Download RRB NTPC Number Systeems Questions and Answers PDF. Top 40 RRB NTPC Maths questions based on asked questions in previous exam papers very important for the Railway NTPC exam.<\/p>\n
Download RRB NTPC Number Systems Questions Pdf<\/a><\/p>\n Get 1 year pass for Rs. 299. Enroll here<\/a><\/p>\n RRB NTPC Previous Papers [Download PDF]<\/a><\/p>\n Question 1:\u00a0<\/b>Find the number of odd divisor of 900900.<\/p>\n a)\u00a0144<\/p>\n b)\u00a036<\/p>\n c)\u00a0216<\/p>\n d)\u00a072<\/p>\n Question 2:\u00a0<\/b>What is the total number of even factors of 1143072?<\/p>\n a)\u00a0126<\/p>\n b)\u00a0105<\/p>\n c)\u00a084<\/p>\n d)\u00a021<\/p>\n Question 3:\u00a0<\/b>N = $-(1!)^1+(2!)^2-(3!)^3+(4!)^4-\u2026\u2026\u2026.-(99!)^{99}+(100!)^{100}$. The digit in the units place of $N^{100}$ will be<\/p>\n Question 4:\u00a0<\/b>Find the unit digit of $78^{{79}^{80}}$.<\/p>\n a)\u00a08<\/p>\n b)\u00a04<\/p>\n c)\u00a02<\/p>\n d)\u00a06<\/p>\n e)\u00a00<\/p>\n FREE RRB NTPC YOUTUBE VIDEOS<\/a><\/p>\n RRB NTPC Free Mock Test<\/a><\/p>\n Question 5:\u00a0<\/b>Find the rightmost non-zero digit in 91!.<\/p>\n Question 6:\u00a0<\/b>How many factors of 64800 are perfect squares?<\/p>\n Question 7:\u00a0<\/b>A 3 digit number becomes a perfect square when divided by 3 and becomes a perfect cube when divided by 2. What is the value of the number?<\/p>\n Question 8:\u00a0<\/b>Find the maximum value of x when 1!\u22172!\u22173!\u2217\u2026\u2026\u2026\u221720! is completely divisible by $6^x$?<\/p>\n a)\u00a077<\/p>\n b)\u00a075<\/p>\n c)\u00a078<\/p>\n d)\u00a083<\/p>\n Question 9:\u00a0<\/b>Sum of all digits of the number $10^{68} – 21$?<\/p>\n Question 10:\u00a0<\/b>N is an integer such that $ 10^8 \\leq N \\leq 10^9 $. If it is known that the sum of the digits of N is 4 then how many values of N are possible?<\/p>\n RRB NTPC Previous Papers Download PDF<\/a><\/p>\n RRB JE PREVIOUS PAPERS DOWNLOAD<\/a><\/p>\n Question 11:\u00a0<\/b>The LCM of $(17)_{n}$ and $(14)_{n}$ is $(330)_{4}$. Their GCD is $(11)_2$. Find n.<\/p>\n Question 12:\u00a0<\/b>Two numbers, $297_{B}$ and $792_{B}$ , belong to base B number system. If the first number is a factor of the second number then the value of B is:<\/p>\n a)\u00a011<\/p>\n b)\u00a012<\/p>\n c)\u00a015<\/p>\n d)\u00a017<\/p>\n e)\u00a019<\/p>\n Question 13:\u00a0<\/b>If a, b, c and d are four different positive integers selected from 1 to 25, then the highest possible value of ((a + b) + (c +d ))\/((a + b) + (c – d)) would be:<\/p>\n a)\u00a047<\/p>\n b)\u00a049<\/p>\n c)\u00a051<\/p>\n d)\u00a096<\/p>\n e)\u00a0None of the above<\/p>\n 18000+ Questions – Free SSC Study Material<\/a><\/p>\n Question 14:\u00a0<\/b>What is the largest five digit number which is divisible by 16, 28 and 42?<\/p>\n a)\u00a097792<\/p>\n b)\u00a099772<\/p>\n c)\u00a097992<\/p>\n d)\u00a099792<\/p>\n Question 15:\u00a0<\/b>A three digit number xyz has \u20184\u2019 factors. Which of the following will be the number of factors of the 6 digit number \u2018xyzxyz\u2019?<\/p>\n a)\u00a020<\/p>\n b)\u00a024<\/p>\n c)\u00a032<\/p>\n d)\u00a0More than one of the above are possible.<\/p>\n Question 16:\u00a0<\/b>p and q are positive numbers such that $p^q = q^p$, and $q = 9p$. The value of p is<\/p>\n a)\u00a0$\\sqrt{9}$<\/p>\n b)\u00a0$\\sqrt[6]{9}$<\/p>\n c)\u00a0$\\sqrt[9]{9}$<\/p>\n d)\u00a0$\\sqrt[8]{9}$<\/p>\n e)\u00a0$\\sqrt[3]{9}$<\/p>\n Question 17:\u00a0<\/b>The HCF of 2 numbers is 4 and the LCM is 1008. Further, it is known that one of the 2 numbers has an odd number of factors. The largest among the 2 numbers is<\/p>\n a)\u00a0144<\/p>\n b)\u00a0112<\/p>\n c)\u00a01008<\/p>\n d)\u00a0Cannot be determined<\/p>\n Question 18:\u00a0<\/b>Find the number of zeroes in 53!.<\/p>\n a)\u00a010<\/p>\n b)\u00a012<\/p>\n c)\u00a014<\/p>\n d)\u00a013<\/p>\n RRB NTPC Free Mock Test<\/a><\/p>\n RRB JE Free Mock Test<\/a><\/p>\n Question 19:\u00a0<\/b>Mr Surtur lives on a planet Greip, where all the citizens use base \u2018n\u2019 (where n>2) for calculations. Surtur once sold his watch for a particular amount (in the local currency), which was a two digit number, but received double the amount because the digits got mistakenly interchanged. For the least possible value of \u2018n\u2019, what is the decimal representation of the amount which Surtur should\u2019ve actually received by selling his watch (in the local currency)?<\/p>\n Question 20:\u00a0<\/b>A function $F_n$ is defined as $F_n = 11^n + 13^n$. What is the remainder when $F_{105}$ is divided by 144.<\/p>\n a)\u00a072<\/p>\n b)\u00a0108<\/p>\n c)\u00a096<\/p>\n d)\u00a0120<\/p>\n Question 21:\u00a0<\/b>Hardik wrote first 215 natural numbers in base 6. How many times did he write \u20184\u2019?<\/p>\n Question 22:\u00a0<\/b>Find the smallest four digit number which when divided by 7, 13 and 23 leaves remainders 4, 10 and 5 respectively.<\/p>\n Question 23:\u00a0<\/b>A rod is cut into 3 equal parts. The resulting portions are then cut into 12, 18 and 32 equal parts, respectively. If each of the resulting portions have integer length, the minimum length of the rod is<\/p>\n a)\u00a06912 units<\/p>\n b)\u00a0864 units<\/p>\n c)\u00a0288 units<\/p>\n d)\u00a0240 units<\/p>\n Question 24:\u00a0<\/b>In a Green view apartment, the houses of a row are numbered consecutively from 1 to 49. Assuming that there is a value of \u2018x\u2019 such that the sum of the numbers of the houses preceding the house numbered \u2018x\u2019 is equal to the sum of the numbers of the houses following it. Then what will be the value of \u2018x\u2019?<\/p>\n a)\u00a021<\/p>\n b)\u00a030<\/p>\n c)\u00a035<\/p>\n d)\u00a042<\/p>\n Question 25:\u00a0<\/b> ‘n’ is the greatest possible number that leaves the same remainder on dividing 6912 and 9216. How many factors of \u2018n\u2019 will become a perfect square or perfect cube on multiplying by 6?<\/p>\n a)\u00a06<\/p>\n b)\u00a07<\/p>\n c)\u00a012<\/p>\n d)\u00a08<\/p>\n Daily Free RRB Online Tests for RRB Exams<\/a><\/p>\n 100+ Free Online G.K Tests<\/a><\/p>\n Question 26:\u00a0<\/b>How many proper fractions $f = \\frac{p}{q}$ exist such that $0 < f < 1$ and $p+q=800$. It is known that $p$ and $q$ are relatively prime.<\/p>\n a)\u00a0160<\/p>\n b)\u00a0200<\/p>\n c)\u00a0216<\/p>\n d)\u00a0108<\/p>\n Question 27:\u00a0<\/b>If the last 6 digits of [(M)! – (N)!] are 999000, which of the following option is not possible for (M) \u00d7 (M – N)? Both (M) and (N) are positive integers and M > N. (M)! is factorial M.<\/p>\n a)\u00a0150<\/p>\n b)\u00a0180<\/p>\n c)\u00a0200<\/p>\n d)\u00a0225<\/p>\n e)\u00a0234<\/p>\n Question 28:\u00a0<\/b>A is the smallest even natural number such that it is a) 19% less than a natural number Question 29:\u00a0<\/b>What is the minimum value of \u2018n\u2019 (natural number) for which the remainders obtained when $325^n$ and $326^n$ are divided by 9 equal?<\/p>\n Question 30:\u00a0<\/b>The HCF of two numbers (a, b) is 7. How many ordered pairs (a, b) exist such that the a + b = 1540?<\/p>\n Question 31:\u00a0<\/b>Kishor intended to multiply a two-digit natural number and a three-digit natural number, but he left out the multiplication sign and simply placed the two-digit number to the left of the three-digit number, thereby forming a five-digit number. This number is exactly nine times the product Kishor would have obtained. What is the sum of the two-digit number and the three-digit number?<\/p>\n a)\u00a0126<\/p>\n b)\u00a0147<\/p>\n c)\u00a0151<\/p>\n d)\u00a0159<\/p>\n Download General Science Notes PDF<\/a><\/p>\n Question 32:\u00a0<\/b>How many factors of the number 24696 are perfect squares?<\/p>\n Question 33:\u00a0<\/b>\u2018k\u2019 represents the set of natural numbers whose total number of factors are odd. \u2018m\u2019 represents the set of all odd natural numbers. How many elements will be there in the set $k\\cap m$ if it is known that $0 \\leq k \\leq 1000$ and $0 \\leq m \\leq 900$<\/p>\n Question 34:\u00a0<\/b>L is a seven digit Integer with a digit sum of $55$, how many values are possible for L?<\/p>\n a)\u00a04005<\/p>\n b)\u00a02747<\/p>\n c)\u00a02447<\/p>\n d)\u00a03003<\/p>\n Question 35:\u00a0<\/b>If a number $K$ has $8$ as its Total number of factors, Which of the following cannot be the Total number of factors of $K^2$ ?<\/p>\n a)\u00a027<\/p>\n b)\u00a018<\/p>\n c)\u00a015<\/p>\n d)\u00a021<\/p>\n Question 36:\u00a0<\/b>How many factors of 36288 are perfect cubes?<\/p>\n a)\u00a09<\/p>\n b)\u00a04<\/p>\n c)\u00a06<\/p>\n d)\u00a08<\/p>\n Question 37:\u00a0<\/b>How many 4 digit numbers have their cubes ending with 44?<\/p>\n a)\u00a0180<\/p>\n b)\u00a090<\/p>\n c)\u00a045<\/p>\n d)\u00a0120<\/p>\n e)\u00a00<\/p>\n Question 38:\u00a0<\/b>X is the smallest number which leaves a remainder of 2 when divided by 7 and a remainder of 1 when divided by 19. What is the remainder when X is divided by 23?<\/p>\n a)\u00a012<\/p>\n b)\u00a09<\/p>\n c)\u00a013<\/p>\n d)\u00a017<\/p>\n Question 39:\u00a0<\/b>What will be the number of zeroes in$ (2000!)_{34}$. Here 34 is the base in which the number is written.<\/p>\n a)\u00a0122<\/p>\n b)\u00a0123<\/p>\n c)\u00a0124<\/p>\n d)\u00a0125<\/p>\n Question 40:\u00a0<\/b>Consider the series where $S_n = 200 + n^2$ for all natural numbers $n$. Therefore, $S_1 = 201, S_2 = 204, S_3 = 209$ and so on. Free RRB Daily Practice Set<\/a><\/p>\n Download Current Affairs Questions & Answers PDF<\/a><\/p>\n Answers & Solutions:<\/strong><\/span><\/p>\n 1)\u00a0Answer\u00a0(D)<\/strong><\/p>\n We can prime factorise the number in terms of prime numbers. 2)\u00a0Answer\u00a0(B)<\/strong><\/p>\n The given number (1143072) can be factorized in powers of prime numbers as follows: We can find the number of even factors when we have at least 1 power of 2. Therefore, the number of even factors = 5*(6+1)*(2+1) = 105.<\/p>\n Hence, option B is the correct answer.<\/p>\n 3)\u00a0Answer:\u00a01<\/b><\/p>\n $1! = 1, (1!)^1 = 1$ 4)\u00a0Answer\u00a0(A)<\/strong><\/p>\n We have to find out the unit digit of $78^{{79}^{80}}$. 5)\u00a0Answer:\u00a02<\/b><\/p>\n We know that the rightmost non-zero in x! where 25 < x < 125 = {$4^a$* [Last non-zero digit of a!]*[Last non-zero digit of b!]} mod 10, when we write x as 25a+b.<\/p>\n Here, 91 can be written as 25*3 + 16, therefore, a = 3, b = 16<\/p>\n $\\therefore$ The rightmost non-zero in 91! = {$4^3$*[Last non-zero digit of 3!]*[Last non-zero digit of 16!]} mod 10 … (1)<\/p>\n The rightmost non-zero in x! where 5 < x < 25 = {$2^a$* [Last non-zero digit of a!]*[Last non-zero digit of b!]} mod 10, when we write x as 5a+b.<\/p>\n Here, 16 can be written as 5*3 + 1, therefore, a = 3, b = 1<\/p>\n $\\therefore$ The rightmost non-zero in 16! = {$2^3$*[Last non-zero digit of 3!]*[Last non-zero digit of 1!]} mod 10 = {8*6*1} mod 10 = 8 … (2)<\/p>\n Substituting the value of the rightmost non-zero in 16! from equation (2) to equation (1),<\/p>\n $\\therefore$ The rightmost non-zero in 91! = {64*[6]*[8]} mod 10 = 3072 mod 10 = 2.<\/p>\n 6)\u00a0Answer:\u00a018<\/b><\/p>\n We can write \u201864800\u2019 as $2^5 \\times 3^4 \\times 5^2$ 7)\u00a0Answer:\u00a0432<\/b><\/p>\n The 3 digit number should be of the form $2^a 3^b 5^c \u2026.$ and so on. The number, on division by 2 becomes a perfect cube. Therefore, the power of 2 can be 1,4 or 7.<\/p>\n Since the number becomes a perfect cube and perfect square on division by 3 and 2, the powers of other numbers should be at least 6.<\/p>\n However, terms such as $5^6$ are huge and hence, we can conclude that the number must be composed of powers of 2 and 3.<\/p>\n \u2019a\u2019 can take values 1, 4 or 7 and \u2018b\u2019 can take values 1, 3 or 5. Therefore, $432$ is the right answer.<\/p>\n 8)\u00a0Answer\u00a0(C)<\/strong><\/p>\n For finding out maximum value of $6^x$.<\/p>\n Since we know that 6 = 2*3 and in any factorial frequency of 2 will be higher as compared to 3. Hence for finding out maximum value of x we have to figure out the maximum power of 3.<\/p>\n Maximum power of 3 in 20! This power will remain same for 18! and 19!<\/p>\n For calculating maximum power of 3 in 17! ,16! and 15! Similarly, we will calculate for remaining terms. 9)\u00a0Answer:\u00a0610<\/b><\/p>\n Let us find out the pattern by using small powers.<\/p>\n $\\Rightarrow 10^{4} -21 = 9979$<\/p>\n $\\Rightarrow 10^{5} -21 = 99979$<\/p>\n $\\Rightarrow 10^{6} -21 = 999979$<\/p>\n We can clearly see the pattern<\/p>\n $\\Rightarrow 10^{n} -21 = 9999(n-2 times)79$<\/p>\n So $10^68 -21 = 9999(66 times)79$<\/p>\n Hence, sum of all digits = 67*9 + 7 = 610<\/p>\n 10)\u00a0Answer:\u00a0165<\/b><\/p>\n We have been given that $ 10^8 \\leq N \\leq 10^9 $. Hence, N must be a 9 digit number. Now, sum of the digits of N is 4. Hence, the possible cases are 11)\u00a0Answer:\u00a08<\/b><\/p>\n Given, GCD = $(11)_{2}$ = $(3)_{10}$<\/p>\n Product of the numbers = LCM * HCF<\/p>\n $(17)_{n}$ = n + 7<\/p>\n $(14)_{n}$ = n + 4<\/p>\n (n + 4) (n + 7) = 180<\/p>\n $n^2 + 11n – 152 = 0$<\/p>\n (n – 8) (n + 19) = 0<\/p>\n n = 8<\/p>\n 12)\u00a0Answer\u00a0(E)<\/strong><\/p>\n In Base B, $297_B = 2B^2 + 9B + 7$<\/p>\n and $792_B = 7B^2 + 9B + 2$<\/p>\n It is given that $297_{B}$ is a factor of $792_{B}$<\/p>\n => $\\frac{7B^2 + 9B + 2}{2B^2 + 9B + 7}$ must be an integer<\/p>\n => $\\frac{(2B^2 + 9B + 7) + (5B^2 – 5)}{2B^2 + 9B + 7}$<\/p>\n => $\\frac{5B^2 – 5}{2B^2 + 9B + 7} + 1 = k$<\/p>\n => $5B^2 – 5 = (2B^2 + 9B + 7) k$ (where $k$ is factor)<\/p>\n Put $k = 1$<\/p>\n => $5B^2 – 5 = 2B^2 + 9B + 7$<\/p>\n => $B^2 – 3B – 4 = 0$<\/p>\n => $(B – 4) (B + 1) = 0$<\/p>\n => $B = 4 , -1$<\/p>\n Since, B is a base,so B must be greater than 9. Hence, it is not possible<\/p>\n Put $k = 2$<\/p>\n => $5B^2 – 5 = 4B^2 + 18B + 14$<\/p>\n => $B^2 – 18B – 19 = 0$<\/p>\n => $(B – 19) (B + 1) = 0$<\/p>\n => $B = 19 , -1$<\/p>\n $\\therefore B = 19$<\/p>\n 13)\u00a0Answer\u00a0(C)<\/strong><\/p>\n Expression : $\\frac{a + b + c + d}{a + b + c – d}$<\/p>\n To maximize the above expression, we have to minimize the denominator<\/p>\n Minimum value of the denominator = 1<\/p>\n So we can make $a + b + c = 26$ and $d = 25$ (as maximizing d will give denominator the least value).<\/p>\n So required maximum value = $\\frac{a + b + c + d}{a + b + c – d}$<\/p>\n = $\\frac{26 + 25}{26 – 25} = 51$<\/p>\n 14)\u00a0Answer\u00a0(D)<\/strong><\/p>\n The LCM of 16 and 28 is 112. 15)\u00a0Answer\u00a0(D)<\/strong><\/p>\n xyzxyz = xyz*1001 16)\u00a0Answer\u00a0(D)<\/strong><\/p>\n $p^q = q^p$. Substituting, we get, 17)\u00a0Answer\u00a0(D)<\/strong><\/p>\n We know that the product of 2 numbers = HCF * LCM However, the 2 numbers can be split as $2^2*6^2$ and $2^2*7$ or $2^2$ and $2^2*6^2*7.$ 18)\u00a0Answer\u00a0(B)<\/strong><\/p>\n The number of zeroes is determined by the maximum power of 2 and 5. Highest power of 5 in 53! = $[\\frac{53}{5}] + [\\frac{53}{25}]$ = 10 + 2 = 12<\/p>\n Hence there are 12 zeroes in 53!<\/p>\n 19)\u00a0Answer:\u00a08<\/b><\/p>\n The base used by the citizens of Greip is \u2018n\u2019.<\/p>\n Let the amount in local currency for which the Surtur sold his watch be $(ab)_{n}$<\/p>\n Decimal representation of this original amount = na + b \u2026(1)<\/p>\n The amount actually received by Surtur in local currency = $(ba)_{n}$<\/p>\n Decimal representation of this amount = nb + a \u2026(2)<\/p>\n We know that Surtur received double the amount because the digits got mistakenly interchanged.<\/p>\n Hence, We know that n > 2.<\/p>\n Let\u2019s consider that n = 3, we get, As \u2018a\u2019 cannot be equal to 0; minimum value of b will be 5. This is not possible as in base 3 we don\u2019t have digit 5. Let\u2019s consider that n = 4, we get, As \u2018a\u2019 cannot be equal to 0; minimum value of b will be 7. This is not possible as in base 4 we don\u2019t have digit 7. Let\u2019s consider that n = 5, we get, Hence, value of (a,b) satisfying the equation is (1,3) Hence, least value of n which satisfies the given condition is 5. Hence, amount in local currency for which the Surtur sold his watch is = $(13)_{5}$ 20)\u00a0Answer\u00a0(A)<\/strong><\/p>\n We need to calculate the remainder when $11^{105} + 13^{105}$ is divided by 144. 21)\u00a0Answer:\u00a0108<\/b><\/p>\n 215 = $ 6^{3} – 1$ Now we consider all the numbers upto greatest ‘n’ digit number in base 6. Then there will be total $n*6^n$ digits in total.<\/p>\n One-sixth of these digits will be digit ‘4’.<\/p>\n Thus the number of 4’s will be $\\frac{n*6^n}{6} = n*6^{n-1}$<\/p>\n Here for 215, n=3 as it is the greatest 3 digit number in base 6.<\/p>\n So number of 4’s are $3*6^2$ = 108<\/p>\n Hence 108 is the right answer.<\/p>\n 22)\u00a0Answer:\u00a01362<\/b><\/p>\n We see that the number when divided by 7 and 13, leaves a remainder of -3 in both cases.<\/p>\n Thus, the number should be of the form 91k – 3.<\/p>\n The number 91k – 3 when divided by 23 leaves a remainder of 5.<\/p>\n Thus 91k – 3 – 5 should be divisible by 23.<\/p>\n $Rem(\\frac{91k – 8}{23}) = 0$<\/p>\n $Rem(\\frac{92k – k – 8}{23}) = 0$<\/p>\n $Rem(\\frac{92k – (k + 8)}{23}) = 0$<\/p>\n Hence, k = 15 is one such number. 23)\u00a0Answer\u00a0(B)<\/strong><\/p>\n The rod is cut into 3 equal parts thus the length of the rod will be a multiple of 3. 24)\u00a0Answer\u00a0(C)<\/strong><\/p>\n It is given that sum of the first $(x – 1)$ numbers is equal to sum of the numbers from $(x + 1)$ to 49 25)\u00a0Answer\u00a0(B)<\/strong><\/p>\n Since the number leaves the same remainder on dividing both $6912$ and $7680$, the difference between them must be divisible by the number. 26)\u00a0Answer\u00a0(A)<\/strong><\/p>\n As it is given that $f < 1$, we know that $p<q$ and as $p+q=800$, it implies that $400 < q < 800$ Hence, we need to find the number of numbers between 400 and 800 which are not divisible by 2 and 5. 27)\u00a0Answer\u00a0(B)<\/strong><\/p>\n 28)\u00a0Answer:\u00a08<\/b><\/p>\n Let the two natural numbers in the question be $M$ and $N$ Or, $M = A \\times \\frac{100}{81}$ and $N = A \\times \\frac{50}{67}$<\/p>\n LCM of $67$ and $81$ is 5427.<\/p>\n It is given that $A$ is the smallest even natural number which satisfies the above conditions. Hence, $A$ = 5427 * 2 = 10854<\/p>\n It leaves a remainder of 8 when divided by 17.<\/p>\n 29)\u00a0Answer:\u00a06<\/b><\/p>\n The remainder when 325 divided by 9 is \u201c1\u201d. 30)\u00a0Answer:\u00a080<\/b><\/p>\n Let the two numbers be 7m and 7n where m and n are coprime. 31)\u00a0Answer\u00a0(A)<\/strong><\/p>\n Let $x$ be the two-digit number, $y$ be the three-digit number. Putting together the given, we have 32)\u00a0Answer:\u00a08<\/b><\/p>\n $24696 = 2^3*3^2*7^3$ 33)\u00a0Answer:\u00a015<\/b><\/p>\n \u2018k\u2019 represents the set of natural numbers which have odd number of factors. We know that the total number of factors is odd only for perfect squares. Hence \u2018k\u2019 is essentially the set of all perfect squares while m is the set of all odd natural numbers. 34)\u00a0Answer\u00a0(D)<\/strong><\/p>\n let $\\textrm{lmnopqr}$ be the number. 35)\u00a0Answer\u00a0(B)<\/strong><\/p>\n Given that there are 8 factors for $K$. There are 3 different cases in which 8 can be factorized into 36)\u00a0Answer\u00a0(C)<\/strong><\/p>\n $36288 = 2^6 * 3^4 * 7$ 37)\u00a0Answer\u00a0(A)<\/strong><\/p>\n If the unit digit of the cube is 4, the unit digit of the number must definitely be 4. 38)\u00a0Answer\u00a0(A)<\/strong><\/p>\n X on division by 7 leaves a remainder of 2. So X is of the form 7k+2 39)\u00a0Answer\u00a0(B)<\/strong><\/p>\n 34 = 17*2 40)\u00a0Answer:\u00a0801<\/b><\/p>\n To solve this problem, we will use the below property multiple times. $GCD_n = GCD(200+n^2,200+(n+1)^2) = GCD(200+n^2,200+n^2+2n+1)$
\nb) 34% greater than another natural number. What is the remainder when A is divided by 17? (Enter -1 if the answer can’t be determined)<\/p>\n
\nLet $GCD_n$ be the greatest common divisor of $S_n$ and $S_{n+1}$. Then, what is the maximum value of $GCD_n$<\/p>\n
\n$900900 = 2^2*3^2*5^2*7*11*13$
\nWe have to find the number odd factors = (1)*(2+1)*(2+1)*(1+1)*(1+1)*(1+1) = 72. Hence, option D is the correct answer.<\/p>\n
\n$1143072=2^5*3^6*7^2$<\/p>\n
\n$2! = 2, (2!)^2 = 4$
\n$3! = 3, (3!)^3 = 216$
\n$4! = 24, (4!)^4 = 331776$
\n$5! = 120, (5!)^5$ = term which ends with 0.
\nAny factorial greater than 5 will have at least 1 zero at the end.
\nAs the last term is $(100!)^{100}$, note that the sum of all the terms after $(4!)^4$ will be positive and ending with 0.
\nThus, no number greater than 4 will have any effect on the last digit of N.
\nThus, last digit of N = last digit of (-1+4-216+331776) = 3
\nThus, the last digit of $N^{100}$ = last digit of $3^{100}$
\n3 follows a cyclicity of 4 and thus, the last digit of $3^{100}$ will be the same as the last digit of $3^4 = 1$
\nHence, 1 is the correct answer.<\/p>\n
\nWe know that cyclicity of 8 is 4. Hence, we have to figure remainder that the exponent $79^{80}$ leaves when it is divided by 4.
\nRem.($\\dfrac{79^{80}}{4}$) = Rem.($\\dfrac{(80 – 1)^{80}}{4}$) = 1
\nHence, we can say that $79^{80}$ is a 4k+1 type number.
\nTherefore, we can write $78^{{79}^{80}}$ as $78^{4k+1}$.
\nThus, the unit digit of $78^{4k+1}$ will be 8. Hence, option A is the correct answer.<\/p>\n
\nFor a number to be a perfect square, all the powers of the prime factors have to be even.
\nHere, 2 can have its powers as 0,2,4 (3 cases)
\n3 can have its powers as 0,2,4(3 cases)
\n5 can have its powers as 0,2(2 cases)
\nNumber of possibilities = 3*3*2 = 18<\/p>\n
\nWe can see that the number becomes a perfect square when divided by 3. Therefore, the power of 3 in the number must be one among 1,3 or 5. ($3^7$ is a four digit number).<\/p>\n
\nWhen divided by 2, the remaining term must be a perfect cube. Therefore, the value of $b$ can only be 3.
\nWhen divided by 3, the remaining term must be a perfect square. Therefore, the value of $a$ can only be 4.
\nTherefore, the number is $2^4*3^3$ = $16*27$ = $432$.<\/p>\n
\n$\\Rightarrow [\\frac{20}{3}] + [\\frac{20}{3^2}]$ (Where [.] is a greatest integer function.)
\n$\\Rightarrow$ 6 + 2 = 8<\/p>\n
\n$\\Rightarrow [\\frac{17}{3}] + [\\frac{17}{3^2}]$
\n$\\Rightarrow$ 5 + 1 = 6<\/p>\n
\nHence, for maximum value of \u2018x\u2019 = 8*3 + 6*3 + 5*3 + 4*3 + 2*3 + 1*3 + 0*2 += 78 (Answer :C)<\/p>\n
\n(1, 1, 1, 1), (1, 1, 2), (2, 2), (3, 1), (4, 0)
\nIn case I (1, 1, 1, 1)
\nOne of the 1\u2019s will be at first place, the remaining 3 ones can be placed at any of the remaining 8 places. Hence, possible combinations will be 8C3 = 56
\nIn case 2(1, 1, 2)
\nIf the first digit is 1, then the remaining two can be placed in 8 positions in 8c2*2 = 56 ways
\nIf the first digit is 2, then the rest two can be placed in 8c2 = 28 ways.
\nHence, total possibilities in second case = 84
\nNow in case III,
\nFirst digit can be 3 or 1. The second digits can be placed n any of the remaining 8 possibilities. Hence, total possibilities = 8*2 = 16
\nIn case IV, there will only 8 possibilities.
\nIn case V, there will be only 1 possibility.
\nHence, the required number of ways = 56 + 84 + 16 + 8 + 1 = 165<\/p>\n
\nLCM = $(330)_{4}$ = $(60)_{10}$<\/p>\n
\nThe LCM of 112 and 42 is 336.
\nHence, we need to find the largest five digit number which is divisible by 336.
\nNote that 336*300 = 100800 and hence the largest five digit number which is divisible by 336 is 100800-3*336 = 99792<\/p>\n
\n=> xyzxyz = xyz*7*11*13
\n=> xyz has four factors so, xyz can be of the form $p^3$ where p is a prime number or, xyz can be of the form $a*b$, where a and b are prime numbers.
\nSo in case I, the total number of factors of xyzxyz will be
\n$ (3+1)*(1+1)*(1+1)*(1+1) = 32$, when xyz is not $7^3$
\nIf xyz = $7^3$, then total number of factors of xyzxyz will be given by
\n5*2*2 = 20.
\nThus, in case one the possible values are 20 and 32.
\nConsider case II, where xyz is a product of two prime numbers.
\nIn case xyz is co-prime to 7, 11 and 13 , the total number of factors of xyzxyz will be
\n$(1+1)*(1+1)*(1+1)*(1+1)*(1+1) = 32$
\nWe know that xyz = a*b where a and b are distinct primes. Now if one among a or b is equal to 7, 11 or 13, them the number of factors of xyzxyz will be
\n3*2*2*2 = 24.
\nIn case both ‘a’ and ‘b’ are chosen from 7, 11 and 13, then the number of factors of xyzxyz will be
\n(2+1)*(2+1)*2 = 18.
\nHence, the total possible number of factors of xyzxyz can be 18, 20, 24 or 32.
\nHence, the correct answer is option D.<\/p>\n
\nIt has been given that $q = 9p$.<\/p>\n
\n$p^{9p}=(9p)^p$
\n$(p^p)^9 = 9^p*p^p$
\n=> $(p^p)^8 = 9^p$
\n$p^{8p}=9^p$
\nRaising the power to $\\frac{1}{p}$ on both sides, we get,
\n$p^8=9$
\n$p=\\sqrt[8]{9}$.
\nTherefore, option D is the right answer.<\/p>\n
\nLet the 2 numbers be X and Y.
\nXY = $4*1008$
\n= $2^4*6^2*7$
\nWe know that one of the numbers has an odd number of factors. Therefore, one of the numbers must be a perfect square.<\/p>\n
\nTherefore, we cannot determine the 2 numbers. Option D is the right answer.<\/p>\n
\nSince the exponent of 2 in 53! Will definitely be greater than that of 5, it is sufficient to find the maximum power of 5 in 53!.<\/p>\n
\nnb + a = 2*(na + b)
\n(n-2)b = (2n – 1)a<\/p>\n
\nb = 5a<\/p>\n
\nHence, n=3 is not possible.<\/p>\n
\n2b = 7a<\/p>\n
\nHence, n=4 is not possible.<\/p>\n
\n3b = 9a
\nb = 3a<\/p>\n
\nAs, the base is 5, value of (a,b) = (2,6) and onwards is not possible.<\/p>\n
\nAlso, the only value of (a,b) which satisfies is (1,3)<\/p>\n
\nDecimal representation of this value = 5*1 + 3 = 8<\/p>\n
\nNote that this equals $(12-1)^{105} + (12+1)^{105}$ being divided by 144.
\n$(12-1)^{105}=12^{105} – 105\\times12^{104}+…+105\\times 12 -1$
\n$(12+1)^{105}=12^{105} + 105\\times12^{104}+…+105\\times 12 +1$
\nThe even terms of both the expressions cancel each other.
\nHence, the only term where the power of $12$ is less than 2 is $105 \\times 12 + 105\\times 12=210 \\times 12 = 2520$
\nThe remainder when this is divided by 144 is 72<\/p>\n
\nThus 215 is the largest 3 digit number in base 6.<\/p>\n
\n$Rem(\\frac{ k + 8}{23}) = 0$<\/p>\n
\nHence, the required number will be 91k – 3, which is 91*15 – 3 = 1362<\/p>\n
\nEach part is then cut into $12 = 2^2*3$
\n$18 = 2*3^2$ and $32 = 2^5$ parts and thus, each part of rod has to be a multiple of $2^5*3^2 = 288$
\nThus, the rod will be a multiple of $288*3 = 864$
\nThus, the minimum length of the rod is 864 units.
\nHence, option B is the correct answer.<\/p>\n
\nor, sum of $(x – 1)$ numbers = sum of first 49 numbers – sum of first $x$ numbers
\n$\\dfrac{x(x – 1)}{2} = \\dfrac{49 * 50}{2} – \\dfrac{x(x + 1)}{2}$
\nOn solving, we get $x$ = 35
\nHence, option C is the correct answer.<\/p>\n
\n$9216 – 6912 = 2304$
\nThe greatest possible value of ‘n’ is 2304.
\n$2304 = 9*256 $
\n$= 3^2 * 2^8$
\nNow, $6$ can be split as $3*2.$
\n$3^2*2^8, 3^2*2^5, 3^2*2^2$ will become a perfect cube on multiplying by $6.$
\n$3^1*2^1, 3^1*2^3, 3^1*2^5$ and $ 3^1*2^7$will become a perfect square on multiplying by $6.$
\nHence, there are $7$ factors in total.<\/p>\n
\n<\/q>Note that $800 = 2^5 \\times 5^2$
\nHence, $p$ and $q$ will be relatively prime if $q$ is not divisible by either 2 or 5. Note that in this case, even $p$ will not be divisible by $2$ or $5$.<\/p>\n
\nThe total number of numbers between 400 and 800 is 399.
\nThe number of such numbers which are divisible by 2 is 199.
\nThe number of such numbers which are divisible by 5 is 79.
\nThe number of such numbers which are divisible by 10 is 39.
\nHence, the required number is 399-199-79+39 = 160.<\/p>\n
\nTherefore, $M \\times \\frac{81}{100} = A$
\nand, $N \\times \\frac{134}{100} = A$<\/p>\n
\nThe remainder when 326 divided by 9 is \u201c2\u201d.
\nFor any value of \u2018n\u2019 the remainder when $325^n$ divided by 9 will be 1.
\nThe remainder when $326^n$ divided by 9 should be 1 for to be equal.
\n326mod9 = 2
\nThe remainder when $326^n$ divided by 9 is equal to the remainder when $2^n$ divided by 9
\nThe least value at which the remainder is 1 is for n = 6.<\/p>\n
\nSo we have
\n7m + 7n = 1540
\n=> m + n = 1540\/7 = 220
\nSo we have to write 220 as the sum of two co-prime numbers.
\nTotal numbers below 220 which are also co-prime to 220 are given by the euler no. of 220 = $220*\\frac{1}{2}*\\frac{4}{5}*\\frac{10}{11}$ = 80.
\nFor each of these numbers, there will be a corresponding number such that the sum is 220. For example, 3 + 217, 7 + 213, 13 + 207 and so on.
\nSince the question asks for ordered pairs so both a and b can take 80 values each. Hence the required answer is 80.<\/p>\n
\n$1000x + y = 9xy$
\n$\\Rightarrow$ $9xy – 1000x – y = 0$
\n$\\Rightarrow$ $(9x – 1)(y – \\dfrac{1000}{9})$ = $\\dfrac{1000}{9}$
\n$\\Rightarrow$ $(9x – 1)(9y – 1000) = 1000$
\nWe know that $x$ is a two digit number hence 89 $\\leq$ (9x – 1) $\\leq$ 890.
\nHence, we have to check the solution for every divisor of 1000 which is greater than 89 and less than 890.
\nDivisors of 1000, which are greater than 89 and less than 890 = (100, 125, 200, 250, 500)
\nWe can see that only at (9x – 1) = 125, (9y – 1000) = 8
\ni.e. y = 112 also (9x – 1) = 125, i.e. x = 14
\nFor any other value of (9x – 1) we get non integer values of y which is not possible because y is a three digit number.
\nHence, the required sum = x + y = 14 + 112 = 126.
\nTherefore, option A is the correct answer.<\/p>\n
\nAll factors of 24696 are in the form of $2^a * 3^b * 7^c$
\nTo be a perfect square, a can take values 0,2
\nb can take values 0,2
\nc can take values 0,2
\nTherefore, total number of factors of 24696 which are perfect squares = 2*2*2 = 8<\/p>\n
\n$0 \\leq k \\leq 1000$
\nThe number of perfect squares between 1 and 1000 = 31 {Since $32^2 = 1024$
\nOut of these 31, 15 will be even numbers ($2^2, 4^2, 6^2, 8^2, 10^2 . . . . . . 30^2$)
\nThe remaining 16 will be odd ($1^2, 3^2, 5^2, 7^2, 9^2 . . . . . . .31^2$)
\nHowever, we know that $0 \\leq m \\leq 900$. Hence, $31^2$ will be outside the range of m. Hence $k \\cap m$ will only have 15 elements.<\/p>\n
\nEach of the digits can take a value between 0 and 9. So let
\nl = 9 – a, m = 9 – b, n = 9 – c, o = 9 – d, p = 9 – e, q = 9 – f, r = 9 – g
\nWe have been given that
\nl + m + n + o + p + q + r = 55
\n=> 9 – a + 9 – b + 9 – c + 9 – d + 9 – e + 9 – f + 9 – g = 55. (Here, b, c, d, e, f, g are non negative integers less than or equal to 9 and a is a non negative integer less than or equal to 8)
\n=> a + b + c + d + e + f + g = 8
\nThe, number of non negative solutions for this equation can be obtained by using the formula (n+r-1)C(r-1)
\nSo the required number of solutions would be (8+7-1)C(7-1) = 14C6 = 3003.
\nHence $3003$ seven digit numbers are there with a digit sum of 55.<\/p>\n
\nCase 1: $(1+1)*(1+1)*(1+1) =8$
\nWhen K is squared all its factors are also squared , number of factors of $K^2 = (2+1)(2+1)(2+1) = 27$
\nCase $2: (1+1)*(3+1) = 8$
\nNumber of factors of $K^2 = (2+1)(6+1) = 21$
\nCase 3:
\n$1*(7+1) = 8$
\nNumber of factors of $K^2 = (14+1) =15$<\/p>\n
\nFor any perfect cube, all the powers of its prime numbers have to be multiples of 3.
\nSo, if the factor is of form $2^a * 3^b * 7^c$, a can take values 0, 3, 6
\nAnd b can take values 0, 3
\nAnd c can take value 0.
\n==> There are 3*2*1 = 6 possibilities.<\/p>\n
\n=> The number must be of the form \u2018abc4\u2019
\nSince a and b are the thousandth and the hundredth digit number, they won\u2019t contribute to the tens digit number of the cube. Let us find how many values c can assume.
\n$(10c+4)^3$ gives 44 in the end.
\n=> $1000c^3 + 64 + 400c^2 + 480c $ ends in 44.
\nAgain $1000c^3$ and $400c^2$ won\u2019t contribute to the last 2 digits.
\n=> 64+80c ends in 44. This only happens when c=1 or c=6
\n=> a can assume 1-9 i.e 9 values, b can assume 0-9 i.e. 10 values, and c can assume 2 values. Total numbers= 180.<\/p>\n
\nSame number on division by 19 leaves a remainder of 1, So X is also of the form 19m + 1
\nThus
\n7k+2 = 19m + 1
\nIf we put m = 3, we get a number which is of the form 7k+2. Thus the smallest number which fits the given criteria is 19*3+1 =58
\nWhen 58 is divided by 23, the remainder would be 12.<\/p>\n
\nSo we have to find the highest power of 17 in 2000!. We need not find the power of 2 because of 2 will be greater than the power of 17. Thus the power of 17 will act as the limiting value.
\nThus the highest power of 17 in 2000! is
\n[2000\/17] + [ 2000\/289] + [2000\/4913], [] is greatest integer function
\n= 117 + 6 + 0 = 123
\nThus the required number of zeroes is 123.<\/p>\n
\n$GCD(a,b) = GCD(a-k*b,b)$ for any integer $k$.<\/p>\n
\nTherefore, $GCD_n = GCD(200+n^2,2n+1) = GCD(400+2n^2,2n+1)$
\nTherefore, $GCD_n = GCD(400+2n^2 -n*(2n+1),2n+1) = GCD(400-n,2n+1)$
\nTherefore, $GCD_n = GCD(800-2n,2n+1) = GCD(801,2n+1)$
\nHence, the maximum value of $GCD_n = 801$ when $2n+1 = 801$ or $n=400$<\/p>\n