am asking if the sources of a correlation are 100% random.

You are more than welcome to participate, which I would like, however, I respect any decision you make thereabout.
 
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  • #77
PeterDonis said:
Similarly, if you pick only the "1" bits out of each sample and match them up with each other, you are making a meaningless comparison.

How you meant it doesn't change the fact that it's meaningless. See above.
What I mean is that the experiment(al setup) is the "cherrypicker" in this case, in my consideration.
 
  • #78
entropy1 said:
To put it simply: I am asking if the sources of a correlation are 100% random.

You are more than welcome to participate, which I would like, however, I respect any decision you make thereabout.
I assume you mean 'deviate from randomness. This big topic is part of standard statistical theory and the Wiki articles are a good introduction.
https://en.wikipedia.org/wiki/Statistical_randomness
and this is useful and mentions higher concepts like spectral decompositions and Hadamard transformations.
https://en.wikipedia.org/wiki/Randomness_tests

This is not part of quantum theory. Correlations in QT play a different but very important role.
 
  • #79
entropy1 said:
By random I mean that, in the binary case, the limit of l to ∞ of the probability of getting a fragment of n identical bits in a random string of length l is ##(\frac{1}{2})^{n-1}##.

Where are you getting this definition of "random" from?

entropy1 said:
I am asking if the sources of a correlation are 100% random.

Obviously it depends on the sources.

entropy1 said:
What I mean is that the experiment(al setup) is the "cherrypicker" in this case, in my consideration.

The experimental setup certainly tells you what comparison between two bit strings is meaningful. But you seemed to be saying that any such comparison was meaningful, because you were talking about rearranging how the two bit strings are compared with each other (by, for example, shifting one bit string relative to the other and then comparing). If you do that, you aren't doing what the experimental setup tells you to do; you're doing something different, and meaningless. That's what I meant by cherry-picking the data.
 
  • #80
entropy1 said:
This is probably an example of my limited knowledge of English.

I think the entire topic of this thread might be an artifact of your limited knowledge of English. That's why I keep asking what you mean by the word "random"; I don't think you mean what that word usually means in English.

Perhaps it would help to ask the question a different way: why do you care whether "the sources of a correlation are 100% random"? What would it tell you if the answer was yes? What would it tell you if the answer was no?
 
  • #81
PeterDonis said:
Where are you getting this definition of "random" from?
From the data of my computer code :biggrin:
PeterDonis said:
The experimental setup certainly tells you what comparison between two bit strings is meaningful. But you seemed to be saying that any such comparison was meaningful, because you were talking about rearranging how the two bit strings are compared with each other (by, for example, shifting one bit string relative to the other and then comparing). If you do that, you aren't doing what the experimental setup tells you to do; you're doing something different, and meaningless. That's what I meant by cherry-picking the data.
Well, I can reassure you that was not my angle of approach. The cherry-picking part I introduced to illustrate how improbable it is to get a correlation out of pure randomness.
PeterDonis said:
I think the entire topic of this thread might be an artifact of your limited knowledge of English. That's why I keep asking what you mean by the word "random"; I don't think you mean what that word usually means in English.
That's not entirely fair - I think it is a matter of starting point.
 
  • #82
entropy1 said:
how improbable it is to get a correlation out of pure randomness.

But you still haven't really explained what you mean by this.
 
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  • #83
PeterDonis said:
But you still haven't really explained what you mean by this.
Well, I am afraid I can't do better than this currently. I will ponder some more.
 
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  • #84
entropy1 said:
Well, I am afraid I can't do better than this currently. I will ponder some more.
You should stsrt by finding out the customary meanings of randomness and also how to calculate a correlation.
 
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  • #85
entropy1 said:
Suppose we have two truly random sources A and B that generate bits ('0' or '1') synchronously. If we measure the correlation between the respective bits generated, we find a random, ie no, correlation.

Now suppose A and B are two detectors that register polarization-entangled photons passing respective polarization filters. We can define bits as 'detection'='1' and 'no detection'='0'. A and B individually yield random results. However, there is in almost every case a non-zero correlation, depending on the angle of the filters.

So my question would then be: since the detections of the entangled particles often exhibit a different correlation than truly random sources, are the detections purely random in case of entanglement? (or do they only seem random?)
A major problem in getting your question answered is that your terminology is sloppy, in fact truly sloppy.
Demystifier said:
Define "truly random"!
PeterDonis said:
Where are you getting this definition of "random" from?
You failed to make a definition. The terms "random" and "truly random" are neither used nor defined in probability texts. And after reading more of your posts it is not clear to me what you mean.

Let me give a simple concrete QM example:
Given an entangled pair from state √½(|00⟩ + |11⟩), we let A measure one of the pair at angle 0º, i.e. with measurement operator/observable ##Z =\begin{pmatrix}1&0\\0&-1 \end {pmatrix}##.
We let B measure the other at 30°, i.e. with observable ##½Z + √¾X =\begin{pmatrix}½&√¾\\√¾&-½\end{pmatrix}##.

The joint probability density of (A,B) is (1,1) with prob ⅜, (1,-1) with prob ⅛, (-1,1) with prob ⅛, (-1,-1) with prob ⅜. (1 & -1 are eigenvalues of the observables)
We see A and B agree with prob = ¾ = cos²30º, as usual.
The correlation coefficient is ½.
The marginal density of A is 1 with prob ½, -1 with prob ½. Same for B. A and B are not independent.

All of this is justified by repeated trials in the lab.

Can you ask your question from the above formulation?
 
  • #86
Zafa Pi said:
Can you ask your question from the above formulation?
I thought I remembered the basics, but this morning my meds demand my brain, so I would have to look it up.
 
  • #87
Zafa Pi said:
You failed to make a definition. The terms "random" and "truly random" are neither used nor defined in probability texts.
If the term is not defined in scientific literature, then why are you asking me, a layman, to define it? By the way, I gave one:
entropy1 said:
By random I mean that, in the binary case, the limit of l to ∞ of the probability of getting a fragment of n identical bits in a random string of length l is ##(\frac{1}{2})^{n-1}##. There are probably standard deviations one could run on this. My own knowledge of mathematics is too limited for that.
Anyway, I will think about what I mean by 'truly' random.
 
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  • #88
entropy1 said:
If the term is not defined in scientific literature, then why are you asking me, a layman, to define it?

Because you used it. We need to know what you meant by it.
 
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  • #89
entropy1 said:
By random I mean that, in the binary case, the limit of l to ∞ of the probability of getting a fragment of n identical bits in a random string of length l is (12)n−1(12)n−1(\frac{1}{2})^{n-1}. There are probably standard deviations one could run on this. My own knowledge of mathematics is too limited for that.
I don't know what you mean by fragment. Do you have a link?
If a1,a2, ... ,al with l=20 is a binary sequence, what is a fragment of 10 bits? Is it a subset of size 10? Is it a contiguous subset like a7,a8, ... ,a16? Or what?
 
  • #90
entropy1 said:
By random I mean that, in the binary case, the limit of l to ∞ of the probability of getting a fragment of n identical bits in a random string of length l is (12)n−1(12)n−1(\frac{1}{2})^{n-1}. There are probably standard deviations one could run on this. My own knowledge of mathematics is too limited for that.
I now think you were trying to define a binary normal sequence, but failed.

"A sequence of bits is random if there exists no Program shorter than it which can produce the same sequence." ~ Kolmogorov
So obviously it is impossible to exhibit a Kolmogorov random sequence.

Neither normality or K-random imply one another. But all of this should be in the Probability section of PF. And none of this is relevant to QM.
 
  • #91
Suppose I walk down the street, and each time I look to my right, a red car is passing. If I don't look, I don't know which color the passing cars have.

So the correlation between me looking and a red car passing is 100%.

So I assume the moments I look are random (A) and the cars passing have FAPP random colors (B).

So, in this case, with the correlation manifesting, are (A) and (B) "truly" random?

Since we generally do not see correlations like this always and everywhere, it should be, however not impossible, improbable to see this. So, I cannot determine whether there is a red car convention in town or not, since I don't know the counterfactual measurements (looking). So, would a string of red cars passing me still be random? After all it would require a red car convention. And if there is NO red car convention, would the string of cars passing still be truly random if the correlation with my looking direction would be 100% red cars? (Or, for that matter, would my peeking be random?)

The problem I see, is that if (A) and (B) are truly random, the measurements should be typical for what is reality. For example, based on my perceptions, I might say that in this street probably only red cars are allowed, while the counterfactual data is in contradiction with that.

You could also see it the other way round: I see typical cars passing, while when I'm not looking only red cars pass which I wouldn't know of. My assessment of the data might lead me to faulty conclusions.

So I think "randomness" is required to accurately assess reality.
 
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  • #92
entropy1 said:
Suppose I walk down the street, and each time I look to my right, a red car is passing. If I don't look, I don't know which color the passing cars have.

So the correlation between me looking and a red car passing is 100%.

So I assume the moments I look are random (A) and the cars passing have FAPP random colors (B).

So, in this case, with the correlation manifesting, are (A) and (B) "truly" random?

There was a different thread in the "Set Theory, Logic, Probability and Statistics" forum on this topic. Random is relative to a model or theory. You can't know whether something is "truly" random unless you know what theory is correct. Which, of course, you can never know.

According to QM, the results of certain types of measurements are random, in the sense that QM doesn't propose any means of determining the values ahead of time. According to a different theory (maybe Bohmian mechanics), the results may not be random.

The facts you describe above is consistent with multiple explanations:
  1. All the cars are red.
  2. There are cars of other colors, but for whatever reason, you only have an impulse to look at a car when the car is red.
  3. There are cars of other colors, but just by coincidence, you happened to look at the moments a red car is passing.
  4. Etc.
 
  • #93
bahamagreen said:
I flip a coin and it lands heads. Does it still make sense to describe the probability of a heads for that flip as p=.5, ten minutes after the fact? Does probability even exist for events in the past?

Both of these thoughts goes to a time relationship of randomness... does the standard treatment not take time into account?

The standard mathematical treatment of probability (which uses measure theory) says nothing about events actually happening. It doesn't have any axioms that say you can take random samples. It does not have a model of time as that notion is used in physics. So the standard mathematical theory does not deal with questions about a probability "before" or "after" some time or a probability that changes with the "actual" occurance of an event.

The standard techniques for applying probability theory to real life problems do assume that it is possible to take random samples and that events actually happen (or don't happen). In applications of probability theory the indexing set used in the abstract definition of "stochastic process" is often interpreted to be time in the physical sense.

The distinction between mathematical probability theory and interpretations that people make when applying it is blurred by the fact that only the most advanced texts on mathematical probability theory confine themselves to discussing that theory. The typical textbook on probability theory tries to be helpful by teaching both probability theory and its useful applications. For example, the "conditional probability" P(A|B) has a very abstract mathematical definition. However, typical textbooks present P(A}B) by interpreting it to mean "The probability of event A given that the event B has (actually) happened".

In mathematical probability theory, a specific sequence of numbers can be assigned a probability and it can be a member of a "sample space" on which a probability measure is defined. But there is no definition for a particular sequence of numbers being "random" or "not random". In mathematical probability theory, there is a definition for two random variables to be correlated However there is no definition for two specific sequences of numbers to be correlated. In this thread, there is the usual confusion involving numerical calculations done on specific sets of numbers to estimate mathematical correlation versus the mathematical definition of correlation.

Attempts have been made to create mathematical notions of randomness for specific sequences of numbers. These attempts are not "standard" mathematical probability theory.

When discussing physics, people are making their own interpretations of mathematical probability theory.
 
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<h2>1. What is entanglement?</h2><p>Entanglement is a phenomenon in quantum mechanics where two or more particles become connected in such a way that the state of one particle is dependent on the state of the other, regardless of the distance between them. This means that measuring the state of one particle will immediately affect the state of the other particle, even if they are separated by large distances.</p><h2>2. What are entanglement correlations?</h2><p>Entanglement correlations are the relationships between the states of entangled particles. These correlations are observed when the state of one particle is measured and it is found to be directly related to the state of the other particle, even though they may be separated by a large distance. These correlations are often described as being "spooky" or "non-local" because they seem to defy our classical understanding of cause and effect.</p><h2>3. Are entanglement correlations truly random?</h2><p>The answer to this question is still a topic of debate among scientists. Some argue that entanglement correlations are truly random, meaning that there is no underlying cause or hidden variables that determine the outcome of measurements on entangled particles. Others argue that there may be hidden variables at play, but they are currently unobservable due to limitations in our technology and understanding of quantum mechanics.</p><h2>4. How do we know that entanglement correlations are not just a coincidence?</h2><p>Scientists have conducted numerous experiments to test the validity of entanglement correlations. These experiments have consistently shown that the correlations between entangled particles are not due to coincidence, as the measurements on one particle are found to be directly related to the measurements on the other particle. Additionally, the strength of these correlations has been found to be much stronger than what would be expected by chance.</p><h2>5. What are the potential applications of entanglement correlations?</h2><p>Entanglement correlations have the potential to be used in various applications, such as quantum computing, secure communication, and quantum cryptography. By harnessing the properties of entanglement, scientists hope to develop technologies that are faster, more secure, and more powerful than current classical systems. However, further research and advancements in our understanding of entanglement are needed before these applications can become a reality.</p>

1. What is entanglement?

Entanglement is a phenomenon in quantum mechanics where two or more particles become connected in such a way that the state of one particle is dependent on the state of the other, regardless of the distance between them. This means that measuring the state of one particle will immediately affect the state of the other particle, even if they are separated by large distances.

2. What are entanglement correlations?

Entanglement correlations are the relationships between the states of entangled particles. These correlations are observed when the state of one particle is measured and it is found to be directly related to the state of the other particle, even though they may be separated by a large distance. These correlations are often described as being "spooky" or "non-local" because they seem to defy our classical understanding of cause and effect.

3. Are entanglement correlations truly random?

The answer to this question is still a topic of debate among scientists. Some argue that entanglement correlations are truly random, meaning that there is no underlying cause or hidden variables that determine the outcome of measurements on entangled particles. Others argue that there may be hidden variables at play, but they are currently unobservable due to limitations in our technology and understanding of quantum mechanics.

4. How do we know that entanglement correlations are not just a coincidence?

Scientists have conducted numerous experiments to test the validity of entanglement correlations. These experiments have consistently shown that the correlations between entangled particles are not due to coincidence, as the measurements on one particle are found to be directly related to the measurements on the other particle. Additionally, the strength of these correlations has been found to be much stronger than what would be expected by chance.

5. What are the potential applications of entanglement correlations?

Entanglement correlations have the potential to be used in various applications, such as quantum computing, secure communication, and quantum cryptography. By harnessing the properties of entanglement, scientists hope to develop technologies that are faster, more secure, and more powerful than current classical systems. However, further research and advancements in our understanding of entanglement are needed before these applications can become a reality.

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