Let me see if I can add some clarity to all this...
There is no clarity in all this. Monty Hall discussions will go on until the heat death of the universe.
Proposition #4
Monty offers you the choice of two doors. One has a car behind it, the other has a goat. One door was chosen by you ealier. You can keep "your door" or just as easily change to the other. What is the odds of getting the "car"?
I submit that proposition #3 has no bearing on proposition #4.
This is the fundamental error. Monty's actions depend on yours. Unlike the coin toss, it is not an independent action, but is completely deterministic.
In probability terms, let A = you chose a car on your first trial
~A = you chose a goat
Let B = Monty chooses a car after his actions,
~B = Monty's door is a goat
If your actions and Monty's are independent, then P(B|A) = P(B).
That is, the probability that Monty chooses a goat is independent of what you do. But that's not true.
In fact, the true model is:
P(B|A) = 0
P(B|~A) = 1
If you chose a goat, Monty's door is a car. P(B|~A) = 1.
If you chose a car, Monty's door is a goat. P(B|A) = 0.
Now the question we want to know is, what is P(B)? When all the actions are over, what is the probability that Monty's door holds a car?
P(B) = P(B|A) P(A) + P(B|~A) P(~A)
= 0 * (1/3) + 1 * (2/3)
= 2/3.
They are different choices. The fact that you picked a door earlier has no relevance to proposition #4. It's exactly the same as coin flips that happened prior to proposition #2.
Absolutely untrue. The doors Monty is offering you depend on what you chose the first time. Hence the conditional probabilities are different than the unconditioned probability.
All that's important is:
A> There are two choices
B> You are equally able to choose either
C> One choice is victory and the other defeat
Nope. And it's because Monty's actions are conditioned on yours.
Here are the two possibilities for that fateful 2nd choice, before we open the two remaining doors:
Door 1 2
Goat Car
Car Goat
Now, you are saying that Monty has arranged things so that these are equally likely outcomes. But they aren't. If Door 1 is your original
choice and Door 2 is the one Monty offers after opening the rest, then the probability that the arrangement is (Goat, Car) is (N-1)/N where N = the number of original doors. The probability that the final arrangement is (Goat,Car) is exactly the probability that the first choice was Goat.
The first coin flip was NOT a fair coin. You were NOT equally able to choose Goat or Car on the first choice, and so you aren't equally likely to be based with (Goat, Car) and (Car, Goat) after Monty's move.
If Monty had you choose "your" door after he opened all but 2, then we'd be faced with a 50/50 choice. Then we'd have P(A) = P(B) = 1/2. But that's not the situation. P(A) is not 1/2, it's 1/N.
Many people here seem intent on adding bigger numbers, as if that changes anything. It does not. If there are a BILLION doors and I pick one, and only one is a winner, then my odds are one in a billion.
Precisely.
However if God comes by and eliminates all but two choices, one of which is the winner, and I can choose either... it's back to one in two. The prior one in a billion choice has no bearing on the subsequent one in two choice.
Also correct. However, if God lets you choose first, so that there is only a 1 in a bililion chance you've got the car, then there is a 999,999,999 in a billion chance that God's door is the car. Those outcomes are all the ones in which you didn't pick the car first.
I hope that this helps.... 
It helped me sort out the thinking of the 50-percenters.
