Learn on PengiEureka Math, Grade 4Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.

In this Grade 4 Eureka Math lesson from Chapter 15, students learn to represent and solve three-digit dividend division problems numerically using divisors of 2, 3, 4, and 5. The lesson focuses on the long division algorithm alongside place value charts and unit form reasoning, building fluency with problems such as 297 ÷ 4 and 846 ÷ 2. Students also practice multiplying and dividing by place value units to strengthen their understanding of hundreds, tens, and ones in division.

Section 1

Executing the Standard Algorithm for Three-Digit Division

Property

The standard algorithm for division is a step-by-step process to find a quotient and a remainder. The relationship is defined by: $Dividend = (Quotient \times Divisor) + Remainder$ .

Examples

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Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Back to Eureka Math, Grade 4

Lesson 1
Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.
Learn Practice
Lesson 2
Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.
Learn Practice
Lesson 3Current
Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.
Learn Practice
Lesson 4
Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.
Learn Practice
Lesson 5
Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.
Learn Practice
Lesson 6
Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.
Learn Practice
Lesson 7
Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.
Learn Practice
Lesson 8
Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.
Learn Practice

Lesson overview

Expand to review the lesson summary and core properties.

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Section 1

Executing the Standard Algorithm for Three-Digit Division

Property

The standard algorithm for division is a step-by-step process to find a quotient and a remainder. The relationship is defined by: $Dividend = (Quotient \times Divisor) + Remainder$ .

Examples

Book overview

Jump across lessons in the current chapter without opening the full course modal.

Continue this chapter

Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Back to Eureka Math, Grade 4

Lesson 1
Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.
Learn Practice
Lesson 2
Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.
Learn Practice
Lesson 3Current
Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.
Learn Practice
Lesson 4
Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.
Learn Practice
Lesson 5
Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.
Learn Practice
Lesson 6
Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.
Learn Practice
Lesson 7
Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.
Learn Practice
Lesson 8
Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.
Learn Practice

Overview

Lesson overview

Review the lesson summary and core properties without leaving the current page.

Overview

Section 1

Executing the Standard Algorithm for Three-Digit Division

Property

The standard algorithm for division is a step-by-step process to find a quotient and a remainder. The relationship is defined by: $Dividend = (Quotient \times Divisor) + Remainder$ .

Examples

Book overview

Jump across lessons in the current chapter without opening the full course modal.

Continue this chapter

Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Back to Eureka Math, Grade 4

Lesson 1
Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.
Learn Practice
Lesson 2
Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.
Learn Practice
Lesson 3Current
Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.
Learn Practice
Lesson 4
Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.
Learn Practice
Lesson 5
Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.
Learn Practice
Lesson 6
Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.
Learn Practice
Lesson 7
Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.
Learn Practice
Lesson 8
Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.
Learn Practice

Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.

Property

Examples

Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.

Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.

Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.

Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.

Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.

Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.

Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.

Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.

Lesson overview

Property

Examples

Chapter 15: Division of Thousands, Hundreds, Tens, and Ones

Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.

Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.

Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.

Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.

Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.

Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.

Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.

Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.

Lesson 1: Divide multiples of 10, 100, and 1,000 by single-digit numbers.

Lesson 2: Represent and solve division problems with up to a three-digit dividend numerically and with place value disks requiring decomposing a remainder in the hundreds place.

Lesson 3: Represent and solve three-digit dividend division with divisors of 2, 3, 4, and 5 numerically.

Lesson 4: Represent numerically four-digit dividend division with divisors of 2, 3, 4, and 5, decomposing a remainder up to three times.

Lesson 5: Solve division problems with a zero in the dividend or with a zero in the quotient.

Lesson 6: Interpret division word problems as either number of groups unknown or group size unknown.

Lesson 7: Interpret and find whole number quotients and remainders to solve one-step division word problems with larger divisors of 6, 7, 8, and 9.

Lesson 8: Explain the connection of the area model of division to the long division algorithm for three- and four-digit dividends.