Assume Statement 1 alone. Examine these examples:

In both cases, the main conditon and that of Statement 1 are satisfied, but in only one case can the result be represented by a terminating decimal or integer.

A similar argument shows Statement 2 alone to be insufficient:

Assume both statements. Then rewrite the fractions as follows:

, where  - that is, their lowest-terms representations.

By Statement 1, ; by Statement 2, . Therefore,

,

and their product is

,

a terminating decimal.

We have one equation and two unknowns. To find x, we need to find y.

I) Tells us that y is .79 therefore we can plug this value into our equation and solve for x.

Plugging in the y value from Statement I and using algebraic operations to solve for x.

Multiply first term.

Subtract 4.74 from both sides.

Divide by -13.

II) Is irrelevant.

Therefore Statement I) alone is sufficient to answer the question but Statement II) alone is not.

 (1) Subtracting  from both sides of  shows that  , so   must be negative  SUFFICIENT

(2) Subtracting 4 from both sides of  gives . Therefore, for this statement,  can be negative  but is not necessarily negative. NOT SUFFICIENT.

Looking at statements (1) and (2) separately, there is no information about the distance between  and . Looking at statements (1) and (2) together, there are two possibilities: 1)  and  are on different sides of , and the distance between them is 19; 2)  and  are on the same side of , and the distance between them is 5. Therefore, we cannot get the only possible answer to this question based on the two statements.

Statement 1 precisely tells how many children are attending the party while Statement 2 only provides a range.

The price of 6 sandwiches can be expressed as . Regrouping is needed since this is not in the answer choices. If $3.00 is used instead of $2.99, each of the five additional sandwiches is .01 too high and the total is .05 too high. Therefore, this amount needs to be subtracted from the $4.95.

If it is known that , it can be determined that .

Then 

Since  , , and the question is answered.

But if we only know that , it is not sufficient.

Case 1:

 yields 

Case 2:

 yields 

The answer is that Statement 1 is sufficient, but not Statement 2.

A number is rational if and only if its decimal representation is terminating or repeating.

 and  are terminating decimals, which are rational (note: the latter number is not equal to ). Both can be eliminated.

 has a repeating digit and  has a repeating group of five digits, and are therefore repeating decimals, which are also rational. Both can be eliminated.

 has an infinite pattern - the number of zeroes that precede each one is increasing by one with each group - but since the pattern is not repeating, it is neither a terminating decimal nor a repeating decimal. It is irrational.

To find the real solutions, we need to know what c is. An easy way to do that would be if we had a point on the function.

I) gives us such a point. Therefore, we are able to substitute in our values and solve for c using algebraic operations.

Thus our equation becomes:

.

From here we can try to factor to find the real solutions or you can use the quadratic formula.

Plugging in our values we get the solution .

II) Is not really relevant, we are dealing with a parabola, so it shouldn't be undefined anyway.

We can find each in terms of .

In ascending order, the four values are:

The correct choice is  .