Obviously, if the experiment is set up as a "pure" and precise system, the analytic value is biased towards initial conditions, ie the exactness will produce a contiueous and repetative result based on the very first recorded data.
If the coins are true, and the initial states of all coins being placed exactly as possible upon the levers, and they attain an exact height for the detector/camera, than all 100 coins will show the exact same face! there can be no random distribution, does this precision constitute "unfairness" ?
How much immprecision needs to be added to the experiment in order to attain a result that for all intensive purpose is deemed "random" but fair?
As an example, lets have 100 levers that have intermitent Heads-Tails-Heads-Tails... placed upon the levers at rest before they are all activated. Will this then produce 50 Heads 50 Tails? Even leaving the coins fall to the ground, at the instant they hit the ground, they should all have equal values, all coins that started from rest with Heads face up, should all end up recorded with the same resultant values.
The fact there is only two possible outcomes, can be replaced with geometric structures, say with different colour or numbered sides, for instance any cubic form?
"No toss is affected by the outcome of the previous tosses.", but if the setup is true and precise, then what falls first, or what is detected initially, will always follow, there can be no deviation from all coins obeying initial conditions, what ever law governs the first recorded data, if it remains true and constant, will impose the same effects upon all following recorded data.
If one could confirm that a single spin factor of say an Electron is "spin up", out of two possible states 'up or down', then one can always make the logical assumption that in entanglement experiment, the 2nd electron, split from the first, must be identical, spin up too!..The reason one assumes the "other" entangled electron is also "spin up", is based on the premise of the temr "EITHER" it cannot possibly be spin up down at two different locations?
A two spin state SINGLE Electron, will always be assigned one-or-the-other spin state. One can never detect a single electron, at TWO separate locations, with TWO opposite spin-states!
One can FIP make the statement that every single electron in existence, will follow identical spin states, EITHER up or down, simplified I defy anyone to present an argument against the following statement:If I detect an electron in a spin-up state, then at that very instant, all non-detected electrons in existence are also in the same identical state. Conversly if I detect an electron spin-down state, the at that same instance, all non-detected electrons have the same spin-state value.