Analyze the polynomial to consider factoring by grouping. If the polynomial is in the form where the removal of the greatest common factor (GCF) from the first two terms and the last two terms reveals another common factor, you can employ the grouping method. For instance, let F(x) = x³ – x² – 4x + 4. When you remove the GCF from the first and last two terms, you get the following: x²(x – 1) – 4 (x – 1). Now you can pull out (x – 1) from each part to get, (x² – 4) (x – 1). Using the “difference of squares” method, you can go further: (x – 2) (x + 2) (x – 1). Once each factor is in its prime, or nonfactorable form, you are done.

Look for a difference or sum of cubes. If the polynomial has only two terms, each with a perfect cube, you can factor it based on known cubic formulas. For sums, (x³ + y³) = (x + y) (x² – xy + y²). For differences, (x³ – y³) = (x – y) (x² + xy + y²). For example, let G(x) = 8x³ – 125. Then factoring this third degree polynomial relies on a difference of cubes as follows: (2x – 5) (4x² + 10x + 25), where 2x is the cube-root of 8x³ and 5 is the cube-root of 125. Because 4x² + 10x + 25 is prime, you are done factoring.

See if there is a GCF containing a variable which can reduce the degree of the polynomial. For instance, if H(x) = x³ – 4x, factoring out the GCF of “x,” you would get x (x² - 4). Then using the difference of squares technique, you can further breakdown the polynomial into x (x – 2) (x + 2).

Use known solutions to reduce the degree of the polynomial. For example, let P(x) = x³ – 4x² – 7x + 10. Because there is no GCF or difference/sum of cubes, you must use other information to factor the polynomial. Once you find out that P(c) = 0, you know (x – c) is a factor of P(x) based on the "Factor Theorem" of algebra. Therefore, find such a "c." In this case, P(5) = 0, so (x – 5) must be a factor. Using synthetic or long division, you get a quotient of (x² + x – 2), which factors into (x – 1) (x + 2). Therefore, P(x) = (x – 5) (x – 1) (x + 2).