Statistics

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CLASS X Mathematics ~4 marks/year Ch 13 of 14
Statistics

Class 10 · Mathematics · NCERT chapter notes · Akanksha Classes

Snapshot
  • This chapter finds the three measures of central tendencymean, mode and median — for grouped data (data arranged in class intervals).
  • Mean has three methods, all giving the same answer: Direct, Assumed-mean and Step-deviation. Pick whichever keeps arithmetic light.
  • Mode = $l+\dfrac{f_1-f_0}{2f_1-f_0-f_2}\times h$ — locate the modal class (highest frequency) first.
  • Median = $l+\dfrac{\frac{n}{2}-cf}{f}\times h$ — needs a cumulative frequency column; locate the median class first.
  • Empirical relation linking all three: $3\,\text{Median}=\text{Mode}+2\,\text{Mean}$.
  • Board weightage: ~4 marks/year — usually one mean question and one mode/median question (often a "find the missing frequency" type).
Detailed notes

1. Where this chapter sits

In Class 9 you classified data into ungrouped and grouped frequency distributions, drew bar graphs, histograms and frequency polygons, and met three measures of central tendency — single numbers that "represent" a whole data set: the mean (average), the median (middle value) and the mode (most frequent value).

This chapter takes one step further: it finds those same three measures when the data is grouped into class intervals (like $10\text{-}25,\ 25\text{-}40,\dots$). When data is large, we condense it into classes — but then we no longer know the individual values, so we need new formulae. We also build the idea of cumulative frequency.

Quick recap of the basic terms:

  • Class interval: a range such as $10\text{-}25$; here $10$ is the lower limit, $25$ the upper limit.
  • Class size $h$ = upper limit − lower limit (e.g. $25-10=15$).
  • Class mark $x_i=\dfrac{\text{upper limit}+\text{lower limit}}{2}$ — the mid-point, used as the representative value of the class.
  • Frequency $f_i$ = number of observations in that class.

2. Mean of ungrouped data — the starting point

If observations $x_1,x_2,\dots,x_n$ occur with frequencies $f_1,f_2,\dots,f_n$, the mean is the sum of all values divided by the number of values:

$$\bar{x}=\dfrac{f_1x_1+f_2x_2+\dots+f_nx_n}{f_1+f_2+\dots+f_n}=\dfrac{\sum f_ix_i}{\sum f_i}$$

The Greek letter $\sum$ (sigma) just means "add them all up".

NCERT Example 1 — mean marks of 30 students

Marks $x_i$ and number of students $f_i$ are given. We build a $f_ix_i$ column and add:

$x_i$$f_i$$f_ix_i$
10110
20120
363108
404160
503150
562112
604240
704280
72172
80180
882176
923276
95195
Total301779

$\bar{x}=\dfrac{\sum f_ix_i}{\sum f_i}=\dfrac{1779}{30}=59.3$. So the mean marks are 59.3.

3. Mean of grouped data — Direct Method

When data is grouped, we no longer know each value. We assume the frequency of each class is centred at its class mark $x_i$, and treat $x_i$ as the representative value. Then the same formula works:

$$\bar{x}=\dfrac{\sum f_ix_i}{\sum f_i}\qquad\text{(Direct Method)}$$

Converting Example 1 into classes of width $15$ gives Table 13.3. (Note the convention: a value on an upper limit, e.g. $40$, belongs to the next class $40\text{-}55$, not $25\text{-}40$.)

Class interval$f_i$$x_i$$f_ix_i$
10 - 25217.535.0
25 - 40332.597.5
40 - 55747.5332.5
55 - 70662.5375.0
70 - 85677.5465.0
85 - 100692.5555.0
Total301860.0

$\bar{x}=\dfrac{1860}{30}=62$. Notice this differs from the ungrouped $59.3$ — that gap is the price of the mid-point assumption ($59.3$ is exact, $62$ is approximate).

4. Mean — Assumed-Mean Method

When the $x_i$ are large, multiplying $f_ix_i$ is tedious. Instead, pick one class mark as the assumed mean $a$ (best taken near the middle), and compute the deviation $d_i=x_i-a$. These are smaller numbers:

$$\bar{x}=a+\dfrac{\sum f_id_i}{\sum f_i},\qquad d_i=x_i-a\qquad\text{(Assumed-Mean Method)}$$

For Table 13.3 take $a=47.5$:

Class$f_i$$x_i$$d_i=x_i-47.5$$f_id_i$
10 - 25217.5−30−60
25 - 40332.5−15−45
40 - 55747.500
55 - 70662.51590
70 - 85677.530180
85 - 100692.545270
Total30435

$\bar{x}=47.5+\dfrac{435}{30}=47.5+14.5=62$ — same answer, less labour. The mean does not depend on which $a$ you choose.

5. Mean — Step-Deviation Method

If all the deviations $d_i$ share a common factor (usually the class size $h$), divide them by $h$ to get even smaller numbers $u_i=\dfrac{x_i-a}{h}$. Then:

$$\bar{x}=a+h\left(\dfrac{\sum f_iu_i}{\sum f_i}\right),\qquad u_i=\dfrac{x_i-a}{h}\qquad\text{(Step-Deviation Method)}$$

For Table 13.3 with $a=47.5,\ h=15$:

Class$f_i$$x_i$$d_i=x_i-a$$u_i=\frac{x_i-a}{h}$$f_iu_i$
10 - 25217.5−30−2−4
25 - 40332.5−15−1−3
40 - 55747.5000
55 - 70662.51516
70 - 85677.530212
85 - 100692.545318
Total3029

$\bar{x}=47.5+15\times\dfrac{29}{30}=47.5+14.5=62$. All three methods agree — they are just simpler forms of the direct method. Use direct when $x_i,f_i$ are small; assumed-mean or step-deviation when they are large.

6. More worked mean examples

NCERT Example 2 — mean % of female teachers (all 3 methods)

Classes $15\text{-}25,\dots,75\text{-}85$ with $f_i:6,11,7,4,4,2,1$. Take $a=50,\ h=10$, so $\sum f_i=35$.

Class$f_i$$x_i$$d_i$$u_i$$f_ix_i$$f_id_i$$f_iu_i$
15-25620−30−3120−180−18
25-351130−20−2330−220−22
35-45740−10−1280−70−7
45-554500020000
55-65460101240404
65-75270202140404
75-8518030380303
Total351390−360−36

Direct: $\bar{x}=\dfrac{1390}{35}=39.71$.

Assumed-mean: $\bar{x}=50+\dfrac{-360}{35}=39.71$.

Step-deviation: $\bar{x}=50+\dfrac{-36}{35}\times10=39.71$. All three agree: mean $\approx 39.71\%$.

NCERT Example 3 — mean wickets by 45 bowlers

Class sizes are unequal and $x_i$ large, so step-deviation is best. Take $a=200,\ h=20$. Note $u_i$ need not be integers when classes are unequal.

Class$f_i$$x_i$$d_i$$u_i=d_i/20$$u_if_i$
20-60740−160−8−56
60-100580−120−6−30
100-15016125−75−3.75−60
150-25012200000
250-3502300100510
350-45034002001030
Total45−106

$\bar{x}=200+20\times\dfrac{-106}{45}=200-47.11=152.89$. On average each bowler took about 153 wickets.

7. Mode of grouped data

The mode is the value occurring most often. For ungrouped data you simply spot the highest frequency. For grouped data you cannot read a single value, so you first find the modal class — the class with the maximum frequency — and then use:

$$\text{Mode}=l+\left(\dfrac{f_1-f_0}{2f_1-f_0-f_2}\right)\times h$$

where $l$ = lower limit of the modal class, $h$ = class size, $f_1$ = frequency of the modal class, $f_0$ = frequency of the class before it, $f_2$ = frequency of the class after it.

NCERT Example 4 — mode of ungrouped data

Wickets in 10 matches: $2,6,4,5,0,2,1,3,2,3$. Building a frequency table, the value $2$ occurs $3$ times (the most). So the mode is 2.

NCERT Example 5 — mode of family sizes

Classes $1\text{-}3,3\text{-}5,5\text{-}7,7\text{-}9,9\text{-}11$ with $f:7,8,2,2,1$. Maximum frequency $8$ is in $3\text{-}5$, so modal class $=3\text{-}5$: $l=3,\ h=2,\ f_1=8,\ f_0=7,\ f_2=2$.

$\text{Mode}=3+\dfrac{8-7}{2\times8-7-2}\times2=3+\dfrac{1}{7}\times2=3+\dfrac{2}{7}=3.286$.

NCERT Example 6 — mode of the marks data (Table 13.3)

Maximum frequency $7$ is in $40\text{-}55$, so modal class $=40\text{-}55$: $l=40,\ h=15,\ f_1=7,\ f_0=3,\ f_2=6$.

$\text{Mode}=40+\dfrac{7-3}{2\times7-3-6}\times15=40+\dfrac{4}{5}\times15=40+12=52$.

So the mode is $52$ while the mean (Example 1) was $62$: most students scored around $52$, but the average is pulled up to $62$ by higher scores.

8. Cumulative frequency

The cumulative frequency (cf) of a class is its frequency plus the frequencies of all classes before it. There are two types:

  • "Less than" type: running total going down — e.g. number of students scoring less than $20$, less than $30$, … Uses the upper limits.
  • "More than" type: running total subtracted from the top — number scoring more than or equal to $0$, $10$, … Uses the lower limits.

The cumulative frequency column is the key tool for finding the median (next section). Example of a "less than" cf for marks of $53$ students:

Marks$f$cf
0 - 1055
10 - 2038
20 - 30412
30 - 40315
40 - 50318
50 - 60422
60 - 70729
70 - 80938
80 - 90745
90 - 100853

9. Median of grouped data

The median is the middle-most value. For ungrouped data of $n$ observations (arranged in order): if $n$ is odd it is the $\left(\dfrac{n+1}{2}\right)$th value; if $n$ is even it is the average of the $\dfrac{n}{2}$th and $\left(\dfrac{n}{2}+1\right)$th values.

For grouped data the middle observation falls inside a class, so we find the median class — the first class whose cumulative frequency is $\ge\dfrac{n}{2}$ — then use:

$$\text{Median}=l+\left(\dfrac{\frac{n}{2}-cf}{f}\right)\times h$$

where $l$ = lower limit of the median class, $n=\sum f_i$, $cf$ = cumulative frequency of the class before the median class, $f$ = frequency of the median class, $h$ = class size.

NCERT — median of the 53-student data (Table 13.15)

$n=53\Rightarrow\dfrac{n}{2}=26.5$. The first cf $\ge26.5$ is $29$ (class $60\text{-}70$), so the median class is $60\text{-}70$: $l=60,\ cf=22,\ f=7,\ h=10$.

$\text{Median}=60+\dfrac{26.5-22}{7}\times10=60+\dfrac{45}{7}=66.4$. About half the students scored below $66.4$.

NCERT Example 7 — median height of 51 girls (less-than data)

Given "less than" cumulative frequencies, first recover the ordinary frequencies by subtracting consecutive cf values:

ClassFrequencycf
Below 14044
140 - 145711
145 - 1501829
150 - 1551140
155 - 160646
160 - 165551

$n=51\Rightarrow\dfrac{n}{2}=25.5$, which lies in $145\text{-}150$ (cf $29$): $l=145,\ cf=11,\ f=18,\ h=5$.

$\text{Median}=145+\dfrac{25.5-11}{18}\times5=145+\dfrac{72.5}{18}=149.03$ cm.

NCERT Example 8 — find missing frequencies x, y (median = 525)

Total frequency $=100$. Sum of known frequencies $=2+5+12+17+20+9+7+4=76$, so $x+y=100-76=24$ … (1).

Median $525$ lies in class $500\text{-}600$, so $l=500,\ f=20,\ h=100$ and $cf=36+x$ (cumulative up to $400\text{-}500$). With $\dfrac{n}{2}=50$:

$525=500+\dfrac{50-(36+x)}{20}\times100\Rightarrow25=(14-x)\times5\Rightarrow5=14-x\Rightarrow x=9$.

From (1): $9+y=24\Rightarrow y=15$. So $x=9,\ y=15$.

10. Choosing a measure & the empirical relation

Which measure is best?

  • Mean — most used; takes every value into account. But extreme values distort it, so it can mislead for very uneven data.
  • Median — best when individual values don't matter and there are outliers (e.g. typical wage), since extremes don't affect the middle value.
  • Mode — best for "most popular / most frequent" questions (most-watched TV programme, most-demanded product).

The three are linked by an approximate empirical relationship:

$$3\,\text{Median}=\text{Mode}+2\,\text{Mean}$$

Rearranged: $\text{Mode}=3\,\text{Median}-2\,\text{Mean}$. Given any two of the three, you can estimate the third. Note: before using the mode or median formula, make sure class intervals are continuous (no gaps) — convert if needed.

11. NCERT Exercise 13.1 — fully solved

Q1. Plants per house (20 houses). Classes $0\text{-}2,\dots,12\text{-}14$, $f:1,2,1,5,6,2,3$. Class marks $1,3,5,7,9,11,13$. Direct method (small values): $\sum f_ix_i=1+6+5+35+54+22+39=162$, $\sum f_i=20$. Mean $=\dfrac{162}{20}=8.1$ plants. Direct method chosen because $x_i,f_i$ are small.

Q2. Daily wages of 50 workers. Classes $500\text{-}520,\dots,580\text{-}600$, $f:12,14,8,6,10$. Take $a=550,\ h=20$. $u_i:-2,-1,0,1,2$; $f_iu_i:-24,-14,0,6,20$, $\sum f_iu_i=-12$. Mean $=550+\dfrac{-12}{50}\times20=550-4.8=545.2$ rupees.

Q3. Missing frequency $f$ (mean = 18). Classes $11\text{-}13,\dots,23\text{-}25$, $f:7,6,9,13,f,5,4$. Class marks $12,14,16,18,20,22,24$. $\sum f_ix_i=84+84+144+234+20f+110+96=752+20f$; $\sum f_i=44+f$. Set $\dfrac{752+20f}{44+f}=18\Rightarrow752+20f=792+18f\Rightarrow2f=40\Rightarrow f=20$.

Q4. Heartbeats of 30 women. Classes $65\text{-}68,\dots,83\text{-}86$, $f:2,4,3,8,7,4,2$. Take $a=75.5,\ h=3$. $u_i:-3,-2,-1,0,1,2,3$; $f_iu_i:-6,-8,-3,0,7,8,6=4$. Mean $=75.5+\dfrac{4}{30}\times3=75.5+0.4=75.9$ beats/min.

Q5. Mangoes per box. Classes (continuous: $49.5\text{-}52.5,\dots$), $f:15,110,135,115,25$, $\sum f=400$. Class marks $51,54,57,60,63$. Take $a=57,\ h=3$. $u_i:-2,-1,0,1,2$; $f_iu_i:-30,-110,0,115,50=25$. Mean $=57+\dfrac{25}{400}\times3=57+0.1875\approx57.19$ mangoes. Step-deviation chosen.

Q6. Daily food expenditure (25 households). Classes $100\text{-}150,\dots,300\text{-}350$, $f:4,5,12,2,2$. Take $a=225,\ h=50$. $u_i:-2,-1,0,1,2$; $f_iu_i:-8,-5,0,2,4=-7$. Mean $=225+\dfrac{-7}{25}\times50=225-14=211$ rupees.

Q7. SO$_2$ concentration. Classes $0.00\text{-}0.04,\dots,0.20\text{-}0.24$, $f:4,9,9,2,4,2$, $\sum f=30$. Class marks $0.02,0.06,0.10,0.14,0.18,0.22$. $\sum f_ix_i=0.08+0.54+0.90+0.28+0.72+0.44=2.96$. Mean $=\dfrac{2.96}{30}=0.099$ ppm.

Q8. Days absent (40 students). Classes $0\text{-}6,6\text{-}10,10\text{-}14,14\text{-}20,20\text{-}28,28\text{-}38,38\text{-}40$ (unequal), $f:11,10,7,4,4,3,1$. Class marks $3,8,12,17,24,33,39$. $\sum f_ix_i=33+80+84+68+96+99+39=499$. Mean $=\dfrac{499}{40}=12.475\approx12.48$ days.

Q9. Literacy rate of 35 cities. Classes $45\text{-}55,\dots,85\text{-}95$, $f:3,10,11,8,3$. Take $a=70,\ h=10$. $u_i:-2,-1,0,1,2$; $f_iu_i:-6,-10,0,8,6=-2$. Mean $=70+\dfrac{-2}{35}\times10=70-0.57=69.43\%$.

12. NCERT Exercise 13.2 — fully solved

Q1. Ages of patients — mode and mean. Classes $5\text{-}15,\dots,55\text{-}65$, $f:6,11,21,23,14,5$. Modal class $35\text{-}45$ (max $f=23$): $l=35,f_1=23,f_0=21,f_2=14,h=10$. $\text{Mode}=35+\dfrac{23-21}{46-21-14}\times10=35+\dfrac{20}{11}=36.8$ years. Mean: $a=30,h=10$, $u_i:-2,-1,0,1,2,3$; $f_iu_i:-12,-11,0,23,28,15=43$, $\sum f=80$. Mean $=30+\dfrac{43}{80}\times10=30+5.37=35.37$ years. Maximum patients are around age $36.8$; the average age is $35.37$.

Q2. Modal lifetime of 225 components. Classes $0\text{-}20,\dots,100\text{-}120$, $f:10,35,52,61,38,29$. Modal class $60\text{-}80$ (max $f=61$): $l=60,f_1=61,f_0=52,f_2=38,h=20$. $\text{Mode}=60+\dfrac{61-52}{122-52-38}\times20=60+\dfrac{9}{32}\times20=60+5.625=65.625$ hours.

Q3. Monthly expenditure of 200 families — mode and mean. Modal class $1500\text{-}2000$ (max $f=40$): $l=1500,f_1=40,f_0=24,f_2=33,h=500$. $\text{Mode}=1500+\dfrac{40-24}{80-24-33}\times500=1500+\dfrac{16}{23}\times500=1500+347.83=1847.83$ rupees. Mean: $a=2750,h=500$, $\sum f_iu_i=-235$ (from $u_i:-3,-2,-1,0,1,2,3,4$ with $f:24,40,33,28,30,22,16,7$). Mean $=2750+\dfrac{-235}{200}\times500=2750-587.5=2662.5$ rupees.

Q4. Teacher-student ratio — mode and mean. Classes $15\text{-}20,\dots,50\text{-}55$, $f:3,8,9,10,3,0,0,2$. Modal class $30\text{-}35$ (max $f=10$): $l=30,f_1=10,f_0=9,f_2=3,h=5$. $\text{Mode}=30+\dfrac{10-9}{20-9-3}\times5=30+\dfrac{5}{8}=30.6$. Mean: $a=32.5,h=5$, $\sum f=35$, $\sum f_iu_i=-23$. Mean $=32.5+\dfrac{-23}{35}\times5=32.5-3.29=29.2$. Most states have ratio $\approx30.6$; the average is $29.2$.

Q5. Runs by batsmen — mode. Modal class $4000\text{-}5000$ (max $f=18$): $l=4000,f_1=18,f_0=4,f_2=9,h=1000$. $\text{Mode}=4000+\dfrac{18-4}{36-4-9}\times1000=4000+\dfrac{14}{23}\times1000=4608.7$ runs.

Q6. Cars per period — mode. Classes $0\text{-}10,\dots,70\text{-}80$, $f:7,14,13,12,20,11,15,8$. Modal class $40\text{-}50$ (max $f=20$): $l=40,f_1=20,f_0=12,f_2=11,h=10$. $\text{Mode}=40+\dfrac{20-12}{40-12-11}\times10=40+\dfrac{80}{17}=44.7$ cars.

13. NCERT Exercise 13.3 — fully solved

Q1. Electricity consumption (68 consumers) — median, mean, mode. Classes $65\text{-}85,\dots,185\text{-}205$, $f:4,5,13,20,14,8,4$. Mean: $a=135,h=20$, $\sum f_iu_i=7$; mean $=135+\dfrac{7}{68}\times20=137.06$ units. Median: $\dfrac{n}{2}=34$; cf: $4,9,22,42,\dots$ — median class $125\text{-}145$ ($l=125,cf=22,f=20,h=20$). $\text{Median}=125+\dfrac{34-22}{20}\times20=125+12=137$ units. Mode: modal class $125\text{-}145$: $\text{Mode}=125+\dfrac{20-13}{40-13-14}\times20=125+\dfrac{140}{13}=135.77$ units. The three measures are close ($\approx135\text{-}137$).

Q2. Missing $x,y$ (median = 28.5, total = 60). Classes $0\text{-}10,\dots,50\text{-}60$, $f:5,x,20,15,y,5$. Sum $=45+x+y=60\Rightarrow x+y=15$ … (1). Median $28.5$ lies in $20\text{-}30$: $l=20,f=20,h=10,cf=5+x$, $\dfrac{n}{2}=30$. $28.5=20+\dfrac{30-(5+x)}{20}\times10\Rightarrow8.5=\dfrac{25-x}{2}\Rightarrow17=25-x\Rightarrow x=8$. From (1): $y=7$.

Q3. Ages of 100 policy holders — median (below-type data). Convert to frequencies: classes $18\text{-}20,20\text{-}25,\dots,55\text{-}60$, $f:2,4,18,21,33,11,3,6,2$. cf: $2,6,24,45,78,\dots$. $\dfrac{n}{2}=50$; median class $35\text{-}40$ ($l=35,cf=45,f=33,h=5$). $\text{Median}=35+\dfrac{50-45}{33}\times5=35+\dfrac{25}{33}=35.76$ years.

Q4. Lengths of 40 leaves — median. Make classes continuous: $117.5\text{-}126.5,\dots,171.5\text{-}180.5$, $f:3,5,9,12,5,4,2$. cf: $3,8,17,29,\dots$. $\dfrac{n}{2}=20$; median class $144.5\text{-}153.5$ ($l=144.5,cf=17,f=12,h=9$). $\text{Median}=144.5+\dfrac{20-17}{12}\times9=144.5+2.25=146.75$ mm.

Q5. Lifetime of 400 lamps — median. Classes $1500\text{-}2000,\dots,4500\text{-}5000$, $f:14,56,60,86,74,62,48$. cf: $14,70,130,216,\dots$. $\dfrac{n}{2}=200$; median class $3000\text{-}3500$ ($l=3000,cf=130,f=86,h=500$). $\text{Median}=3000+\dfrac{200-130}{86}\times500=3000+406.98=3406.98$ hours.

Q6. Letters in 100 surnames — median, mean, mode. Classes $1\text{-}4,\dots,16\text{-}19$, $f:6,30,40,16,4,4$. Median: cf $6,36,76,\dots$, $\dfrac{n}{2}=50$; median class $7\text{-}10$ ($l=7,cf=36,f=40,h=3$). $\text{Median}=7+\dfrac{50-36}{40}\times3=7+1.05=8.05$. Mean: $a=11.5,h=3$, class marks $2.5,5.5,8.5,11.5,14.5,17.5$; $\sum f_iu_i=-106$; mean $=11.5+\dfrac{-106}{100}\times3=11.5-3.18=8.32$. Mode: modal class $7\text{-}10$: $\text{Mode}=7+\dfrac{40-30}{80-30-16}\times3=7+\dfrac{30}{34}=7.88$.

Q7. Weights of 30 students — median. Classes $40\text{-}45,\dots,70\text{-}75$, $f:2,3,8,6,6,3,2$. cf: $2,5,13,19,\dots$. $\dfrac{n}{2}=15$; median class $55\text{-}60$ ($l=55,cf=13,f=6,h=5$). $\text{Median}=55+\dfrac{15-13}{6}\times5=55+1.67=56.67$ kg.

14. Common mistakes to avoid

  • Comparing the wrong column to $\dfrac{n}{2}$ — always compare the cumulative frequency, and use the lower limit of the chosen class as $l$.
  • For median, taking $cf$ of the median class instead of the class before it.
  • Forgetting to make class intervals continuous before applying mode/median formulae (e.g. $1\text{-}4,5\text{-}8\dots$ must become $0.5\text{-}4.5,\dots$).
  • Mixing up $f_0$ (class before) and $f_2$ (class after) in the mode formula.
  • In the mean, using the class limits instead of the class mark $x_i$.
  • Writing the empirical relation as $3\,\text{Mode}=\dots$ — it is $3\,\text{Median}=\text{Mode}+2\,\text{Mean}$.

15. Quick revision checklist

  • Class mark $x_i=\dfrac{\text{upper}+\text{lower}}{2}$; class size $h=$ upper − lower.
  • Mean: Direct $\bar{x}=\dfrac{\sum f_ix_i}{\sum f_i}$; Assumed $\bar{x}=a+\dfrac{\sum f_id_i}{\sum f_i}$; Step $\bar{x}=a+h\dfrac{\sum f_iu_i}{\sum f_i}$.
  • Mode $=l+\dfrac{f_1-f_0}{2f_1-f_0-f_2}\times h$ (modal class = max frequency).
  • Median $=l+\dfrac{\frac{n}{2}-cf}{f}\times h$ (median class = first cf $\ge\frac{n}{2}$).
  • Empirical relation: $3\,\text{Median}=\text{Mode}+2\,\text{Mean}$.
  • Always build a cf column for median; ensure classes are continuous for mode/median.
Practice MCQs
1. The class mark of the interval $25\text{-}40$ is:
  1. $15$
  2. $32.5$
  3. $65$
  4. $30$
Answer: (B) $\dfrac{25+40}{2}=32.5$.
2. In the mode formula, $f_0$ stands for the frequency of the:
  1. modal class
  2. class preceding the modal class
  3. class succeeding the modal class
  4. median class
Answer: (B) $f_0$ is the frequency of the class before the modal class.
3. The median class is the class whose cumulative frequency is:
  1. maximum
  2. just greater than (and nearest to) $\dfrac{n}{2}$
  3. equal to $n$
  4. minimum
Answer: (B) the first class with cf $\ge\dfrac{n}{2}$.
4. For the data with mean $62$ and mode $52$, the median (by the empirical relation) is:
  1. $57$
  2. $58.7$
  3. $60$
  4. $54$
Answer: (B) $3M=52+2(62)=176\Rightarrow M=58.67\approx58.7$.
5. The step-deviation $u_i$ is defined as:
  1. $x_i-a$
  2. $\dfrac{x_i-a}{h}$
  3. $f_ix_i$
  4. $\dfrac{a-x_i}{f_i}$
Answer: (B) $u_i=\dfrac{x_i-a}{h}$.
6. Which measure of central tendency is most affected by extreme values?
  1. Mode
  2. Median
  3. Mean
  4. All equally
Answer: (C) the mean uses every value, so outliers shift it most.
7. The "less than" cumulative frequency uses which limit of each class?
  1. lower limit
  2. upper limit
  3. class mark
  4. mid-point
Answer: (B) "less than" cf is written against the upper limits.
8. For finding the median of $1\text{-}4,5\text{-}8,9\text{-}12,\dots$, the classes must first be made:
  1. discrete
  2. continuous
  3. equal-frequency
  4. cumulative
Answer: (B) the formula assumes continuous classes (e.g. $0.5\text{-}4.5,\dots$).
9. If $\sum f_i=30$ and $\sum f_id_i=435$ with $a=47.5$, the mean is:
  1. $47.5$
  2. $14.5$
  3. $62$
  4. $59.3$
Answer: (C) $47.5+\dfrac{435}{30}=47.5+14.5=62$.
10. To find the mode of grouped data we first locate the:
  1. median class
  2. modal class (maximum frequency)
  3. class with $\dfrac{n}{2}$
  4. class mark
Answer: (B) the modal class is the one with the highest frequency.
11. The three methods (direct, assumed-mean, step-deviation) of finding the mean:
  1. give three different answers
  2. give the same answer
  3. only work for ungrouped data
  4. need a cf column
Answer: (B) they are simpler forms of one another and always agree.
12. In Median $=l+\dfrac{\frac{n}{2}-cf}{f}\times h$, the term $cf$ is the cumulative frequency of the:
  1. median class
  2. class preceding the median class
  3. last class
  4. modal class
Answer: (B) the class just before the median class.
Assertion–Reason
A: For a grouped distribution, the mean can be found by the step-deviation method.   R: $u_i=\dfrac{x_i-a}{h}$ makes the products $f_iu_i$ smaller and easier to add.
Answer: Both A and R are true, and R correctly explains A — dividing by $h$ shrinks the numbers, simplifying the arithmetic.
A: The empirical relation is $3\,\text{Median}=\text{Mode}+2\,\text{Mean}$.   R: This relation holds exactly for every distribution.
Answer: A is true, R is false — the relation is only approximate (empirical), not exact.
Previous-year questions
Q1. Find the mode of the data with modal class $40\text{-}50$, $f_1=20,\ f_0=12,\ f_2=11,\ h=10$. (CBSE, 2 marks)
Answer: $\text{Mode}=40+\dfrac{20-12}{40-12-11}\times10=40+\dfrac{80}{17}=44.7$ (approx).
Q2. The median of a grouped distribution is $28.5$ and total frequency $60$; find the missing frequencies $x,y$ for classes $0\text{-}10(5),10\text{-}20(x),20\text{-}30(20),30\text{-}40(15),40\text{-}50(y),50\text{-}60(5)$. (CBSE, 3 marks)
Answer: $x+y=15$; median class $20\text{-}30$ gives $28.5=20+\dfrac{30-(5+x)}{20}\times10\Rightarrow x=8,\ y=7$.
Q3. Find the mean of the daily wages of $50$ workers: $500\text{-}520(12),520\text{-}540(14),540\text{-}560(8),560\text{-}580(6),580\text{-}600(10)$. (CBSE, 3 marks)
Answer: $a=550,h=20$, $\sum f_iu_i=-12$; mean $=550+\dfrac{-12}{50}\times20=545.2$ rupees.
Q4. The mean and median of a distribution are $35.37$ and $\approx35.4$. Estimate the mode. (CBSE, 2 marks)
Answer: $\text{Mode}=3\,\text{Median}-2\,\text{Mean}=3(35.4)-2(35.37)=106.2-70.74=35.46$ (approx).
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