Would this equal Pr( rolling 2 7's)/Pr(rolling 2 7's or rolling 6 even numbers)? Or could I approach the problem as follows:
1- (Pr(rolling 6 even numbers)+ Pr( rolling 5 even numbers, 7 and an even number)) ?
Would this equal Pr( rolling 2 7's)/Pr(rolling 2 7's or rolling 6 even numbers)? Or could I approach the problem as follows:
1- (Pr(rolling 6 even numbers)+ Pr( rolling 5 even numbers, 7 and an even number)) ?
On the assumption that your question means that you roll a pair of dice several times and stop when you have rolled either six even numbers or two sevens during the sequence, then neither of your answers are correct.
What you need to do is look at the probability of rolling a seven before an even number: this is $\dfrac{\frac{1}{6}}{\frac{1}{6}+\frac{1}{2}}=\dfrac{1}{4}$.
You can then work out the probabilities of getting to the position of $a$ sevens and $b$ even numbers without having previously stopped. You have
The answer is $\sum_{b=0}^5 \Pr(2,b)= \dfrac{4547}{8192} \approx 0.555.$
Here’s a slightly different way to look at it.
Odd rolls other than seven are meaningless and can be ignored. By the seventh meaningful roll you must have either two sevens or six even numbers. Thus, you get two sevens before you get six even numbers if and only if you get at least two sevens in the first seven rolls.
On each meaningful roll the probability of getting a seven is $\frac{\frac16}{\frac16+\frac12} = \frac14,$ so the probability of getting at most one seven in seven meaningful rolls is $\binom70\left(\frac34\right)^7 + \binom71\left(\frac14\right)\left(\frac34\right)^6 = \frac{3^7+7\cdot 3^6}{4^7} = \frac{10\cdot 3^6}{4^7} = \frac{3645}{8192}.$
The probability of getting at least two sevens in seven meaningful rolls is therefore $1 - \frac{3645}{8192} = \frac{4547}{8192}.$