Arithmetic Progressions

1. Patterns around us — why this chapter exists

Nature and daily life are full of patterns: petals of a sunflower, holes of a honeycomb, spirals on a pine cone. NCERT opens with everyday lists:

• A salary of $\rupee$8000 rising by $\rupee$500 a year: $8000,\ 8500,\ 9000,\dots$
• Ladder-rung lengths dropping by 2 cm: $45,\ 43,\ 41,\ 39,\dots$
• Savings of $\rupee$100 increased by $\rupee$50 each birthday: $100,\ 150,\ 200,\ 250,\dots$

In each, the next term comes from the previous by adding a fixed number. Lists like this are Arithmetic Progressions. Some other lists (areas of squares $1^2,2^2,3^2,\dots$ or the rabbit/Fibonacci list $1,1,2,3,5,8,\dots$) are not APs — they grow by a different rule. This chapter studies only the "add a fixed number" pattern, learns to find its $n$th term and the sum of $n$ terms, and uses these in word problems.

2. Definition of an AP and the common difference

An arithmetic progression is a list of numbers in which each term is obtained by adding a fixed number to the preceding term — except the first term. That fixed number is the common difference, written $d$. It can be positive, negative or zero.

Denote the terms $a_1,a_2,a_3,\dots,a_n$. Then by definition:

Look at NCERT's sample lists:

• $1,2,3,4,\dots$ — each term is $1$ more than before, so $d=1$.
• $100,70,40,10,\dots$ — each is $30$ less, so $d=-30$.
• $-3,-2,-1,0,\dots$ — add $1$ each time, $d=1$.
• $3,3,3,3,\dots$ — add $0$ each time, $d=0$ (a constant AP).
• $-1.0,-1.5,-2.0,-2.5,\dots$ — subtract $0.5$, so $d=-0.5$.

Caution: to find $d$, always subtract a term from the term that follows it: $d=a_{k+1}-a_k$. For $6,3,0,-3,\dots$ we compute $3-6=-3$, not $6-3$, even though the later term is smaller.

3. General form, finite vs infinite, and how to test an AP

If the first term is $a$ and the common difference is $d$, the AP is:

This is the general form. So to know an AP completely you need both $a$ and $d$. For example $a=6,d=3$ gives $6,9,12,15,\dots$ while $a=6,d=-3$ gives $6,3,0,-3,\dots$

• An AP with a last term is finite (e.g. heights $147,148,\dots,157$).
• An AP that never ends is infinite (e.g. $1,2,3,4,\dots$).

To test whether a list is an AP: compute consecutive differences $a_2-a_1,\ a_3-a_2,\ a_4-a_3,\dots$ If they are all equal, it is an AP; otherwise it is not. (You only need to confirm the difference is the same throughout — one mismatch disqualifies it.) The list $1,1,2,3,5,\dots$ fails this test, so it is not an AP.

4. First worked examples on identifying an AP

5. The nth term of an AP

Suppose Reena's salary starts at $\rupee$8000 and rises by $\rupee$500 a year. The pattern is:

The coefficient of $d$ is always one less than the term number. So the $n$th term (also called the general term) is:

If the AP is finite with $m$ terms, the last term $a_m$ is often written $l$, so $l=a+(m-1)d$. This one formula handles "find a given term", "which term equals…", and "is this number in the AP?" type questions.

6. More nth-term examples — membership and last-term tricks

7. Sum of the first n terms of an AP

Young Gauss summed $1+2+\dots+100$ by writing the sum forwards and backwards and adding:

The same pairing trick on $a,\ a+d,\ a+2d,\dots$ gives the general result. Writing $S$ forwards and backwards and adding term-wise, each of the $n$ pairs equals $2a+(n-1)d$, so $2S=n[2a+(n-1)d]$, hence:

Since $a+(n-1)d=a_n$ (the last term), we can also write:

The second form is handy when the first and last terms are known but $d$ is not. The formula links four quantities $S_n,\ a,\ d,\ n$ (or $a_n$) — given any three you can find the fourth. A useful link between sum and term:

8. Worked examples on sums

9. Arithmetic mean

From NCERT's "Note to the reader": if $a,b,c$ are in AP, the middle term is the arithmetic mean of the other two:

This is just the AP condition $b-a=c-b$ rearranged. It is a quick way to insert a term between two given numbers, or to check three numbers form an AP.

10. NCERT Exercise 5.1 — fully solved

Q1. Is it an AP?

• (i) Taxi fare $\rupee15$ first km, $\rupee8$ each extra km: $15,23,31,\dots$ — $d=8$ constant, AP.
• (ii) Vacuum removes $\tfrac14$ of remaining air: each term is $\tfrac34$ of the previous (multiplied, not added) — not an AP.
• (iii) Digging cost $\rupee150$ first metre, rising $\rupee50$ each metre: $150,200,250,\dots$ — $d=50$, AP.
• (iv) $\rupee10000$ at $8\%$ compound interest yearly: amount multiplies by $1.08$ each year — not an AP.

Q2. First four terms.

• (i) $a=10,d=10$: $10,20,30,40$.
• (ii) $a=-2,d=0$: $-2,-2,-2,-2$.
• (iii) $a=4,d=-3$: $4,1,-2,-5$.
• (iv) $a=-1,d=\tfrac12$: $-1,-\tfrac12,0,\tfrac12$.
• (v) $a=-1.25,d=-0.25$: $-1.25,-1.50,-1.75,-2.00$.

Q3. First term and common difference.

• (i) $3,1,-1,-3,\dots$: $a=3,\ d=-2$.
• (ii) $-5,-1,3,7,\dots$: $a=-5,\ d=4$.
• (iii) $\tfrac13,\tfrac53,\tfrac93,\tfrac{13}{3},\dots$: $a=\tfrac13,\ d=\tfrac43$.
• (iv) $0.6,1.7,2.8,3.9,\dots$: $a=0.6,\ d=1.1$.

Q4. Which form an AP? give $d$ and three more terms.

• (i) $2,4,8,16,\dots$: $4-2=2$ but $8-4=4$ — not an AP.
• (ii) $2,\tfrac52,3,\tfrac72,\dots$: $d=\tfrac12$, AP; next $4,\tfrac92,5$.
• (iii) $-1.2,-3.2,-5.2,-7.2,\dots$: $d=-2$, AP; next $-9.2,-11.2,-13.2$.
• (iv) $-10,-6,-2,2,\dots$: $d=4$, AP; next $6,10,14$.
• (v) $3,\ 3+\sqrt2,\ 3+2\sqrt2,\ 3+3\sqrt2,\dots$: $d=\sqrt2$, AP; next $3+4\sqrt2,3+5\sqrt2,3+6\sqrt2$.
• (vi) $0.2,0.22,0.222,0.2222,\dots$: differences $0.02,0.002,\dots$ vary — not an AP.
• (vii) $0,-4,-8,-12,\dots$: $d=-4$, AP; next $-16,-20,-24$.
• (viii) $-\tfrac12,-\tfrac12,-\tfrac12,-\tfrac12,\dots$: $d=0$, AP; next $-\tfrac12,-\tfrac12,-\tfrac12$.
• (ix) $1,3,9,27,\dots$: ratios constant, not differences — not an AP.
• (x) $a,2a,3a,4a,\dots$: $d=a$, AP; next $5a,6a,7a$.
• (xi) $a,a^2,a^3,a^4,\dots$: $a^2-a\neq a^3-a^2$ in general — not an AP.
• (xii) $\sqrt2,\sqrt8,\sqrt{18},\sqrt{32},\dots=\sqrt2,2\sqrt2,3\sqrt2,4\sqrt2,\dots$: $d=\sqrt2$, AP; next $5\sqrt2,6\sqrt2,7\sqrt2$ i.e. $\sqrt{50},\sqrt{72},\sqrt{98}$.
• (xiii) $\sqrt3,\sqrt6,\sqrt9,\sqrt{12},\dots$: $\sqrt6-\sqrt3\neq\sqrt9-\sqrt6$ — not an AP.
• (xiv) $1^2,3^2,5^2,7^2,\dots=1,9,25,49,\dots$: differences $8,16,24$ vary — not an AP.
• (xv) $1^2,5^2,7^2,73,\dots=1,25,49,73,\dots$: differences $24,24,24$ — AP with $d=24$; next $97,121,145$.

11. NCERT Exercise 5.2 — fully solved

Q1. Fill the blanks (using $a_n=a+(n-1)d$).

• (i) $a=7,d=3,n=8$: $a_8=7+7\times3=28$.
• (ii) $a=-18,n=10,a_{10}=0$: $0=-18+9d\Rightarrow d=2$.
• (iii) $d=-3,n=18,a_{18}=-5$: $-5=a+17(-3)\Rightarrow a=46$.
• (iv) $a=-18.9,d=2.5,a_n=3.6$: $3.6=-18.9+(n-1)2.5\Rightarrow 22.5=(n-1)2.5\Rightarrow n=10$.
• (v) $a=3.5,d=0,n=105$: $a_{105}=3.5+104\times0=3.5$.

Q2. Choose correct option.

• (i) 30th term of $10,7,4,\dots$: $a=10,d=-3$; $a_{30}=10+29(-3)=-77$. Answer (C).
• (ii) 11th term of $-3,-\tfrac12,2,\dots$: $a=-3,d=\tfrac52$; $a_{11}=-3+10\times\tfrac52=22$. Answer (B).

Q3. Missing terms.

• (i) $2,\_,26$: middle $=\tfrac{2+26}{2}=14$.
• (ii) $\_,13,\_,3$: here $a_2=13,a_4=3\Rightarrow 2d=-10\Rightarrow d=-5$; so $a=18$ and $a_3=8$. Terms $18,13,8,3$.
• (iii) $5,\_,\_,9\tfrac12$: $a=5,a_4=\tfrac{19}{2}\Rightarrow 3d=\tfrac{9}{2}\Rightarrow d=\tfrac32$; terms $5,\tfrac{13}{2},8,\tfrac{19}{2}$.
• (iv) $-4,\_,\_,\_,\_,6$: $a=-4,a_6=6\Rightarrow 5d=10\Rightarrow d=2$; terms $-4,-2,0,2,4,6$.
• (v) $\_,38,\_,\_,\_,-22$: $a_2=38,a_6=-22\Rightarrow 4d=-60\Rightarrow d=-15$; $a=53$; terms $53,38,23,8,-7,-22$.

Q4. Which term of $3,8,13,18,\dots$ is $78$? $a=3,d=5$; $78=3+(n-1)5\Rightarrow 75=5(n-1)\Rightarrow n=16$.

Q5. Number of terms.

• (i) $7,13,19,\dots,205$: $a=7,d=6$; $205=7+(n-1)6\Rightarrow n=34$.
• (ii) $18,15\tfrac12,13,\dots,-47$: $a=18,d=-\tfrac52$; $-47=18+(n-1)(-\tfrac52)\Rightarrow n=27$.

Q6. Is $-150$ a term of $11,8,5,2,\dots$? $a=11,d=-3$; $-150=11+(n-1)(-3)\Rightarrow n=\tfrac{164}{3}+1$, not an integer — no.

Q7. 11th term $=38$, 16th $=73$. $a+10d=38,\ a+15d=73\Rightarrow 5d=35\Rightarrow d=7,\ a=-32$. So $a_{31}=-32+30\times7=178$.

Q8. 50-term AP, 3rd term $12$, last ($a_{50}$) $=106$. $a+2d=12,\ a+49d=106\Rightarrow 47d=94\Rightarrow d=2,\ a=8$. Then $a_{29}=8+28\times2=64$.

Q9. 3rd term $4$, 9th term $-8$. $a+2d=4,\ a+8d=-8\Rightarrow 6d=-12\Rightarrow d=-2,\ a=8$. Zero term: $8+(n-1)(-2)=0\Rightarrow n=5$. The 5th term is zero.

Q10. $a_{17}=a_{10}+7\Rightarrow (a+16d)-(a+9d)=7\Rightarrow 7d=7\Rightarrow d=1$.

Q11. $3,15,27,39,\dots$: $a=3,d=12$. We need $a_n=a_{54}+132$. $a_{54}=3+53\times12=639$, so $a_n=771$; $771=3+(n-1)12\Rightarrow n=65$. The 65th term.

Q12. Two APs with the same $d$; difference of 100th terms is $100$. Since both share $d$, $a_n-b_n=a-b$ is constant, so $a-b=100$. Difference of 1000th terms is also 100.

Q13. Three-digit multiples of $7$: $105,112,\dots,994$; $a=105,d=7$; $994=105+(n-1)7\Rightarrow n=128$.

Q14. Multiples of $4$ between $10$ and $250$: $12,16,\dots,248$; $a=12,d=4$; $248=12+(n-1)4\Rightarrow n=60$.

Q15. $63,65,67,\dots$ has $a=63,d=2$; $3,10,17,\dots$ has $a=3,d=7$. Equal $n$th terms: $63+(n-1)2=3+(n-1)7\Rightarrow 60=5(n-1)\Rightarrow n=13$.

Q16. 3rd term $16$ and $a_7=a_5+12$. $a+2d=16$; $a_7-a_5=2d=12\Rightarrow d=6$, so $a=16-12=4$. AP: $4,10,16,22,\dots$

Q17. 20th term from the last of $3,8,13,\dots,253$. $a=3,d=5,l=253$; from the last $a=253,d=-5$: 20th $=253+19(-5)=158$.

Q18. $a_4+a_8=24$ and $a_6+a_{10}=44$. $(a+3d)+(a+7d)=2a+10d=24$; $(a+5d)+(a+9d)=2a+14d=44$. Subtract: $4d=20\Rightarrow d=5$, then $2a+50=24\Rightarrow a=-13$. First three terms: $-13,-8,-3$.

Q19. Salary $\rupee5000$ in 1995, rising $\rupee200$/year, reaching $\rupee7000$. $7000=5000+(n-1)200\Rightarrow n-1=10\Rightarrow n=11$. Year $=1995+10=$ 2005.

Q20. Weekly saving $\rupee5$, rising $\rupee1.75$, becomes $\rupee20.75$. $20.75=5+(n-1)1.75\Rightarrow 15.75=(n-1)1.75\Rightarrow n-1=9\Rightarrow n=10$.

12. NCERT Exercise 5.3 — fully solved

Q1. Find the sums.

• (i) $2,7,12,\dots$ to 10 terms: $a=2,d=5$; $S_{10}=\tfrac{10}{2}[4+9\times5]=5\times49=245$.
• (ii) $-37,-33,-29,\dots$ to 12 terms: $a=-37,d=4$; $S_{12}=\tfrac{12}{2}[-74+11\times4]=6(-30)=-180$.
• (iii) $0.6,1.7,2.8,\dots$ to 100 terms: $a=0.6,d=1.1$; $S_{100}=\tfrac{100}{2}[1.2+99\times1.1]=50(1.2+108.9)=50\times110.1=5505$.
• (iv) $\tfrac{1}{15},\tfrac{1}{12},\tfrac{1}{10},\dots$ to 11 terms: $a=\tfrac{1}{15},d=\tfrac{1}{12}-\tfrac{1}{15}=\tfrac{1}{60}$; $S_{11}=\tfrac{11}{2}[\tfrac{2}{15}+10\cdot\tfrac{1}{60}]=\tfrac{11}{2}[\tfrac{8}{60}+\tfrac{10}{60}]=\tfrac{11}{2}\cdot\tfrac{18}{60}=\tfrac{33}{20}$.

Q2. Sums of given series.

• (i) $7+10\tfrac12+14+\dots+84$: $a=7,d=\tfrac72,l=84$; $84=7+(n-1)\tfrac72\Rightarrow n=23$; $S=\tfrac{23}{2}(7+84)=\tfrac{23}{2}\times91=\tfrac{2093}{2}=1046\tfrac12$.
• (ii) $34+32+30+\dots+10$: $a=34,d=-2,l=10$; $10=34+(n-1)(-2)\Rightarrow n=13$; $S=\tfrac{13}{2}(34+10)=\tfrac{13}{2}\times44=286$.
• (iii) $-5+(-8)+(-11)+\dots+(-230)$: $a=-5,d=-3,l=-230$; $-230=-5+(n-1)(-3)\Rightarrow n=76$; $S=\tfrac{76}{2}(-5-230)=38\times(-235)=-8930$.

Q3. In an AP.

• (i) $a=5,d=3,a_n=50$: $50=5+(n-1)3\Rightarrow n=16$; $S_{16}=\tfrac{16}{2}(5+50)=8\times55=440$.
• (ii) $a=7,a_{13}=35$: $35=7+12d\Rightarrow d=\tfrac{7}{3}$; $S_{13}=\tfrac{13}{2}(7+35)=\tfrac{13}{2}\times42=273$.
• (iii) $a_{12}=37,d=3$: $37=a+11\times3\Rightarrow a=4$; $S_{12}=\tfrac{12}{2}(4+37)=6\times41=246$.
• (iv) $a_3=15,S_{10}=125$: $a+2d=15$; $S_{10}=5(2a+9d)=125\Rightarrow 2a+9d=25$. Solve: from $a=15-2d$, $30-4d+9d=25\Rightarrow 5d=-5\Rightarrow d=-1,\ a=17$; $a_{10}=17+9(-1)=8$.
• (v) $d=5,S_9=75$: $S_9=\tfrac{9}{2}(2a+8\times5)=75\Rightarrow 2a+40=\tfrac{150}{9}=\tfrac{50}{3}\Rightarrow a=\tfrac{50/3-40}{2}=-\tfrac{35}{3}$; $a_9=a+8\times5=-\tfrac{35}{3}+40=\tfrac{85}{3}$.
• (vi) $a=2,d=8,S_n=90$: $90=\tfrac{n}{2}[4+(n-1)8]\Rightarrow 180=4n+8n^2-8n\Rightarrow 8n^2-4n-180=0\Rightarrow 2n^2-n-45=0\Rightarrow(2n+9)(n-5)=0\Rightarrow n=5$; $a_5=2+4\times8=34$.
• (vii) $a=8,a_n=62,S_n=210$: $210=\tfrac{n}{2}(8+62)=35n\Rightarrow n=6$; $62=8+5d\Rightarrow d=\tfrac{54}{5}=10.8$.
• (viii) $a_n=4,d=2,S_n=-14$: $4=a+(n-1)2\Rightarrow a=6-2n$; $-14=\tfrac{n}{2}(a+4)=\tfrac{n}{2}(10-2n)\Rightarrow -14=5n-n^2\Rightarrow n^2-5n-14=0\Rightarrow(n-7)(n+2)=0\Rightarrow n=7,\ a=6-14=-8$.
• (ix) $a=3,n=8,S=192$: $192=\tfrac{8}{2}(6+7d)=4(6+7d)\Rightarrow 48=6+7d\Rightarrow d=6$.
• (x) $l=28,S=144,n=9$: $144=\tfrac{9}{2}(a+28)\Rightarrow 32=a+28\Rightarrow a=4$.

Q4. $9,17,25,\dots$ sum to $636$: $a=9,d=8$; $636=\tfrac{n}{2}[18+(n-1)8]\Rightarrow 1272=18n+8n^2-8n\Rightarrow 8n^2+10n-1272=0\Rightarrow 4n^2+5n-636=0\Rightarrow(n-12)(4n+53)=0\Rightarrow n=12$.

Q5. $a=5,l=45,S=400$: $400=\tfrac{n}{2}(5+45)=25n\Rightarrow n=16$; $45=5+15d\Rightarrow d=\tfrac{40}{15}=\tfrac{8}{3}$.

Q6. $a=17,l=350,d=9$: $350=17+(n-1)9\Rightarrow n=38$; $S=\tfrac{38}{2}(17+350)=19\times367=6973$.

Q7. $d=7,a_{22}=149$: $149=a+21\times7\Rightarrow a=2$; $S_{22}=\tfrac{22}{2}(2+149)=11\times151=1661$.

Q8. $a_2=14,a_3=18\Rightarrow d=4,\ a=10$; $S_{51}=\tfrac{51}{2}[20+50\times4]=\tfrac{51}{2}\times220=5610$.

Q9. $S_7=49,\ S_{17}=289$. $\tfrac72(2a+6d)=49\Rightarrow a+3d=7$; $\tfrac{17}{2}(2a+16d)=289\Rightarrow a+8d=17$. Subtract: $5d=10\Rightarrow d=2,\ a=1$. $S_n=\tfrac{n}{2}[2+(n-1)2]=n^2$.

Q10. Show these are APs and find $S_{15}$.

• (i) $a_n=3+4n$: $a_{n+1}-a_n=4$ constant — AP, $a_1=7,d=4$; $S_{15}=\tfrac{15}{2}[14+14\times4]=\tfrac{15}{2}\times70=525$.
• (ii) $a_n=9-5n$: difference $-5$ — AP, $a_1=4,d=-5$; $S_{15}=\tfrac{15}{2}[8+14(-5)]=\tfrac{15}{2}(-62)=-465$.

Q11. $S_n=4n-n^2$. $S_1=3$ so $a_1=3$; $S_2=4$ so $a_2=S_2-S_1=1$, $a_3=S_3-S_2=3-4=-1$, $a_{10}=S_{10}-S_9=-60-(-45)=-15$. General $a_n=S_n-S_{n-1}=(4n-n^2)-(4(n-1)-(n-1)^2)=5-2n$.

Q12. First 40 positive integers divisible by 6: $6,12,\dots$; $a=6,d=6,n=40$; $S_{40}=\tfrac{40}{2}[12+39\times6]=20(12+234)=20\times246=4920$.

Q13. First 15 multiples of 8: $a=8,d=8,n=15$; $S_{15}=\tfrac{15}{2}[16+14\times8]=\tfrac{15}{2}\times128=960$.

Q14. Odd numbers between 0 and 50: $1,3,\dots,49$; $a=1,d=2,n=25$; $S_{25}=\tfrac{25}{2}(1+49)=25\times25=625$.

Q15. Penalty $200,250,300,\dots$ for 30 days: $a=200,d=50,n=30$; $S_{30}=\tfrac{30}{2}[400+29\times50]=15(400+1450)=15\times1850=27750$. Penalty $\rupee$27750.

Q16. Seven prizes summing to $\rupee700$, each $\rupee20$ less than the previous. $S_7=700,n=7,d=-20$: $700=\tfrac72(2a+6(-20))\Rightarrow 200=2a-120\Rightarrow a=160$. Prizes: $\rupee160,140,120,100,80,60,40$.

Q17. Each section plants trees equal to its class number, 3 sections each, Classes I–XII. Trees $=3(1+2+\dots+12)=3\times\tfrac{12\times13}{2}=3\times78=234$.

Q18. Spiral of 13 semicircles, radii $0.5,1.0,1.5,\dots$ cm. Length $=\pi(r_1+r_2+\dots+r_{13})$, radii in AP $a=0.5,d=0.5,n=13$: sum $=\tfrac{13}{2}[1+12\times0.5]=\tfrac{13}{2}\times7=45.5$. Length $=\tfrac{22}{7}\times45.5=143$ cm.

Q19. Logs $20,19,18,\dots$ totalling 200. $a=20,d=-1,S_n=200$: $200=\tfrac{n}{2}[40-(n-1)]\Rightarrow 400=41n-n^2\Rightarrow n^2-41n+400=0\Rightarrow(n-16)(n-25)=0$. $n=25$ gives $a_{25}=20-24=-4$ (impossible), so $n=16$; top row $a_{16}=20-15=5$ logs. 16 rows, 5 logs on top.

Q20. Potato race: distances $2\times5,\ 2\times8,\ 2\times11,\dots$ for 10 potatoes $=10,16,22,\dots$; $a=10,d=6,n=10$; $S_{10}=\tfrac{10}{2}[20+9\times6]=5\times74=370$ m.

13. NCERT Exercise 5.4 (Optional) — fully solved

Q1. $121,117,113,\dots$: $a=121,d=-4$. First negative term needs $a_n<0$: $121+(n-1)(-4)<0\Rightarrow 125<4n\Rightarrow n>31.25\Rightarrow n=32$. The 32nd term is the first negative one.

Q2. $a_3+a_7=6$ and $a_3\cdot a_7=8$. So $(a+2d)+(a+6d)=2a+8d=6\Rightarrow a+4d=3$. The two terms multiply to $8$ and add to $6$, so they are $2$ and $4$. If $a+2d=2,a+6d=4\Rightarrow d=\tfrac12,a=1$; then $S_{16}=\tfrac{16}{2}[2+15\times\tfrac12]=8\times9.5=76$. (Other case $d=-\tfrac12,a=5$ gives $S_{16}=\tfrac{16}{2}[10-7.5]=20$.)

Q3. Ladder rungs 25 cm apart, length from 45 cm (bottom) to 25 cm (top), rungs span $2\tfrac12$ m $=250$ cm. Number of rungs $=\tfrac{250}{25}+1=11$. Lengths form an AP $a=45,l=25,n=11$. Total wood $=S_{11}=\tfrac{11}{2}(45+25)=\tfrac{11}{2}\times70=385$ cm.

Q4. Houses $1$ to $49$; find $x$ with sum before $x$ = sum after $x$. So $S_{x-1}=S_{49}-S_x$, i.e. $\tfrac{(x-1)x}{2}=\tfrac{49\times50}{2}-\tfrac{x(x+1)}{2}$. This gives $x^2=\tfrac{49\times50}{2}=1225\Rightarrow x=35$. The house is numbered 35.

Q5. Terrace of 15 steps, each $50$ m long, rise $\tfrac14$ m, tread $\tfrac12$ m. Volume of step $k$ (counting from top) $=\tfrac14\times\tfrac12\times50\times k=\tfrac{50}{8}k$ m$^3$. Total $=\tfrac{50}{8}(1+2+\dots+15)=\tfrac{50}{8}\times\tfrac{15\times16}{2}=\tfrac{50}{8}\times120=750$ m$^3$.

14. Common mistakes to avoid

• Computing $d$ as $a_k-a_{k+1}$ instead of $a_{k+1}-a_k$ — keep "later minus earlier".
• Using $a+nd$ for the $n$th term — it is $a+(n-1)d$, with $(n-1)$.
• Forgetting that a list with a constant ratio (like $1,3,9,27$) is not an AP.
• Accepting a non-integer $n$ as an answer — the number of terms must be a positive whole number (so "is X a term?" is answered "no").
• For sums, mixing up $S_n=\tfrac{n}{2}[2a+(n-1)d]$ with $\tfrac{n}{2}(a+l)$ — both are correct, just pick the one matching the given data.
• Rejecting a valid second root when an AP turns from positive to negative (Example 13 has two answers).
• In "term from the last", the $k$th term from the end is the $(n-k+1)$th from the start.

15. Quick revision checklist

• AP: constant difference $d=a_{k+1}-a_k$; general form $a,a+d,a+2d,\dots$
• $n$th term: $a_n=a+(n-1)d$.
• Sum: $S_n=\dfrac{n}{2}[2a+(n-1)d]=\dfrac{n}{2}(a+a_n)$.
• $a_n=S_n-S_{n-1}$; arithmetic mean $b=\dfrac{a+c}{2}$.
• Two unknowns? Make two equations from two given terms or sums, then solve.
• $d>0$ increasing, $d<0$ decreasing, $d=0$ constant.