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mad-scientist and computer programmer looking for something more interesting than most people accept as their future
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    But not like 1 negative and 1 positive.... all splits on a bell curve, which should match to what is called a "particle and antiparticle" because both of those are subject to heisenberg uncertainty which really means they were split on a bell curve instead of +1 and -1.

    In the double slit experiment, when its not observed, wave interference occurs with 1 particle with itself. The particle hits on the back wall where the 2 waves are in phase, and does not hit when they are out of phase. This is the gradual version of the EQUAL function, which is the opposite of the XOR function.

    In the double slit experiment, when it is observed, it still goes both paths (and many variations of those on bell curves), and wave interference still happens. How can I say that when no wave interference is observed? Its very simple. The 2 paths do not end in the same place if you observe which path it took. One is a future "left slit, detector on right not detected", and the other future is "right slit, detector on the right detected". These 2 do not converge on the same state of the universe, which is a bell curve between "left slit, detector on the right detected" and "right slit, detector on the right detected", or the opposite of that when not detected.

    The same thing is happening in the double slit experiment if its observed or not. What changes is we twist our possible futures to not overlap eachother anymore, so we are unable to see the wave interference even though it still happens. It is not wave interference between the 2 paths of the photon. It is wave interference between the total state of the universe and whatever paths it takes. Putting a detector at one slit is the same as putting a mirror there to reflect it away from the back wall and toward a back wall in a parallel reality. It twists that possible future to one that does not align with the left slit, so the wave interference is not observed even though its somewhere in the possible states of the universe.

    Every moment of reality (including its light cones) is a possible state of the universe. When we go through one slit or the other, and hit on a place where the 2 waves are out of phase, that is never observed because our reality is cancelled out by an opposite reality (the one that is out of phase). Reality ends. But since we are everywhere and everything all at once (without knowledge of this usually), we continue from all other points in the universe as if nothing had happened, wondering why we don't observe the photon hitting in the dark parts of the back wall of the double slit experiment. It hits there, and its antireality hits there too, but our past shows that never happens because our past is defined by the paths where reality doesn't get cancelled out.

    I have simultaneously solved wave/particle duality and consciousness.

    Can anyone who knows physics give me any evidence that this theory is not true?
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    Logically it makes sense why they act like particles when observed and waves when not observed. Quantum physics is common sense to anyone who understands the statistics of 2 coin flips and how those statistics are affected by observing the coins. I will explain why the double-slit experiment is the same experiment as something you can do with 2 coins.



    In the double-slit experiment, an electron (or other particle/wave) has 2 holes it can go through and then is detected hitting somewhere on the back wall. If it goes through the left hole, statistically it will paint a pattern on the back wall. If it goes through the right hole, it paints a different pattern. It goes through each hole equally often as the other. Most peoples' common sense tells them that statistically it doesnt matter if you know which hole it went through because you can simply average the 2 patterns to get the pattern on the back wall for when it could go through either hole. But its a very different pattern from the average of the left-hole-pattern and right-hole-pattern. Its the same pattern as waves interfering with each other.

    Sometimes electrons act like particles and sometimes like waves, but why? I'm going to explain why that happens using common sense instead of equations. The problem is most people don't have all the parts of common sense that they think they have. If you understand the following about 2 coin flips, and you see the patterns created in the double-slit experiments, then you can put them together and understand why electrons (and other particles/waves) sometimes act like particles and sometimes act like waves. Logically, without considering the specific equations of physics, we can know there has to be something like that in physics somewhere. Here's the 2 coin question:

    If I flipped 2 coins and at least 1 coin landed heads, then whats the chance both landed heads?

    Its 1/3, not 1/4 or 1/2 like most people think, because there are 4 ways 2 coins can land and I only excluded "both tails" when I said "at least 1 coin landed heads" so that leaves 3 possibilities and I asked what is the chance of 1 of those 3 things which happen equally often. Its 1/3. If you still don't believe it, flip 2 coins many times and only ask the question when at least 1 of them lands heads and you will see that 1/3 of the time you ask the question they both land heads. The flaw in Human minds is the need to choose 1 of the coins and say it certainly landed heads, but I did not tell you any specific coin landed heads, and it does change the answer if you take that shortcut.

    Most peoples' common sense tells them that since its a symmetric question (between the 2 coins), it can't matter if they start with 1 of the 1-or-2 coins that landed heads, and they think it will get the same answer as not knowing if a specific coin is heads or not. How could it matter? We know at least 1 of the 2 coins landed heads, so I'll just define a variable called coinX=heads and figure out if coinY=heads or coinY=tails. Since coinY was randomly flipped and coins have a 1/2 chance of heads, then the chance both are heads must be 1/2. But then they think about the extra information I told them: at least 1 coin landed heads. That has to change something, so how could coinY be 1/2 chance of heads by itself and with coinX? CoinX and coinY are symmetric. You can trade them in this question and not change the answer. So whatever is true of coinY has to also be true of coinX on average. So maybe the chance both are heads is 1/4. Most people go back and forth between 1/2 and 1/4, but the answer is 1/3 as I explained above.

    How is the 2-coin experiment related to the double-slit experiment?

    The patterns of the 2 coins (how often they land heads) individually can not always be averaged to get the pattern of both coins together. If at least 1 coin landed heads and you observe a specific coin being heads, then the chance they are both heads is 1/2. If at least 1 coin landed heads but you don't observe any coin, then the chance both are heads is 1/3.

    Logically, observing a specific case of something you know has to be true in general, about the 2 coins, produces a different outcome than only knowing its true in general.

    The analogy to quantum physics is that when you observe a heads or tails, you collapse the wavefunction (including the other coin you didn't observe) to a particle and the other becomes a different wavefunction, but if you do not observe any heads or tails then its a symmetric wavefunction between the 2 coins.

    I can say the same thing about the 2 holes in the double-slit experiment. If I put an electron detector past the left hole, and shoot an electron that could go through either hole, and the detector observes or does not observe an electron, then I get a different pattern (statistically on the back wall of where the electrons hit) than if the detector was not observing the space between the left hole and the back wall. If any part of the possible paths are observed (as containing or not containing an electron), then the other possible paths are affected even though they were not observed. The electron could have gone through both slits or neither or left or right, but still the path on the right is affected by observing the path on the left.

    Most quantum physics scientists explain it as the electron going through the left hole, the right hole, both holes simultaneously, or bouncing off the thing containing the 2 holes without going through either hole. If the electron does not go through either hole, they do not count that in any of the patterns on the back wall.

    In the 2-coin experiment and double-slit experiment, there are 4 possibilities, and 1 is excluded. I need to label the 2 coins for this, like the left and right holes/slits are labeled "left" and "right". One coin is a nickel and the other is a dime. This is not the only way to pair the 4 possibilities. Its just a way to explain that they are the same problem:

    (1) Nickel heads. Dime tails. Electron left slit. Electron not right slit.

    (2) Nickel tails. Dime heads. Electron not left slit. Electron right slit.

    (3) Both coins heads. Electron goes through both slits.

    (4) Both coins tails. Electron bounces off the thing containing the slits and does not go through either. It is not true that "at least 1 coin landed heads" so I don't ask the question or keep statistics of it. The electron didn't hit the back wall so its not part of the statistical patterns.

    In the design of both experiments (2-coin and double-slit), cases (3) and (4) are opposites and cases (1) and (2) are symmetric. Exactly 1 of (3) and (4) is not counted in the statistics, but the chance is equally balanced between (1) and (2). It works the same way if you swap the left and right slits or swap the nickel and dime or swap heads and tails or swap going through a slit with not going through a slit. Its practical to test it going through the slit but not practical to test it after it bounces because bouncing is an observation by the thing it bounced on.

    Quantum physics is a kind of statistics. So is the 2-coin experiment. In the double-slit experiment and the 2-coin experiment, observing any part changes the outcome statistically. I'm not saying the math of the double-slit experiment is exactly the math of a bayesian-network (which is the kind of statistics used for the 2-coin experiment), but I explained enough similarities that quantum physics scientists should take this seriously.

    The double-slit experiment is a variation of the 2-coin experiment that uses continuous angles instead of only heads/tails.

    That is why observing things changes the outcome and why electrons/photons/etc act like particles when observed and act like waves when not observed.

    If I flipped 2 coins and at least 1 coin landed heads, then whats the chance both landed heads? The most important thing to remember is the question is symmetric between the 2 coins, and you can know that 1 of the 2 coins will be heads, but observing either of those coins as heads changes the outcome, like observing what goes through either slit changes the outcome.

    Quantum physics is common sense to anyone who understands the statistics of 2 coin flips.


    There is something which is true about the coins, and there are 2 ways which it could be true, and each of those 2 ways is symmetric, but knowing which of those 2 ways it is changes the outcome.

    If I flipped 2 coins and at least 1 landed heads, then whats the chance both are heads? 1/3

    If I flipped 2 coins and at least 1 landed heads, and http://en.wikipedia.org/wiki/Axiom_of_choice  selects a coin and says its heads, then whats the chance both are heads? 1/3, because http://en.wikipedia.org/wiki/Axiom_of_choice  was used on 2 things which were identical and you have no way to tell them apart.

    If I flipped 2 coins and at least 1 landed heads, and the first coin that landed (or the coin that landed closest to my foot, or whatever) is heads, then whats the chance both are heads? 1/2, because a specific coin is heads and the other is independent.

    Your observation of something which you already know to be true (but not which of 2 symmetric ways for it to be true) changes the chances, and that is exactly what we see in the double-slit experiment.

    Sat, Feb 26, 2011  Permanent link
    Categories: Experiment, statistics, quantum, double slit, common sense, particle, wave
    Sent to project: Polytopia
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