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Quantitative Aptitude Practice Test: Real Numbers and BODMAS Simplification
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Real numbers are numbers that can be used to measure a continuous one-dimensional quantity. They are the union of both rational and irrational numbers. Real numbers can be defined as the union of both rational and irrational numbers. They can be both positive or negative and are denoted by the symbol “R”. All the natural numbers, decimals and fractions come under this category. Real numbers can be positive or negative and are denoted by the symbol “R”. Some examples of real numbers include: 3, Pi, 0.333, −13, 5. BODMAS stands for “Bracket, Order, Division, Multiplication, Addition,... Show more
Quantitative Aptitude Practice Test: Real Numbers and BODMAS Simplification
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21 Questions

1. A and B are two positive integers such that AB = 81. Which of the following cannot be the value of (A+B)?
2. Find the rational number lying between √7 and √8.
3. Find the value of (125+216)-\(\frac{1750}{5^3}\)+15.
4. If p and q are distinct natural numbers, then which of the following is/are integer(s)?
I. \(\frac{p}{q}+\frac{q}{p}\)
II. pq(\(\frac{p}{q}+\frac{q}{p}\)) (p2+q2)-1
III. \(\frac{pq}{p^2+q^2}\)
5. Find the value of y which satisfy the inequalities |y| ≥ y and 7y – 25 > 3.
6. If m is a positive integer, then in which of the following form every square integer is represented?
7. Consider the following statements.
I. There are finite number of rational numbers between 51 and 52.
II. There are infinite number of rational numbers between 99 and 100.
III. There are finite number of irrational numbers between√2 and √3.
Which of the statement(s) given above is/are correct?
8. If \(\frac{m}{n}=\frac{5}{8}\), then what is the value of \(\frac{m-n}{m+n}\)?
9. If x and y are natural number, not necessarily distinct. For all values of x and y, which of the following is also a natural number?
10. What is the value of 12.8- 0.4 of (7.2-3.7)+2.4*3.02?
11. Given that, 12+32+52+72+92=165, then what is the value of 32+92+152+212+272?
12. Find the value of y which satisfy the inequalities |y| ≥ y and 7y – 25 > 3.
13. What is the value of (3+4-\(\frac{6}{2}\)+2) + \((\frac{\frac{9}{3}+6*5}{11})\)*((4+5-6)+(18+3*4)))?
14. What could be the maximum value of Z in the following equation?
7X9 + 2Y8 + 5Z6 = 1503
15. Given that, 12+32+52+72+92=165, then what is the value of 32+92+152+212+272?
16. What is the value of x, if x is real and |\(\frac{7-x}{5}\)|<2?
17. If m is a negative real number, then which of the following is true?
18. If x, y and z are real numbers such that x < y and z < 0, then which of the following statement is true?
19. If \(\frac{49}{15}\)=3+\(\frac{1}{x+\frac{1}{y+\frac{1}{z}}}\), where x, y and z are natural numbers, then what is value of z?
20. What could be the maximum value of Z in the following equation?
7X9 + 2Y8 + 5Z6 = 1503
21. If m is positive even integer and n is negative odd integer, then which of the following real number is the solution of mn?