How do you deal with a leading coefficient greater than #1# ?

Answer 1

A few thoughts...

I am not sure quite where you have encountered this phrase, but I suspect it may be in the context of an explanation as to how you might attempt to factor a quadratic.

When written in standard form, a polynomial is a sum of terms in descending order of power (a.k.a. degree) of #x# (or whatever variable you are using).

For example, the cubic polynomial:

#x^3+5x^2-7#
is in standard form since the degrees of the terms #3, 2, 0# are in descending order.

When written in this way, the "leading" term is the term of highest degree and the "leading coefficient" is the multiplier (coefficient) of this term.

In the case of #x^3+5x^2-7#, the "leading coefficient" is #1#, because we could have equivalently written #1x^3#.
A polynomial with leading coefficient #1# is called a monic polynomial.

So a monic quadratic looks like this:

#x^2+bx+c#
If we can find two numbers #alpha# and #beta# such that #alpha+beta = b# and #alphabeta = c#, then we find:
#x^2+bx+c = (x+alpha)(x+beta)#

For example, given:

#x^2+8x+15#
we can find #5+3=8# and #5*3 = 15#, so:
#x^2+8x+15 = (x+5)(x+3)#
What if we find a leading coefficient greater than #1#? (there's your expression)

This means that we have something like:

#2x^2+7x+6#

How might we try to factor this?

Using an AC method we can try to find a pair of factors of #AC=2*6=12# with sum #B=7#.
The pair #4, 3# works in that #4*3=12# and #4+3=7#.

We can then use this pair to split the middle term and factor by grouping:

#2x^2+7x+6 = (2x^2+4x)+(3x+6)#
#color(white)(2x^2+7x+6) = 2x(x+2)+3(x+2)#
#color(white)(2x^2+7x+6) = (2x+3)(x+2)#
Sign up to view the whole answer

By signing up, you agree to our Terms of Service and Privacy Policy

Sign up with email
Answer 2

When dealing with a leading coefficient greater than 1 in a polynomial function, the graph tends to be steeper compared to when the leading coefficient is 1. This means that the function's rate of increase or decrease is greater. To analyze the behavior of the function, you can consider the end behavior by looking at the sign of the leading coefficient and the degree of the polynomial. If the leading coefficient is positive and the degree of the polynomial is even, the function rises on both ends of the graph. If the leading coefficient is positive and the degree of the polynomial is odd, the function rises to the left and falls to the right. Conversely, if the leading coefficient is negative and the degree of the polynomial is even, the function falls on both ends. And if the leading coefficient is negative and the degree of the polynomial is odd, the function falls to the left and rises to the right.

Sign up to view the whole answer

By signing up, you agree to our Terms of Service and Privacy Policy

Sign up with email
Answer from HIX Tutor

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.

Not the question you need?

Drag image here or click to upload

Or press Ctrl + V to paste
Answer Background
HIX Tutor
Solve ANY homework problem with a smart AI
  • 98% accuracy study help
  • Covers math, physics, chemistry, biology, and more
  • Step-by-step, in-depth guides
  • Readily available 24/7