You have done wonderful research and no doubt it looks like you spent a lot of time and I respect that. I think there is one thing we do have to take into consideration.
On August 18, 1913, at the casino in Monte Carlo, black came up a record twenty-six times in succession in roulette. There was a near-panicky rush to bet on red, beginning about the time black had come up a phenomenal fifteen times. In application of the maturity of chances doctrine the gambler's fallacy, players doubled and tripled their stakes, this doctrine leading them to believe after black came up the twentieth time that there was not a chance in a million of another repeat. In the end the unusual run enriched the Casino by some millions of francs.
Source: Darrell Huff & Irving Geis, How to Take a Chance (1959), pp. 28-29.
The Gambler's Fallacy is based on a failure to understand statistical independence, that is, two events are statistically independent when the occurrence of one has no statistical effect upon the occurrence of the other. Statistical independence is connected to the notion of randomness in the following way: what makes a sequence random is that its members are statistically independent of each other. For instance, a list of random numbers is such that one cannot predict better than chance any member of the list based upon a knowledge of the other list members.
To understand statistical independence, try the following experiment. Predict the next member of each of the two following sequences:
2, 3, 5, 7, 11, __
4, 6, 6, 1, 9, __
The first is the beginning of the sequence of prime numbers. The second is a random sequence gathered from the last digits of the first five numbers in a phone book. The first sequence is non-random, and predictable if one knows the way that it is generated. The second sequence is random and unpredictable—unless, of course, you look in the phone book, but that is not prediction, that is just looking at the sequence—because there is no underlying pattern to the sequence of last digits of telephone numbers in a phone book. The numbers in the second sequence are statistically independent of each other.
Many gambling games are based upon randomly-generated, statistically independent sequences, such as the series of numbers generated by a roulette wheel, or by throws of unloaded dice. A fair coin produces a random sequence of "heads" or "tails", that is, each flip of the coin is statistically independent of all the other flips. This is what is meant by saying that the coin is "fair", namely, that it is not biased in such a way as to produce a predictable sequence.
Consider the Example: If the roulette wheel at the Casino was fair, then the probability of the ball landing on black was a little less than one-half on any given turn of the wheel. Also, since the wheel is fair, the colors that come up are statistically independent of one another, thus no matter how many times the ball has fallen on black, the probability is still the same. If it were possible to predict one color from others, then the wheel would not be a good randomizer. Remember that neither a roulette wheel nor the ball has a memory.
Every gambling "system" is based on this fallacy, or its Sibling. Any gambler who thinks that he can record the results of a roulette wheel, or the throws at a craps table, or lotto numbers, and use this information to predict future outcomes is probably committing some form of the gambler's fallacy.
That is why it is important to set a stop loss and a win goal target. Playing the Labouchere system or any other system, has winning sessions and losing sessions because of this principal.