AMC 8 · 2013 · #17

Grade 6 arithmeticalgebra

Archetype Arithmetic Expression Decomposition

sequences-arithmeticlinear-equations-one-varmean-median-mode-range convert-to-algebraidentify-subproblems ↑ Prerequisites: multi-digit-arithmeticlinear-equations-one-var

📏 Short solution 💡 2 insights

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Problem

The sum of six consecutive positive integers is 2013. What is the largest of these six integers?

Pick an answer.

(A)

335

(B)

338

(C)

340

(D)

345

(E)

350

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Toolkit + CCSS Solution

Understand

Restated: Six positive integers in a row (each one bigger than the last) add up to $2013$. Find the largest of these six numbers.

Givens: Six numbers that are consecutive positive integers (e.g. $n, n+1, n+2, n+3, n+4, n+5$); Their sum equals $2013$; Answer choices: (A) $335$, (B) $338$, (C) $340$, (D) $345$, (E) $350$

Unknowns: The largest of the six consecutive integers

Understand

Restated: Six positive integers in a row (each one bigger than the last) add up to $2013$. Find the largest of these six numbers.

Givens: Six numbers that are consecutive positive integers (e.g. $n, n+1, n+2, n+3, n+4, n+5$); Their sum equals $2013$; Answer choices: (A) $335$, (B) $338$, (C) $340$, (D) $345$, (E) $350$

Plan

Primary tool: #5 Look for a Pattern

Secondary: #7 Identify Subproblems

Six consecutive integers have a clean pattern: their sum is always $6$ times the average, and the average sits exactly in the middle of the list. Tool #5 (Look for a Pattern) lets us turn the sum directly into an average without algebra. Tool #7 (Identify Subproblems) splits the work into two easy pieces — first find the average, then count up to the largest. We avoid Tool #13 (Algebra) because the pattern lets a young solver finish using only division and a small addition.

Execute — Answer: B

#5 Look for a Pattern 6.SP.B.5 Step 1

Notice the pattern that makes consecutive sums easy.
For any list of consecutive integers, $\text{sum} = (\text{count}) \times (\text{average})$, so $\text{average} = \text{sum} \div \text{count}$.
With $6$ numbers summing to $2013$, divide to get the average.

$$\text{average} = 2013 \div 6 = 335.5$$

💡 Treating the sum as $6 \times \text{average}$ is the Grade 6 idea that the mean is the "balance point" of the data.

#5 Look for a Pattern 5.NBT.B.7 Step 2

Locate the average inside the list.
With an even count ($6$) of consecutive integers, the average falls halfway between the two middle numbers (the $3$rd and $4$th).
So $335.5$ means the $3$rd number is $335$ and the $4$th number is $336$.

$$\dots, 335, \underbrace{335.5}_{\text{average}}, 336, \dots$$

💡 A decimal like $.5$ landing between two whole numbers is the Grade 5 "halfway point" reading of a decimal.

#7 Identify Subproblems 3.OA.A.3 Step 3

Break the goal into a subproblem: once the $3$rd number is known, just count up.
The largest is the $6$th number, which is $3$ steps after the $3$rd number.

$$\text{largest} = 335 + 3 = 338$$

💡 Adding $3$ to the $3$rd term to reach the $6$th term is a Grade 3 multi-step word-problem add.

#7 Identify Subproblems 3.OA.A.3 Step 4

Match the largest, $338$, to the answer choices to finish the problem.

$$338 \;\Rightarrow\; \textbf{(B)}$$

💡 Closing the final subproblem by comparing your value to the listed options is a Grade 3 multi-step move.

[1] #5 6.SP.B.5 Notice the pattern that makes consecutive sums easy. For any list of consecutive

[2] #5 5.NBT.B.7 Locate the average inside the list. With an even count ($6$) of consecutive inte

[3] #7 3.OA.A.3 Break the goal into a subproblem: once the $3$rd number is known, just count up.

[4] #7 3.OA.A.3 Match the largest, $338$, to the answer choices to finish the problem.

Review

Reasonableness: Write the six numbers out and add: $333 + 334 + 335 + 336 + 337 + 338$. Pair the ends: $333 + 338 = 671$, $334 + 337 = 671$, $335 + 336 = 671$. Three pairs of $671$ give $3 \times 671 = 2013$. The sum matches, and the largest is $338$ — answer (B).

Alternative: Tool #6 (Guess and Check) on the choices. If the largest were $335$ (A), the six numbers would be $330$–$335$, summing to $6 \times 332.5 = 1995$ — too small. If the largest were $340$ (C), the sum would be $6 \times 337.5 = 2025$ — too big. Only (B) $338$ gives $6 \times 335.5 = 2013$. Tool #3 (Eliminate) confirms (B) is the only choice that works.

CCSS standards used (min grade 6)

3.OA.A.3 Use multiplication and division within 100 to solve word problems (The closing steps — adding $335 + 3 = 338$ to reach the $6$th term and matching the value to a multiple-choice option — are Grade 3 multi-step whole-number reasoning.)
5.NBT.B.7 Add, subtract, multiply, and divide decimals to hundredths (Reading $335.5$ as the halfway point between $335$ and $336$ uses Grade 5 fluency with decimals to the tenths place.)
6.SP.B.5 Summarize numerical data sets, including the mean (average) of a distribution (Using $\text{sum} = \text{count} \times \text{average}$, so $\text{average} = 2013 \div 6 = 335.5$, is the Grade 6 mean concept applied to a six-number list.)

⭐ Six numbers in a row add up to $6$ times their average — once you find the average ($2013 \div 6 = 335.5$), the largest is just three steps past the middle.

Problem

Toolkit + CCSS Solution

Understand

Plan

Execute — Answer: B

Review

CCSS standards used (min grade 6)

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