Difference between revisions of "2019 AMC 10A Problems/Problem 19"

Revision as of 18:46, 19 August 2024

Problem

What is the least possible value of $(x+1)(x+2)(x+3)(x+4)+2019$ where $x$ is a real number?

$\textbf{(A) } 2017 \qquad\textbf{(B) } 2018 \qquad\textbf{(C) } 2019 \qquad\textbf{(D) } 2020 \qquad\textbf{(E) } 2021$

Solution 1

Grouping the first and last terms and two middle terms gives $(x^2+5x+4)(x^2+5x+6)+2019$ , which can be simplified to $(x^2+5x+5)^2-1+2019$ . Noting that squares are nonnegative, and verifying that $x^2+5x+5=0$ for some real $x$ , the answer is $\boxed{\textbf{(B) } 2018}$ .

Solution 2

Let $a=x+\tfrac{5}{2}$ . Then the expression $(x+1)(x+2)(x+3)(x+4)$ becomes $\left(a-\tfrac{3}{2}\right)\left(a-\tfrac{1}{2}\right)\left(a+\tfrac{1}{2}\right)\left(a+\tfrac{3}{2}\right)$ .

We can now use the difference of two squares to get $\left(a^2-\tfrac{9}{4}\right)\left(a^2-\tfrac{1}{4}\right)$ , and expand this to get $a^4-\tfrac{5}{2}a^2+\tfrac{9}{16}$ .

Refactor this by completing the square to get $\left(a^2-\tfrac{5}{4}\right)^2-1$ , which has a minimum value of $-1$ . The answer is thus $2019-1=\boxed{\textbf{(B) }2018}$ .

Solution 3 (calculus)

Similar to Solution 1, grouping the first and last terms and the middle terms, we get $(x^2+5x+4)(x^2+5x+6)+2019$ .

Letting $y=x^2+5x$ , we get the expression $(y+4)(y+6)+2019$ . Now, we can find the critical points of $(y+4)(y+6)$ to minimize the function:

$\frac{d}{dx}(y^2+10y+24)=0$

$2y+10=0$

$2y=-5$

$y=-5,0$

To minimize the result, we use $y=-5$ . Hence, the minimum is $(-5+4)(-5+6)=-1$ , so $-1+2019 = \boxed{\textbf{(B) }2018}$ .

Note: We could also have used the result that minimum/maximum point of a parabola $y = ax^2 + bx + c$ occurs at $x=-\frac{b}{2a}$ .

Note 2: This solution is somewhat "lucky", since when we define variables to equal a function, and create another function out of these variables, the domain of such function may vary from the initial one. This is important because the maximum and minimum value of a function is dependent on its domain, e.g:

$f(x)=x^2$ has no maximum value in the the integers, but once restricting the domain to $(-5, 5)$ the maximum value of $f(x)$ is $25$ .

Also, observe that if we were to evaluate this by taking the derivative of $(x+1)(x+2)(x+3)(x+4)+2019$ , we would get $-5$ as the $x$ -value to obtain the minimum $y$ -value of this expression. It can be seen that $-5$ is actually an inflection point, instead of a minimum or maximum.

-Note 2 from Benedict T (countmath1)

Solution 4(guess with answer choices)

The expression is negative when an odd number of the factors are negative. This happens when $-2 < x < -1$ or $-4 < x < -3$ . Plugging in $x = -\frac32$ or $x = -\frac72$ yields $-\frac{15}{16}$ , which is very close to $-1$ . Thus the answer is $-1 + 2019 = \boxed{\textbf{(B) }2018}$ .

Solution 5 (using the answer choices)

Answer choices $C$ , $D$ , and $E$ are impossible, since $(x+1)(x+2)(x+3)(x+4)$ can be negative (as seen when e.g. $x = -\frac{3}{2}$ ). Plug in $x = -\frac{3}{2}$ to see that it becomes $2019 - \frac{15}{16}$ , so round this to $\boxed{\textbf{(B) }2018}$ .

We can also see that the limit of the function is at least $-1$ since at the minimum, two of the numbers are less than $1$ , but two are between $1$ and $2$ .

Solution 6 (also calculus but more convoluted)

We can ignore the $2019$ and consider it later, as it is a constant. By difference of squares, we can group this into $\left((x+2.5)^2-0.5^2\right)\left((x+2.5)^2-1.5^2\right)$ . We pull a factor of $4$ into each term to avoid dealing with decimals:

$\dfrac{\left((2x+5)^2-1\right)\left((2x+5)^2-9\right)}{16}.$

Now, we let $a=2x+5$ . Our expression becomes:

$\dfrac{(a-1)(a-9)}{16}=\dfrac{a^2-10a+9}{16}.$

Taking the derivative, we get $\dfrac{2a-10}{16}=\dfrac{a-5}8.$ This is equal to $0$ when $a=5$ , and plugging in $a=5$ , we get the expression is equal to $-1$ and therefore our answer is $2019-1=\boxed{\text{(B)}~2018}.$

~Technodoggo

Solution 7

The $2019$ can always be accounted for later, so we only have to consider the minimum value of the term $(x+1)(x+2)(x+3)(x+4)$ . Note that:

$(x+2)(x+3) = (x+2.5)^2-0.25$ .

Similarly,

$(x+1)(x+4) = (x+2.5)^2-2.25$ .

Now, we let $(x+2.5)^2 = a$ , and we can express the term as:

$(a-0.25)(a-2.25)$ .

Expanding, we have:

$y = a^2-2.5a+0.5625$

To find the minimum value of this quadratic, we just find the $x$ -value of the vertex and directly plug it in. We have $\dfrac{-(-2.5)}{2}$ which is just $1.25.$ Plugging it back into our quadratic, we get $(1.25)^2-2.5(1.25)+0.5625$ , which simplifies to $-1$ , meaning our answer is simply just $-1+2019 = \boxed{\textbf{(B)}~2018}.$

~hexuhdecimal

Video Solutions

https://www.youtube.com/watch?v=Vf2LkM7ExhY by SpreadTheMathLove

https://www.youtube.com/watch?v=Lis8yKT9WXc (less than 2 minutes)

https://youtu.be/NRa3VnjNVbw - Education, the Study of Everything
https://www.youtube.com/watch?v=Mfa7j2BoNjI
https://youtu.be/tIzJtgJbHGc - savannahsolver
https://youtu.be/3dfbWzOfJAI?t=3319 - pi_is_3.14
https://youtu.be/GmUWIXXf_uk?t=1134 ~ pi_is_3.14

@@ Line 66: / Line 66: @@
 ~Technodoggo
+==Solution 7==
+The <math>2019</math> can always be accounted for later, so we only have to consider the minimum value of the term <math>(x+1)(x+2)(x+3)(x+4)</math>.
+Note that:
+<math>(x+2)(x+3) = (x+2.5)^2-0.25</math>.
+Similarly,
+<math>(x+1)(x+4) = (x+2.5)^2-2.25</math>.
+Now, we let <math>(x+2.5)^2 = a</math>, and we can express the term as:
+<math>(a-0.25)(a-2.25)</math>.
+Expanding, we have:
+<math>y = a^2-2.5a+0.5625</math>
+To find the minimum value of this quadratic, we just find the <math>x</math>-value of the vertex and directly plug it in. We have <math>\dfrac{-(-2.5)}{2}</math> which is just <math>1.25.</math> Plugging it back into our quadratic, we get <math>(1.25)^2-2.5(1.25)+0.5625</math>, which simplifies to <math>-1</math>, meaning our answer is simply just <math>-1+2019 = \boxed{\textbf{(B)}~2018}.</math>
+~hexuhdecimal
 ==Video Solutions==

2019 AMC 10A (Problems • Answer Key • Resources)
Preceded by Problem 18	Followed by Problem 20
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