Advertisements
Advertisements
Question
Making use of the cube root table, find the cube root
7532 .
Advertisements
Solution
We have: \[7500 < 7532 < 7600 \Rightarrow \sqrt[3]{7500} < \sqrt[3]{7532} < \sqrt[3]{7600}\]
From the cube root table, we have:
\[\sqrt[3]{7500} = 19 . 57 \text{ and } \sqrt[3]{7600} = 19 . 66\]
For the difference (7600 - 7500), i.e., 100, the difference in values
APPEARS IN
RELATED QUESTIONS
You are told that 1331 is a perfect cube. Can you guess without factorization what is its cube root? Similarly, guess the cube roots of 4913, 12167, 32768
Using the method of successive subtraction examine whether or not the following numbers is perfect cube 130 .
\[\sqrt[3]{8 \times . . .} = 8\]
Evaluate:
\[\sqrt[3]{96} \times \sqrt[3]{144}\]
Find The cube root of the numbers 3048625, 20346417, 210644875, 57066625 using the fact that 3048625 = 3375 × 729 .
Making use of the cube root table, find the cube root
5112 .
Making use of the cube root table, find the cube root
7342 .
Making use of the cube root table, find the cube root
133100 .
Find the smallest number by which 26244 may be divided so that the quotient is a perfect cube.
The least number by which 72 be multiplied to make it a perfect cube is ______.
