‘Idli-vada’ is said at common multiples of $3$ and $5$, that is multiples of $15$. The $10$th such number is $10\times15=150$.
$150$.
From $1$ to $90$, multiples of $3$ are $\lfloor90/3\rfloor=30$, multiples of $5$ are $\lfloor90/5\rfloor=18$, and common multiples of $3$ and $5$ are multiples of $15$, giving $\lfloor90/15\rfloor=6$.
a. $30$ times; b. $18$ times; c. $6$ times.
Use the same counting rule up to $900$: $\lfloor900/3\rfloor=300$, $\lfloor900/5\rfloor=180$, and $\lfloor900/15\rfloor=60$.
‘Idli’ would be said $300$ times, ‘vada’ $180$ times, and ‘idli-vada’ $60$ times.
The overlapping region of the figure represents common multiples. In the game, those common multiples are exactly the numbers where ‘idli-vada’ is said.
Yes.
If one number is $4$ and nobody says just ‘vada’, every multiple of the other number must also be a multiple of $4$. Among the given choices, $8$ has this property for the game context.
$8$.
A jump size that reaches both numbers must be a common factor of $15$ and $30$. The factors of $15$ are $1,3,5,15$, and all four also divide $30$.
$1,3,5,$ and $15$.
The shaded entries follow the pattern of multiples of $3$ in the table.
Yes, all shaded numbers are multiples of $3$.
The circled entries follow the pattern of multiples of $4$ in the table.
Yes, all circled numbers are multiples of $4$.
Numbers that are both shaded and circled are divisible by both $3$ and $4$. In the shown range, these are $36,48,$ and $60$.
$36,48,$ and $60$; they are common multiples of $3$ and $4$.
Multiples of $40$ near the range are $40\times7=280$, $40\times8=320$, $40\times9=360$, $40\times10=400$, and $40\times11=440$. Those between $310$ and $410$ are $320,360,400$.
$320,360,$ and $400$.
For a, multiples of $7$ below $40$ are $7,14,21,28,35$; only $35$ has digit sum $8$. For b, the number must be a multiple of $15$ below $100$; $45$ has digits differing by $1$.
a. $35$; b. $45$.
The factors of $6$ are $1,2,3,6$. Their sum is $1+2+3+6=12=2\times6$, so $6$ is perfect.
$6$.
List the factors of each number and keep only the factors common to all numbers in that part.
a. $1,2,4$; b. $1,5$; c. $1,2,4$; d. $1,5$.
Odd multiples of $25$ are not multiples of $50$. Examples are $25\times1=25$, $25\times3=75$, and $25\times5=125$.
$25,75,$ and $125$.
The first ‘idli-vada’ is the least common multiple of the two numbers. For $(7,8)$ it is $56$, for $(7,9)$ it is $63$, and for $(8,9)$ it is $72$, all after $50$.
Possible pairs are $(7,8)$, $(7,9)$, and $(8,9)$.
The possible jump sizes are the common factors of $28$ and $70$. Since $28=2\times2\times7$ and $70=2\times5\times7$, the common factors are $1,2,7,14$.
$1,2,7,$ and $14$.
Use the required prime powers for $1,2,3,4,5,6,8,9,10$: $2^3$ from $8$, $3^2$ from $9$, and $5$ from $5$ or $10$. Thus the smallest number is $2^3\times3^2\times5=8\times9\times5=360$.
$360$.
The least common multiple of $1$ to $10$ uses prime powers $2^3,3^2,5,$ and $7$. Therefore $2^3\times3^2\times5\times7=8\times9\times5\times7=2520$.
$2520$.
The primes from $21$ to $30$ are $23$ and $29$. The remaining eight numbers are composite.
$2$ prime numbers and $8$ composite numbers.
Every even number greater than $2$ is divisible by $2$ and has more than two factors, so it is composite.
No.
The smallest gap occurs between $2$ and $3$: $3-2=1$. The largest gap among successive primes below $100$ occurs between $89$ and $97$: $97-89=8$.
Smallest difference: $1$; largest difference: $8$.
Count the primes in each decade of the table. The counts are not equal across rows.
No. The decade $91$ to $100$ has the least number of primes. The decades $1$ to $10$ and $11$ to $20$ have the most.
$23$ and $37$ have no factors other than $1$ and themselves. $51=3\times17$ and $26=2\times13$ are composite.
$23$ and $37$.
$2+3=5$, $3+7=10$, and $2+13=15$, all multiples of $5$.
Examples: $(2,3)$, $(3,7)$, and $(2,13)$.
Each pair uses the same two digits in reverse order, and both numbers in each pair are prime.
$(17,71)$, $(37,73)$, and $(79,97)$.
Each of these seven numbers is composite: $90,92,94,96$ are even, $91=7\times13$, $93=3\times31$, and $95=5\times19$.
$90,91,92,93,94,95,96$.
Check consecutive prime pairs below $100$ and select the pairs whose difference is $2$.
$(3,5)$, $(5,7)$, $(11,13)$, $(17,19)$, $(29,31)$, $(41,43)$, $(59,61)$, and $(71,73)$.
a. A number ending in $4$ is even and greater than $2$, so it is composite. b. A product of primes has those primes as factors, so it is composite. c. A prime has exactly two factors, $1$ and itself. d. $2$ is even and prime. e. After any odd prime, the next number is even and greater than $2$, hence composite.
a. True; b. False; c. False; d. False; e. True.
Any number ending in $2$ or $4$ is even, and any number ending in $5$ is divisible by $5$. Since each arrangement ends in $2$, $4$, or $5$, no arrangement is prime.
None.
For each prime $p$, compute $2p+1$: $2\times5+1=11$, $2\times11+1=23$, $2\times23+1=47$, $2\times29+1=59$, and $2\times41+1=83$, all prime.
Yes. Examples are $5\to11$, $11\to23$, $23\to47$, $29\to59$, and $41\to83$.
A pair is safe when the two numbers are co-prime, so no jump size greater than $1$ reaches both. $4$ and $15$ share no factor greater than $1$, and $18$ and $29$ share no factor greater than $1$.
The safe pairs are $4$ and $15$, and $18$ and $29$.
Each listed co-prime pair has no common factor greater than $1$. The pairs $30$ and $415$ share $5$, and $81$ and $18$ share $9$, so they are not co-prime.
a. $18$ and $35$; b. $15$ and $37$; d. $17$ and $69$.
For co-prime pairs, the first common multiple is the product of the two numbers. For pairs with a common factor greater than $1$, the first common multiple is less than the product.
Examples for case 1: $(3,5)$, $(3,7)$, $(4,9)$. Examples for case 2: $(3,6)$, $(3,12)$, $(6,15)$.
Divide each number successively by prime factors until only primes remain. The listed products multiply back to the original numbers.
$64=2^6$; $104=2^3\times13$; $105=3\times5\times7$; $243=3^5$; $320=2^6\times5$; $141=3\times47$; $1728=2^6\times3^3$; $729=3^6$; $1024=2^{10}$; $1331=11^3$; $1000=2^3\times5^3$.
The number is $2\times3\times3\times11=198$.
$198$.
$1955\div5=391$, and $391=17\times23$. Thus $1955=5\times17\times23$, with all three primes less than $30$.
$5,17,$ and $23$.
Factor each component first: $56=2^3\times7$, $25=5^2$; $108=2^2\times3^3$, $75=3\times5^2$; $1000=2^3\times5^3$, $81=3^4$.
a. $2^3\times5^2\times7$; b. $2^2\times3^4\times5^2$; c. $2^3\times3^4\times5^3$.
For the smallest such numbers, use the smallest different primes. Three different primes give $2\times3\times5=30$; four different primes give $2\times3\times5\times7=210$.
a. $30$; b. $210$.
$30=2\times3\times5$ and $45=3^2\times5$ share factors. $57=3\times19$ and $85=5\times17$ share none. $121=11^2$ and $1331=11^3$ share $11$. $343=7^3$ and $216=2^3\times3^3$ share none.
a. No; b. Yes; c. No; d. Yes.
$225=3^2\times5^2$ does not contain $27=3^3$. $96=2^5\times3$ contains $24=2^3\times3$. $343=7^3$ does not contain factor $17$. $999=3^3\times37$ does not contain $99=3^2\times11$.
a. No; b. Yes; c. No; d. No.
Both numbers share factors $3$ and $7$, so they are not co-prime. The first has factor $2$ which the second lacks, and the second has factor $11$ which the first lacks, so neither prime factorisation is contained in the other.
They are not co-prime, and neither divides the other.
Two distinct primes have no common factor other than $1$, so they are co-prime. For example, $2$ and $3$, or $3$ and $11$.
Yes, if the two prime numbers are distinct.
Only the last two digits need to be checked for divisibility by $4$. Since $36$ is divisible by $4$, $8536$ is divisible by $4$.
Yes.
Any whole number can be split as a multiple of $100$ plus its last two digits. Since $100$ is divisible by $4$, divisibility by $4$ depends only on the number formed by the last two digits.
Yes, all three statements are true.
The numbers in each range whose last three digits form a multiple of $8$ are listed. This suggests that the last three digits decide divisibility by $8$.
$128,136$; $1128,1136$; $3128,3136$.
$8552\div8=1069$, so $8552$ is a multiple of $8$.
One possible answer is $8552$.
Any whole number can be split as a multiple of $1000$ plus its last three digits. Since $1000$ is divisible by $8$, divisibility by $8$ depends only on the number formed by the last three digits.
Yes, all three statements are true.
For part b, count multiples of $4$ from $2024$ through $2099$: $2024,2028,\ldots,2096$. This arithmetic sequence has $((2096-2024)/4)+1=19$ terms. The year $2100$ is outside the range.
a. The answer depends on the student's birth year. b. $19$ leap years.
For even numbers, $2+6=8$ is a multiple of $4$, but $2+4=6$ is not. For odd numbers, $1+3=4$ is a multiple of $4$, but $1+5=6$ is not.
a. Sometimes true; b. Sometimes true.
For division by $10$, the remainder is the last digit. For division by $5$, reduce the last digit modulo $5$. For division by $2$, even numbers have remainder $0$ and odd numbers have remainder $1$.
For division by $10$: $8,9,3,2,0,1,5$; by $5$: $3,4,3,2,0,1,0$; by $2$: $0,1,1,0,0,1,1$.
If a number is divisible by $8$, it is divisible by $2$ and $4$. If it is also divisible by $5$, then being even makes it divisible by $10$. Since $14560$ is divisible by both $5$ and $8$, it is divisible by all five numbers.
$5$ and $8$.
A number divisible by all of $2,4,5,8,10$ must be divisible by $8$ and end in $0$. The numbers $5600$, $6000$, and $77622160$ satisfy this; $572$ and $2352$ do not end in $0$.
$5600,6000,$ and $77622160$.
$16\times625=10000$, and neither $16$ nor $625$ has $0$ as its units digit.
$16$ and $625$.