Look at the bases you would have when you dissociated a H off of your answer choices.
SiH3-
SH-
H3CO-
TeH-
OH-
You have the right idea with electronegativity, it increases from left to right across the periodic table. The elements to the right of the table want electrons more, so they're more okay with having a negative charge. If they're more stable with a negative charge, it means that the hydrogen will be more willing to dissociate off of it, which means it's a better acid. Now, there will still be an equilibrium
HA <--> H+ + A- (generic acid-dissociation reaction)
but if A- is more okay with existing (like we said because they're more electronegative, think Cl- or Br- existing in solution), then equilibrium will be shifted to the right, increasing [H+] concentration. That was just to give you a few ways to think about it.
Now, let's look at your answer choices. You should have it narrowed down to the three molecules with the elements furthest right on the periodic table, so you have OH- SH- and TeH-. I know you're still probably thinking "okay, electronegativity" but there's a more important factor at play when all of your elements are in the same column - the size of the atom that carries the negative charge. Imagine you have a tennis ball and a beach ball - your OH- is your tennis ball (8 protons?!) and your TeH- is your beach ball (55 protons!!), and you have to smear an entire jar of peanut butter over the surface of the ball. It'll be a lot easier to smear that peanut butter over the beach ball than the tennis ball, so the larger molecule is better at stabilizing the negative charge, therefore TeH- is the most stable anion, meaning TeH2 is more willing to dissociate, making a higher [H+] concentration, making a stronger acid.