Below I've included data from a PEW research study. What is the method for combining probabilities to reach a composite for say: an 18 year old black male?

1Take a look at mathisfun. – abybaddi009 Feb 16 '18 at 5:46

Thanks so, for a 30yr black man it would be .95*.98*.98 = .91 probability? – Craig_VG Feb 16 '18 at 5:51

1Having "any cell phone"? Yes. – abybaddi009 Feb 16 '18 at 5:53

By that math, a 65+ year old white woman would only have a 75% chance of owning any cell phone... that doesn't seem to make sense when just a 65+ year old would still have a 85% chance, right? – Craig_VG Feb 16 '18 at 6:11

1@abybaddi009 I'm sorry, that's simply incorrect. The table shows P(cell phone  race), P(cell phone  age), P(cell phone  gender). The relation between those three factors and P(cell phone  race, age, gender) is more complicated than just multiplying them together, even when independence is assumed. I'll work on an answer about that. – Robert Dodier Feb 18 '18 at 5:40
As pointed out by Imran, one cannot deduce the answer from the limited data that are available. If you're willing to make a simplifying assumption, you can make progress. Note, however, that whether or not this assumption is valid can only be answered by getting more detailed data.
Here we go. OP is asking for P(cell phoneage, race, gender). By Bayes' rule, this is:
P(cell phoneage, race, gender)
= P(age, race, gender, cell phone) / P(age, race, gender)
= P(age, race, gendercell phone) P(cell phone) / P(age, race, gender)
The simplifying assumption is that age, race, and gender are independent given cell phone status. Again, whether this is valid can't be answered with the available data. Assuming that, we have:
P(age, race, gendercell phone)
= P(agecell phone) P(racecell phone) P(gendercell phone)
Now apply Bayes' rule to each term:
P(agecell phone) = P(cell phoneage) P(age) / P(cell phone)
P(racecell phone) = P(cell phonerace) P(race) / P(cell phone)
P(gendercell phone) = P(cell phonegender) P(gender) / P(cell phone)
At this point we have:
P(age, race, gender, cell phone)
= P(cell phoneage) P(cell phonerace) P(cell phonegender)
P(age) P(race) P(gender) / P(cell phone)^2
Let P1 = P(age, race, gender, cell phone) and P0 = P(age, race, gender, no cell phone). Then P(age, race, gender) = P1 + P0, and
P(cell phoneage, race, gender) = P1/(P1 + P0) = 1/(1 + P0/P1)
Now, happily, some terms cancel:
P0/P1 = foo/bar
with
foo = P(no cell phoneage) P(no cell phonerace) P(no cell phonegender) / P(no cell phone)^2
bar = P(cell phoneage) P(cell phonerace) P(cell phonegender) / P(cell phone)^2
Some examples:
P(cell phoneage = 1829, race=black, gender=male)
= 1 / (1 + ((0 * 0.02 * 0.05) / 0.05^2) / ((1 * 0.98 * 0.95) / 0.95^2))
= 1
P(cell phoneage = 3049, race=black, gender=male)
= 1 / (1 + ((0.02 * 0.02 * 0.05) / 0.05^2) / ((0.98 * 0.98 * 0.95) / 0.95^2))
= 0.992
P(cell phoneage = 65+, race=white, gender=female)
= 1 / (1 + ((0.15 * 0.06 * 0.06) / 0.05^2) / ((0.85 * 0.94 * 0.94) / 0.95^2))
= 0.794
So, there are some results. Again, remember that these results depend on an assumption that can only be verified with more data.
There is not enough information to determine exactly how many people in a combined group have a cell phone, because we don't know exactly how those groups overlap.
Let's consider a simpler example: Out of 100 people, 50 are men and 50 like cheese. How many are men who like cheese?
Clearly we don't have enough information, because anywhere from none of the men to all of the men could like cheese.
The same concept applies to the cell phone data, and furthermore it is difficult to even come up with ranges of possibilities.
For example consider how many hispanic men have cellphones. It should be between 95% and 98%, right? Wrong! Imagine there are 10k men in the survey , 990 hispanic women, but only 10 hispanic men. We could have 9.5k nonhispanic men, 980 hispanic women, and 0 hispanic men who have a cell phone  giving us 0% of hispanic men owning a cell phone. Or by similar reasoning we could construct a case where 100% of hispanic men own a cell phone.
However, if we have data on exactly how many of each group were surveyed you might be able come up with some possible ranges that are narrower than 0100%. For example in the men who like cheese example if 60 of the people were men then we could say at least 10 must like cheese.