Uses of Square and Cube roots
Key Concepts
1. Solving Equations involving Perfect Squares
2. Solving Equations involving Perfect cubes
3. Solving Equations involving Imperfect Squares and Cubes
Solve Equations Using Square Roots and Cube Roots
Introduction:
- In this chapter, we will learn to solve equations involving perfect squares and cubes.
- Solve equations involving imperfect squares and imperfect cubes.
Square root:
The square root of a number is the number that gets multiplied by itself to give the product.
The square root of 9 is 3, because when 3 is multiplied by itself we get 9.
Perfect squares:
Perfect squares are numbers whose square roots are whole numbers.
Diagrammatic representation of perfect squares:
What is a Cube Root?
The cube root of a number is a special value that when cubed gives the original number.
This is called 3 Cubed i.e., 3 × 3 × 3
So, cube root of 27 is 3.
Perfect Cubes:
Perfect cubes are numbers whose cube roots are whole numbers.
5 is the cube root of 125.
Since 5 is a whole number, 27 is called perfect cube.
1.5 Solve Equations Using Square Roots and Cube Roots:
1.5.1 Solve equations involving perfect squares
George wants to make a square patio. He has enough concrete to pave an area of 225 square feet. Use the formula s =√A to find the length of each side of the patio.
Step 1: Read the problem. Draw a figure of square patio and label it with the given information.
A = 225 square feet
Step 2: Identify what you are looking for.
The length of a side of the square patio.
Step 3: Name what you are looking for by choosing a variable to represent it.
Let s = the length of a side.
Step 4: Translate into an equation by writing the appropriate formula or model for the situation.
Substitute the given information.
A = s2, and A = 225
225 = s2
√225 = √s2
Step 5: Solve the equation using good algebra techniques.
25 = s
Step 6: Answer the question with a complete sentence.
Each side of the patio should be 25 feet.
1.5.2 Solve equations involving perfect cubes
George constructed a cubical water tank that has base area of 49 m2 and is
13
water filled. Let’s find the amount of water it can hold.
A cube has all three sides equal.
Let the side be a
so base area = a2 = 49
a = 7m
So, volume of water it can hold = a × a × a
= 7 × 7 × 7
= 343m3
1313
of the tank is already filled. So, remaining part of the tank is
2323
343 ×
2323
= 228.6
1m3 = 1000L
So, the amount of water it can hold = 228.6 × 1000 = 228600 L
1.5.3 Solve equations involving imperfect squares and cubes
Let’s solve for x in the equation x 2 = 27
Step1: Apply root on both the sides for simplification
√x 2 = √27
Step2: Simplify the equation
x = √27
x = +√27 or -√27
Let’s solve for x in the equation x 3 = 11
Step1: Apply cube root on both the sides for simplification
3√x 3 = 3√11
Step2: Simplify the equation
x = 3√11
Exercise:
1. Find the square of the following numbers.
(i) 32 (ii) 35 (iii) 86
(iv) 93 (v) 71 (vi) 46
2. Find which of the following numbers are perfect squares?
(i) 225 (ii) 189 (iii) 441
(iv) 729 (v) 1575 (iv) 900
3. Which of the following numbers are not perfect cubes?
(i) 216 (ii) 128 (iii) 1000 (iv) 100 (v) 46656
4. Which of the following are perfect cubes?
(i) 400 (ii) 3375 (iii) 8000 (iv) 15625
(v) 9000 (vi) 6859 (vii) 2025 (viii) 10648
5. Is 392 a perfect cube? If not, find the smallest natural number by which 392 must be multiplied so that the product is a perfect cube.
6. Find the smallest number by which each of the following numbers must be multiplied to obtain a perfect cube.
(i) 243 (ii) 256 (iii) 72 (iv) 675 (v) 100
7. Find the smallest number by which each of the following numbers must be divided to obtain a perfect cube.
(i) 81 (ii) 128 (iii) 135 (iv) 192 (v) 704
8. Parikshit makes a cuboid of plasticine of sides 5 cm, 2 cm, 5 cm. How many such cuboids will he need to form a cube?
9. Find the cube root of each of the following numbers by prime factorization method.
(i) 64 (ii) 512 (iii) 10648 (iv) 27000
10. The students of Class VIII of a school donated 2401 dollars in all, for a cyclone relief fund. Each student donated as many dollars as the number of students in the class. Find the number of students in the class.
What have we learned:
• Square roots and cube roots.
• Perfect squares and perfect cubes.
• How to use perfect squares and perfect cubes to solve equations.
• How to use imperfect squares and imperfect cubes to solve equations.
Concept Map:
Related topics
Square 1 to 20 : Chart, Table, Perfect Squares and Examples
Square 1 to 20 When you multiply a number by itself, the result is called a square. And when you’re preparing for exams, you need to have a foundation for algebra and quick mental math because you get a really short time to do your exam. Therefore, learning the squares from one to twenty is […]
Square 1 to 40 : Table, Perfect Squares, Chart and Examples
Square 1 to 40 When you multiply a number by itself, the resulting number is a square, and if you are someone who is either appearing in a competitive exam or just wants to do well in math in school, knowing square 1 to 40 is a really important skill. But manually multiplying every time, […]
Square Root : Definition, Formula, Methods and Types Explained
Square Root Square roots are one of those seemingly daunting maths topics that appear in many different situations, from algebra to geometry. Yet the concepts behind them aren’t as hard to grasp. It makes handling numbers far easier if you know the concept well. Let us understand how to find the square roots of a number […]
Cubes 1 to 20 : Chart, Table, Memory Tricks and Examples
Most students don’t struggle much with smaller cubes like 2³ or 3³. Those usually come quickly. The hesitation starts with numbers like 11³ or 17³. Or when someone suddenly asks, what is 20 cubed? That pause is not a memory problem. It’s about the lack of proper understanding and hence confidence. Naturally, learning cubes 1 […]
Other topics
Comments: