2024 BSc Statistics and Probability PDF

Summary

This document is a BSc Statistics and Probability lecture script for January 2024. It covers topics such as descriptive statistics, probability theory, and inferential statistics. The document also includes references for further reading and an index.

Full Transcript

Bachelor of Science

Statistics and Probability

Module coordinator: Pia Domschke as of January 29, 2024
Course overview

I Descriptive Statistics
1 Statistical attributes and variables.......................................................... 5
2 Measures to describe statistical distributions............................................. 31
3 Two dimensional distributions............................................................. 71
4 Linear regression..........................................................................103

II Probability Theory
5 Combinatorics and counting principles.................................................. 120
6 Fundamentals of probability theory....................................................... 131
7 Random variables in one dimension...................................................... 169
8 Multidimensional random variables....................................................... 210
9 Stochastic models and special distributions.............................................. 237
10 Limit theorems............................................................................. 259

1-1
III Inferential Statistics
11 Point estimators for parameters of a population..........................................277
12 Interval estimators........................................................................ 286
13 Statistical testing.......................................................................... 317

IV Appendix
Literature...................................................................................348 - 1
Index....................................................................................... 349 - 1

1-2
Statistics

2
Literature:

[Anderson et al., 2012] Anderson, D. R., Sweeney, D. J., Williams, T. A., Camm, J. D.,
and Cochran, J. D. (2012).
Statistics for Business and Economics.
South-Western Cengage Learning, 12th edition.

[Bleymüller, 2012] Bleymüller, J. (2012).
Statistik für Wirtschaftswissenschaftler.
Vahlen, 16th edition.
[Newbold et al., 2013] Newbold, P., Carlson, W. L., and Thorne, B. M. (2013).
Statistics for business and economics.
Pearson, 8th edition.
[Schira, 2016] Schira, J. (2016).
Statistische Methoden der VWL und BWL – Theorie und Praxis.
Pearson, 5th edition.

3
 Part I – Descriptive Statistics

1 Statistical attributes and variables.......................................................... 5

2 Measures to describe statistical distributions............................................. 31

3 Two dimensional distributions............................................................. 71

4 Linear regression..........................................................................103

4
 1 Statistical attributes and variables

1.1 Statistical units and populations....................................................... 6
1.2 Attributes/Characteristics and their values............................................. 8
1.3 Subpopulations, random samples.....................................................12
1.4 Statistical distribution................................................................. 15
1.5 Frequency and distribution function................................................... 20
1.6 Frequency density and histograms.................................................... 24

according to [Schira, 2016], chapter 1
see also: [Anderson et al., 2012], chapter 1 & 2; and [Newbold et al., 2013], chapter 1
1. Statistical attributes and variables 5
 Statistical units and populations

Definition:
Statistical units are the objects whose attributes are of interest in a given context and
are focussed on and observed, surveyed, or measured within the scope of empirical
investigation.

The identification of similar statistical units belonging to a statistical population are es-
sentially given by objective and precise identification criteria (IC) relating to

1. time
2. space and
3. objectivity

Examples of statistical units:
Motor vehicles, buildings, horses, students, civil servants, farms, branches, apples, sales,
marriages, births, accidents, bank accounts, etc.

1. Statistical attributes and variables 6
 Statistical units and populations

Definition:
The set
Ω := {ω | ω fulfills (IC) }
of all statistical units ω , that fulfill the well defined identification criteria (IC) is called the
population.
Synonyms are statistical mass, collective

Examples of statistical populations:

Traffic accidents in Bavaria in 2002
Traffic accidents with personal injury in Germany in 1999
Students in lectures on Tuesday, 25.02.2014 at 2:15pm in Frankfurt School of
Finance and Management, Germany
Registered bankruptcies of building companies in North Rhine Westphalia in April
2002

1. Statistical attributes and variables 7
 Attributes/Characteristics and their values

Statistical units ω are not of direct interest, but some of their attributes M (ω).
Distinguishable manifestations of a characteristic are called characteristic values or
modes.

Examples:

The characteristic gender has the possible values {male, female, diverse}.
The characteristic eye color has the possible values {blue, green, grey, brown}.
For the characteristic body weight of adult humans all values between 30 and
300 kg have to be allowed as possible values.

1. Statistical attributes and variables 8
 Statistical variable

Definition:
The statistical variable assigns a real number x to a statistical unit ω or its characteristic
M (ω). Thus
x = X (ω) = Fkt (M (ω)).
X (ω) is a real-valued function of the characteristic values M (ω) and thus of the statistical
units

X :Ω→R
ω 7→ X (ω) = x

Difference between M and X :
X (ω) is always a real number. M (ω) can also be „green“ or „married“.
Characteristic (if numerical) and statistical variable are often used as synonyms,
although strictly speaking they do not precisely denote the same thing.
One often simply says: „the statistical variable X “ or „the characteristic X “

1. Statistical attributes and variables 9
 Types of attributes

Qualitative characteristics are e.g.:
gender
religious belief
legal form of companies, etc.

Quantitative characteristics or variables are e.g.:
age (in whole years)
number of children discrete
income
living space
continuous
length of a line

characteristics or variables

1. Statistical attributes and variables 10
 Measurement levels (scales)

Nominally measurable variables

Increasing degree of measurability
Nominal attributes are always qualitative.
Examples: religion, nationality, professions, color of a car, the legal structure of a
company

Ordinally measurable variables
There exists a natural or meaningful way to determine the ranking.
Examples: intelligence quotient, school grades or table positions in the German
football league.

Cardinally measurable variables
In the case of cardinally scaled variables, also the difference between outcomes is
meaningful
Examples: GDP, investment, inflation, costs, revenue and profit

1. Statistical attributes and variables 11
 Subpopulations, random samples

Possibilities to sample the values of a characteristic
Full sampling ( but in many cases not feasible)
Partial sampling

Definition:
Each proper subset Ω∗ of Ω is called a subpopulation or sample of the whole popula-
tion.
Subpopulations are called random samples if chance played a significant role in the
selection of the elements.

1. Statistical attributes and variables 12
 Subpopulations, random samples

Pure random sampling:
Each part of the population has the same chance of being selected in the random
sample.

Representative random sampling:
The aim is to select a subpopulation that is representative of the whole population.
As the structure of the characteristics we are interested in is unknown before sampling,
we try to ensure that it is representative with respect to other characteristics where
we assume that the characteristic to be investigated has a certain „statistical relationship“
to this other characteristic.

1. Statistical attributes and variables 13
 Subpopulations, random samples
Example

A research institute creates an election forecast.
For this purpose, 3000 entitled voters are asked the so-called
Sunday question: „Which party would you choose if there were
elections next Sunday?“

To get more realistic results , the random sample is selected on a representative basis:
consequently other characteristics are taken into consideration that could have a
statistical influence on party preference. The random sample needs to include the share
of women in the population of all eligible voters. The age structure should also conform
to the whole population.
This already makes the sample quite representative for this purpose. It would certainly
still be important to take the geographical distribution into account to avoid a situation
where too many respondents happen to live in Baden-Württemberg. Furthermore, it
would be good if the professional structure were at least analogous in the
characteristics workers, employees, civil servants, self-employed. Yes, and of course
students must be in the sample, otherwise Green voters might be underrepresented.

1. Statistical attributes and variables 14
 Statistical distribution

Raw data table

Elements ω1 ω2... ωi... ωn
Possible outcomes x1 x2... xi... xn

Definition:
The (finite) sequence of the n values

x1 , x2 ,... , xi ,... , xn

withxi = X (ωi ) fori = 1,... , n is called observation series of the variable X or simply
data set X.

1. Statistical attributes and variables 15
 Statistical distribution

If the order of the observations does not matter, it is often helpful to sort and renumber
the variable values.

x1 ≤ x2 ≤ x3 ≤ · · · ≤ xi ≤ · · · ≤ xn

Example: n = 20 observations

1.6 1.6 3.0 3.0 3.0 3.0 4.1 4.1 4.1 4.1
4.1 4.1 4.1 4.1 5.0 5.0 5.0 5.0 5.0 5.0

withk = 4 different outcomes: 1.6 3.0 4.1 5.0

1. Statistical attributes and variables 16
 Absolute and relative frequency

Definition:
The absolute frequency
ni := absF(X = xi )
indicates how often the statistical variable X takes a certain value xi.

The relative frequency
ni
hi := relF(X = xi ) = , 0 < hi ≤ 1
n
indicates the share of the characteristic expression xi in the population.

1. Statistical attributes and variables 17
 Statistical distribution

Definition:
The tables

x1 x2... xk x1 x2... xk
and
n1 n2... nk h1 h2... hk

k
P k
P
with ni = n and hi = 1
i =1 i =1

are called absolute and relative frequency distribution of the statistical variable X ,
respectively.

Example:

xi 1.6 3.0 4.1 5.0 xi 1.6 3.0 4.1 5.0

ni 2 4 8 6 hi 0.1 0.2 0.4 0.3
4
P 4
P
ni = 20 hi = 1
i =1 i =1
1. Statistical attributes and variables 18
 Statistical distribution

1.6 1.6 3.0 3.0 3.0 3.0 4.1 4.1 4.1 4.1
4.1 4.1 4.1 4.1 5.0 5.0 5.0 5.0 5.0 5.0

ni hi

10 0.5
8 0.4
6 0.3

4 0.2

2 0.1
xi
1.6 3 4.1 5
Graph of a frequency distribution

1. Statistical attributes and variables 19
 Frequency and distribution function

Definition:
The function (
hi , if x = xi
h(x ) =
0 otherwise
is called the (relative) frequency function of the statistical variable X.

The function X
H (x ) = h ( xi )
xi ≤x

is called the empirical cumulative distribution function of the statistical variable X.

1. Statistical attributes and variables 20
 Frequency and distribution function
Example

xi 1.6 3.0 4.1 5.0

hi 0.1 0.2 0.4 0.3

Hi 0.1 0.3 0.7 1.0

h(x ) frequency function

0.5
0.25
x
1 2 3 4 5 6
H (x )
distribution function
1
0.75
0.5 step function
0.25
x
1 2 3 4 5 6
1. Statistical attributes and variables 21
 Frequency and distribution function
Properties of the empirical cumulative distribution function

The empirical cumulative distribution function H is
1. everywhere at least continuous to the right

lim H (x + ∆x ) = H (x )
∆x →0+

(at jumps it is only continuous to the right),
2. monotonically increasing

H (a) ≤ H (b), if a < b

3. and has lower limit 0 and upper limit 1

lim H (x ) = 0, lim H (x ) = 1
x →−∞ x →∞

1. Statistical attributes and variables 22
 Frequency and distribution function
Further properties of the distribution function

1. For a < b, the difference H (b) − H (a) = relF(a < X ≤ b)

specifies the relative frequency of observed values of the variable X that are greater
than a , but not greater than b.
2. The function value at a point x indicates the relative frequency of which values less
than or equal to x occur in the data set:

H (x ) = relF(X ≤ x )

3. At each point, the values of the frequency function are obtained from the empirical
distribution function as the difference

h(x ) = H (x ) − lim H (x − ∆x )
∆x →0+

1. Statistical attributes and variables 23
 Frequency density and histograms

Due to limitations in practice, we often apply

Formation of class intervals or layers Income distribution Germany as a whole:

Class size
Class frequency

Distribution function of the classes

Approximation by polygons
Frequency density of the classes
Frequency density function and histogram

Approximation by smooth curves
continuous density function

1. Statistical attributes and variables 24
 Frequency density and histograms

Formation of class intervals or layers with appropriately selected class limits
ξ0 , ξ 1 , ξ 2 ,... , ξ m :

x
ξ0 ξ1 ξ2 ξ3...... ξm

The m sections have the class sizes

∆i := ξi − ξi −1 , i = 1,... , m

and the class frequency of the values in each size class is

hi := relH(ξi −1 < X ≤ ξi ), i = 1,... , m

Note: [Schira, 2016] uses right hand inclusion while [Anderson et al., 2012] and
[Newbold et al., 2013] use left hand inclusion

1. Statistical attributes and variables 25
 Frequency density and histograms

Definition:
By assigning the class frequencies to the upper limits of the classes (an alternative
possibilty would be to assign the class frequencies to the class centers), the following
frequency table can be drawn from the values

ξ1 ξ2... ξm k
P
hi = 1
h1 h2... hm i =1

and hence the so-called distribution function of the classes HK (x ).

Exercise:
How does the distribution function for the classes
shown on the left look like? (Choose an appropriate
upper limit for the final class).

1. Statistical attributes and variables 26
 Frequency density and histograms

By focussing on the upper limits (or any other single point) of the classes we lose
information about the distribution within the classes. The assumption of a uniform
distribution leads to the definition below.

Definition:
Let HK (x ) be the distribution function of a characteristic X obtained by size classes with
upper class limits ξ1 , ξ2 ,... , ξm. Then, the ratio

HK (ξi ) − HK (ξi −1 ) hi
=
ξi − ξi −1 ∆i
is called the (average) frequency density of the ith size class (i = 1,... , m).

1. Statistical attributes and variables 27
 Frequency density and histograms

distribution function
Approximation of the distribution function Hk
by a polygonal line H̄ (x )
Taking the derivative of H̄ (x ) leads to the
(average) frequency density function h̄(x )
of the size classes:
dH̄ (x )
h̄(x ) :=
dx
Its graph is called histogram.
histogram
The area of a column corresponds to the
relative class frequency.
The total area of the columns of the
histogram is one.

1. Statistical attributes and variables 28
 Frequency density and histograms

distribution function

Approximation of the distribution function of
the classes Hk by a smooth curve H̃ (x )

Taking the derivative of H̃ (x ) leads to
density function.

density function dH̃ (x )
h̃(x ) :=
dx

1. Statistical attributes and variables 29
 Control questions

1. What is the difference between characteristic and variable?

2. What different types of scales are there? Examples!

3. Why are mainly representative random samples taken into account in practice?

4. What are the properties of the step function? What is its information content?

5. Why is the formation of size classes often necessary?

6. What is the implicit assumption underlying the approximating distribution function
H̄ (x )?

7. What is the difference between a bar chart (look up definition if necessary) and a
histogram? Under what condition do they both look the same?

1. Statistical attributes and variables 30
 2 Measures to describe statistical distributions

2.1 Measures to describe statistical distributions..................................... 32
2.2 Measures of central tendency...................................................... 33
2.3 Mode.................................................................................34
2.4 Arithmetic mean...................................................................... 36
2.5 Geometric mean..................................................................... 38
2.6 Harmonic mean...................................................................... 43
2.7 Measures of variation............................................................... 45
2.8 Variance and standard deviation...................................................... 49
2.9 Robust measures................................................................... 58
2.10 Median............................................................................... 59
2.11 Quartiles............................................................................. 61
2.12 Quantiles............................................................................ 62
2.13 Five-point summary and box plot..................................................... 69

according to [Schira, 2016], chapter 2
see also: [Anderson et al., 2012], chapter 3;
and [Newbold et al., 2013], chapter 2

2. Measures to describe statistical distributions 31
 Measures to describe statistical distributions

Especially for statistical data sets with many different characteristical values, one would
like to describe the entire distribution of the characteristic with the help of a few numbers.
Such numbers are called measures or parameters of a distribution.

We distinguish between
measures of location
measures of dispersion

2. Measures to describe statistical distributions 32
 Measures of central tendency

Definition:
A measure of central tendency or measure of location is a parameter used to de-
scribe the distribution of a random variable and provides a „typical“ value. In particular,
it describes the location of the data set, i.e. where or in which order of magnitude the
values of the variable are located.

2. Measures to describe statistical distributions 33
 Mode

Definition:
A number xMod with
h(xMod ) ≥ h(xi ) for all i
is called mode or modal value of an empirical data set.

Useful measure of location especially for purely qualitative characteristics

2. Measures to describe statistical distributions 34
 Mode

Examples:
The data set

2 3 3 4 4 4 5 6

has the mode xMod = 4 (and is thus unimodal)

There are two „most frequent“ values in the data set

1 2 3 3 3 4 5 6 6 6 7

namely the values 3 and 6.

The mode is the value that occurs with highest frequency

2. Measures to describe statistical distributions 35
 Arithmetic mean

Definition:
The value
n
1X
x̄ := xj
n
j =1

is called arithmetic mean, mean value, or average of a statistical distribution.

Alternative calculation using absolute or relative frequencies:
k k
1X X
x̄ = nj xj = hj xj
n
j =1 j =1

2. Measures to describe statistical distributions 36
 Arithmetic mean

Properties of the arithmetic mean

1. Central property
n
X
(xj − x̄ ) = 0
j =1

2. Shifting all values of a data set X by the constant value a shifts the arithmetic
mean by exactly this value:

yi := xi + a ⇒ ȳ = x̄ + a

3. Multiplication of all values of a data set X with the constant factor b multiplies the
arithmetic mean by exactly this value:

zi := b · xi ⇒ z̄ = b · x̄

2. Measures to describe statistical distributions 37
 Geometric mean

Definition:
For the geometric mean
√
n
GX := x1 · x2 · · · · · xn , xi > 0

For the geometric mean, the individual characteristic values are multiplied and the n-th
root is taken from the product. It is only defined if all values of the data set X are positive.

The logarithm of the geometric mean corresponds to the arithmetic mean of the
logarithms. (important for the calculation of overall return on an investment)
n
1X
log GX = log xi
n
i =1

2. Measures to describe statistical distributions 38
 Geometric mean

Example:
For the data set X with the values

2 6 12 9

the geometric mean is GX = 6
and the arithmetic mean is x̄ = 7.25

Note: The geometric mean for each set with only positive values is always smaller than
the arithmetic mean unless all the values in the data set are the same.

2. Measures to describe statistical distributions 39
 Geometric mean
Example

In five consecutive years the turnover Y given in thousand C) of a company developed
as follows:

2. Measures to describe statistical distributions 40
 Geometric mean
Example (cont’d)

Question: Which mean is best suited for the calculation of the average growth?

Arithmetic mean:

1 + r = (1.20 + 0.85 + 1.40 + 1.25)/4 = 1.175

Geometric mean:
√
4
G1+r = 1.20 · 0.85 · 1.40 · 1.25 = 1.1559

An average increase in turnover of 17.5 % would result in a turnover of 2287 kC in 2001
whereas an average increase in turnover of 15.59 % would result in the actual value of
2142 kC.

2. Measures to describe statistical distributions 41
 Example Stock return

Financial advisor: The
share is a top investment,
with an average return of
Arithmetic mean: 25 %.

1
1+r = 2
· ((1 + 100 %) + (1 − 50 %)) = 1 + 25 % ⇒ 25 %

Geometric mean:
√
2
G1+r = 2 · 0.5 = 1 ⇒ 0%

2. Measures to describe statistical distributions 42
 Harmonic mean

Definition:
From the values xi > 0 of a data set, one can calculate the reciprocal values 1/xi and
then calculate the arithmetic mean of these values
 
1 1 1
+ ··· +
n x1 xn

Taking the reciprocal of the result again, yields the so-called harmonic mean
n
HX := n 1.
P
j =1 xj

2. Measures to describe statistical distributions 43
 Harmonic mean

Example:
For the data set X with the values

2 6 12 9

the harmonic mean is HX = 4.645
the geometric mean is GX = 6
and the arithmetic mean is x̄ = 7.25

Note: For every data set with (different) positive values, it can be shown that

HX < GX < x̄

2. Measures to describe statistical distributions 44
Example:

Two trucks travel at speeds of v1 = 60 km/h and v2 = 80 km/h on the highway. Thus the average
speed (arithmetic mean) is
 
1 km km km
v̄ = 60 + 80 = 70.
2 h h h

To estimate the (average) transport times t̄ and thus transport capacities and transport costs for
a distance of say from Hamburg to Duisburg, one would divide the corresponding distance d =
420 km by this value and obtained with

d 420 km
= = 6h,
v̄ 70 km/h

a wrong value. Indeed, the transport times of the two trucks are t1 = 7 h and t2 = 5.25 h. Thus the
average transport time is
t̄ = 6.125 h.

If, on the contrary, one divides the distance by the harmonic mean

2 480 km km
HV = 1 1
= ≈ 68.57 ,
60 km/h
+ 80 km/h
7 h h

44 - 1
then one receives with
d 420 km
= 480
= 6.125 h = t̄
HV 7
km/h

the correct result. If you are doing a salary calculation
based on an hourly wage, then this
question is highly relevant.

Question: Why is the first calculation wrong?

In this example we want to calculate an average transport time for a fixed distance d. The problem
with the average speed is that it is not valid over the whole time, because the first truck arrives
already after 5.25 h and then stops while the other one is still moving. For the calculation of the mean
transportation time, the speeds are in the denominator due to the principle ti = vd. This leads to the
i
harmonic mean:
 
1 1 d d
t̄ = (t1 + · · · + tn ) = + ··· +
n n v1 vn
 
1 1 1 1 d
=d· + ··· + =d· =.
n v1 vn HV HV

44 - 2
If, in contrast, we want to know how far the trucks have come on (arithmetic) average after a certain
time t, the calculation

1 1
d̄ = (d1 + · · · + dn ) = (t · v1 + · · · + t · vn )
n n
1
=t· (v1 + · · · + vn ) = t · v̄
n

is the correct one.

44 - 3
 Measures of variation

Three histograms: distribution with different degrees of spread or variability

The extent of the spread or variation or dispersion of a distribution needs to be ex-
pressed as a measure.

2. Measures to describe statistical distributions 45
 Measures of variation

The descriptive statistics provides some measures of variation:

Definition:
The range is the difference between the largest and the smallest value in a data set:

range := xmax − xmin

Definition:
The so-called mean absolute deviation
n
1X
MAD := |xj − x̄ |
n
j =1

is calculated as the arithmetic mean of the amounts of the deviations of the characteristic
values from their mean.

2. Measures to describe statistical distributions 46
 Measures of variation

We recall the median and the quartiles Q1 ≤ Q2 = xMed ≤ Q3 , that divide the ordered
data set into four approximately equally sized parts.

Definition:
The difference
IQR := Q3 − Q1
is known as the interquartile range.

Definition:
The arithmetic mean of the deviation of the quartiles from the median is called the quar-
tile deviation or semi-interquartile range

(Q3 − Q2 ) + (Q2 − Q1 ) IQR
QD := =
2 2

2. Measures to describe statistical distributions 47
 Measures of variation

Example:
For a data set with n = 14 values we are looking for the quartile deviation.

As median we take the arithmetic mean of both neighbours and obtain Q2 = xMed = 26.8.

2. Measures to describe statistical distributions 48
 Variance and standard deviation

These are the most important measures of variation in statistics:

Definition:
The average quadratic deviation from the arithmetic mean
n
2 1X
sX := (xj − x̄ )2
n
j =1

is called empirical variance or in short variance of an observed data set X.

Calculation also using relative frequencies:
k
X
2 2
sX := hj (xj − x̄ )
j =1

Definition: The positive root of the variance
q
sX := + sX2

is called standard deviation.

2. Measures to describe statistical distributions 49
 Variance and standard deviation
Example

Pk 2
Variance calculation using relative frequencies: sX2 := j =1 hj (xj − x̄ )
The following distribution is given:

xi 4 5 6
1 1 1
hi
4 2 4

The arithmetic mean is x̄ = 5. Its variance is
2 1 2 1 1
sX = (4 − 5) ·+ (5 − 5)2 · + (6 − 5)2 ·
4 2 4
1 1 1
= +0+ =
4 4 2

and its standard deviation is
r
1 1
sX = = √ ≈ 0.7071.
2 2

2. Measures to describe statistical distributions 50
 Variance and standard deviation
Example

For the data set

3 5 9 9 6 6 3 7 7 6 7 6 5 7 6 9 6 5 3 5

consisting of 20 numbers, we use the following working table:

Arithmetic mean : 6
Variance : 3.1
Standard deviation: 1.761

2. Measures to describe statistical distributions 51
 Variance and standard deviation

The variance can also be calculated for density functions.
Example: Assume that the distribution of a statistical variable has been approximated by
a frequency density function h(x ) in the interval 0 < x < 2 given by the parabola
( As the graph shows, for symmetry reasons, the
3
x − 12 x 2


x ∈ (0, 2)
h (x ) = 2 mean value is equal to 1. To calculate the value,
0 otherwise. the summation symbol is replaced by the integral

Z∞
x̄ = x · h(x ) dx
−∞

In the same way the variance is calculated by

Z∞
2
sx = (x − x̄ )2 h(x ) dx
−∞

2. Measures to describe statistical distributions 52
 Variance and standard deviation

Example (continued): Hence we calculate the variance as the definite integral

Z2 Z2  
2 2 23 1 2
sX = (x − x̄ ) h(x ) dx = (x − 1) x− x dx
2 2
0 0

Z2  
3 5 2 3 1 4
= x− x + 2x − x dx
2 2 2
0
 2
3 1 2 5 3 1 4 1 5
= x − x + x − x
2 2 6 2 10 0
 
3 4 40 16 32 24 1
= − + − = 3 − 10 + 12 − =
2 2 6 2 10 5 5
q
1
and the standard deviation as its root: sX = 5
≈ 0.4472.

2. Measures to describe statistical distributions 53
 Variance and standard deviation

Properties of the variance

1. The variance is always greater than or equal to zero:
2
sX ≥ 0

2. Shifting all values of a data set X by the constant value a leaves the variance
unchanged:
2 2
yi := xi + a ⇒ sY = sX
3. Multiplication of all values of a data set X by a constant factor b multiplies the
variance by the square of this value:
2 2 2
zi := b · xi ⇒ sZ = b · sX

Note: sZ = |b| sX

2. Measures to describe statistical distributions 54
 Variance and standard deviation

S TEINER’s translation theorem
For each constant d ∈ R it holds that
n n
1X 1X
(xj − x̄ )2 = (xj − d )2 − (x̄ − d )2 (1)
n n
j =1 j =1

where (x̄ − d ) is the shift (=translation) from the mean.

Properties of the variance (contd.)

4. In the special case of d = 0, the following formula for the simplified calculation of
the variance is obtained
n
2 1X 2 2 2
sX = xj − x̄ = x 2 − x̄ (2)
n
j =1

Exercise : Use formula (2) to recalculate the variances of the preceding examples.

2. Measures to describe statistical distributions 55
Minimum property of the variance
Since in the translation theorem (1) the term (x̄ − d )2 can never be negative, for every d ̸= x̄ it
always holds
n n
1X
2 1X
2
xj − x̄ < xj − d.
n n
j =1 j =1

This means that the average quadratic deviation from the arithmetic mean x̄ is always smaller than
the average quadratic deviation from any other value d (minimum property). Multiplying the equation
by n, we get for the sum of the squared deviations, orthe residual sum of squares (RSS), from any
d ∈ R:
n n
X
2 X
2
RSS(d ) := xj − d ≥ xj − x̄.
j =1 j =1

That is, RSS becomes minimal in x̄. This provides us with an alternative definition of the mean:

Definition:
RSS(d ) −→ min
d

⇒ Principle of least squares.

55 - 1
 Variance and standard deviation

Definition:
The quotient of the standard deviation and the absolute value of the mean of a data set
with x̄ ̸= 0
sX
CVX :=
|x̄ |
is called the coefficient of variation.

The coefficient of variation is a relative measure. It measures the dispersion relative to
the level or absolute size of the data set and thus makes sets with different scales
comparable.

2. Measures to describe statistical distributions 56
 Variance and standard deviation

Example:
Over a period of 250 trading days, the Volkswagen share
price had a mean value of 174.56 C and a standard
deviation of 10.28 C. For the same period, a standard
deviation of 4.68 C with a mean value of 36.96 C is
determined for the BMW AG share. The two coefficients
of variation as a measure of the volatility of the share
prices are as follows

10.28 C
CVX = = 0.0589 for VW and
174.56 C
4.68 C
CVY = = 0.1266 for BMW
36.96 C
Thus, despite a lower absolute standard deviation, BMW stock is more volatile in relative
terms.

2. Measures to describe statistical distributions 57
 Robust measures

The measures presented so far are quite sensitive to outliers. This means that strong
deviations of individual values significantly influence these measures. This is not the
case with so-called robust measures.

Definition:
Starting with the raw data
x = (x1 , x2 ,... , xn )
of a data set of size n, the characteristic values xi are arranged in ascending order:

x(1) ≤ x(2) ≤ · · · ≤ x(n).

The resulting list
x( ) = (x(1) , x(2) ,... , x(n) )
is called an ordered sample (for the raw data x).

Annotation:
In the following, the parentheses in the index are omitted for ordered samples. It should always be
clear from the context whether a data set is ordered or not.

2. Measures to describe statistical distributions 58
 Median

First order and renumber the observed values:

x1 ≤ x2 ≤ x3 ≤ · · · ≤ xi ≤ · · · ≤ xn.

New indexing is also called „rank“.

Definition: A number xMed with

relF(X ≤ xMed ) ≥ 50 %
relF(X ≥ xMed ) ≥ 50 %

is called the median or central value of the empirical data set X.
For an even number n it can happen that the median is not uniquely determined. For a
unique value we define

x n + 1 if n odd
xMed = 1 2 
 2 x n + x n +1 if n even
2 2

2. Measures to describe statistical distributions 59
 Median

Outliers tend to influ-
Example: ence the mean, but not
the median.
The data set

4 7 7 7 12 12 13 16 19 23 23 97

has the arithmetic mean x̄ = 20
and the median xMed = 12.5

2. Measures to describe statistical distributions 60
Annotation:

With the definition of the median via the relative frequencies

relF(X ≤ xMed ) ≥ 50 %
relF(X ≥ xMed ) ≥ 50 %

one obtains the potentially non-unique definition
(
xMed = x n+1 if n odd,
2
x n ≤ xMed ≤ x n +1 if n even.
2 2

Strictly speaking, in the previous example, 12 or 13 or 12.2 would also be medians, since they divide
the data in the middle as well.

60 - 1
In practice, the arithmetic mean and the median are the most important characteristic measures of
location for a given distribution. Colloquially, however, a distinction is not always made between the
two measures, especially when it comes to income or wealth distributions.

Example: Median income is the income for
which there are just as many people with a
higher income as with a lower income. Me-
dian income, which is explicitly not identical
with average income, is used in the social sci-
ences and economics to undertake poverty
calculations, for example. It is more robust
against outliers in a sample and is therefore
often preferred to the arithmetic mean (aver-
age).

Think about when and why the average income differs from the median income?

60 - 2
 Quartiles

In addition to the median, two other values can be defined that further divide the ordered
statistical data set:

Definition:
The characteristic values of the data set are arranged in ascending order

x1 ≤ x2 ≤ · · · ≤ xn

and divided into four segments with (as far as possible) the same number of values.
The three values
Q1 ≤ Q2 = xMed ≤ Q3
are called quartiles and are defined in such a way that they lie in beween the four
segments just as the median xMed does.
Consequently about 50 % of the observations are found between Q1 and Q3.

Median and quartiles more general quantiles

2. Measures to describe statistical distributions 61
 Quantiles

Definition:
A number x[q ] with 0 < q < 1 is called q-quantile if it splits the data set X such that at
least 100 · q % of its observed values are less than or equal to x[q ] and at the same time
at least 100 · (1 − q )% are greater than or equal to x[q ] , that is:

relF(X ≤ x[q ] ) ≥ q and relF(X ≥ x[q ] ) ≥ 1 − q.

Special quantiles:

Quartiles:

Q1 = x[0.25] lower quartile
Q2 = x[0.5] = xMed Median
Q3 = x[0.75] upper quartile

Deciles: x[0.1] , x[0.2] , x[0.3] ,... , x[0.9]
Percentiles: x[0.01] , x[0.02] , x[0.03] ,... , x[0.99]

2. Measures to describe statistical distributions 62
 Quantiles

Calculation of the q-quantiles:
For continuously approximated distribution functions, the following holds for the
q-quantiles
H (x[q ] ) = q ,
This yields the q quantiles from the inverse of the distribution function,

x[q ] = H −1 (q )

This also works for step function shaped distribution functions if one directly hits a jump.
However, if one lands on a stairstep, the inverse function is not uniquely determined.
Then, in fact, every value between the adjacent jumps is a q-quantile:

xi ≤ x[q ] ≤ xi +1.

To obtain a unique value, one then usually takes the arithmetic mean of both jumps
x[q ] = 21 (xi + xi +1 ).

2. Measures to describe statistical distributions 63
 Quantiles

2. Measures to describe statistical distributions 64
 Quantiles

For a data set, the q-quantile can also be determined without the detour via the graph of
the distribution function

The q-quantile of an ordered data set x1 ,... , xn is determined by
(
1
2
(xn·q + xn·q +1 ) if n · q is an integer
x[q ] =
x⌈n·q ⌉ otherwise

Here ⌈n · q ⌉ means that the number n · q is rounded up to the nearest integer.

2. Measures to describe statistical distributions 65
 Quantiles
Example

Table: Turnover of large industrial companies in Germany (2005, in million C)

Company Turnover Company Turnover

20 DaimlerChrysler 149 776 10 Bayer 27 383
19 Volkswagen 95 268 9 Shell Deutschland 24 300
18 Siemens 75 445 8 RAG AG 21 869
17 E.ON 51 854 7 Hochtief 14 854
16 BMW 46 656 6 MAN 14 671
15 BASF 42 745 5 Continental 13 837
14 ThyssenKrupp 42 064 4 Henkel 11 974
13 Bosch 41 461 3 ZF Friedrichshafen 10 833
12 RWE 40 518 2 EnBW 10 769
11 Deutsche BP 37 432 1 Vattenfall 10 543

1 1
x[0.80] = 2
(x16 + x17 ) = 2
(46 656 + 51 854) = 49 255

2. Measures to describe statistical distributions 66
 Quantiles
Example (cont’d)

150 000

120 000

90 000

60 000 80 %-quantile = 49 255

30 000

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
Turnover of 20 industrial companies and 80 % quantile

2. Measures to describe statistical distributions 67
 Quantiles
Example

2. Measures to describe statistical distributions 68
 Five-point summary and box plot

The distribution of a data set can be analyzed quite well with only a few values. In
practice, one often uses the so-called five-point summary.

(xmin , x[0.25] , xMed , x[0.75] , xmax )

It divides the data set into four parts, so that each part contains about a quarter of the
observed values. It contains the median as a measure of location and the range and
interquartile range IQR as measures of variation.

Definition:
The graphical representation of the five-point summary is called a box plot.

xmin xmax

x[0.25] xMed x[0.75]

2. Measures to describe statistical distributions 69
 Control questions

1. What is the central property of the arithmetic mean?

2. When is the arithmetic and when is the geometric mean used and why?

3. How does the variance change if all values of a data set are converted from DM to
euro?

4. Describe the translation theorem as a property of the variance! What feature results
from the special case d = 0?

5. What is the minimum property of the variance? What does the principle of least
squares mean in this context?

6. What does the coefficient of variation mean? Which measure from portfolio theory in
business administration comes to your mind?

2. Measures to describe statistical distributions 70
 3 Two dimensional distributions

3.1 Scatterplot and joint distribution...................................................... 72
3.2 Marginal distributions................................................................. 77
3.3 Conditional distributions and statistical correlations................................... 82
3.4 Covariance........................................................................... 90
3.5 Correlation coefficient................................................................ 94
3.6 Rank correlation...................................................................... 99

according to: [Schira, 2016], chapter 3
see also: [Anderson et al., 2012], chapter 3.5
and [Newbold et al., 2013], chapter 2.4

3. Two dimensional distributions 71
 Scatterplot and joint distribution

Multi-dimensional statistics:
Each statistical unit ωi of a population Ω can have a variety of characteristics.

Definition:
The univariate statistics takes only one characteristic or variable into account.
The multivariate statistics considers several variables for each unit ωi

X1 (ωi ), X2 (ωi ),... , Xm (ωi )

Example:
For a person ωi we measure the duration of education X1 (ωi ) and the income X2 (ωi ) five
years past to the end of education.

3. Two dimensional distributions 72
 Scatterplot and joint distribution

Most simple case: two variables X (ωi ) andY (ωi ) are of interest.
The result is paired data (xi , yi ) for each ωi.
These can be represented as points

P1 := (x1 , y1 ), P2 := (x2 , y2 ),..., Pn := (xn , yn )

in a scatter plot.

3. Two dimensional distributions 73
 Scatterplot and joint distribution

Definition: The contingency table represents the joint distribution of the statistical
variables X and Y in a concise way.

y1 y2... yj... yl Σ
x1 n11 n12... n1j... n1l n1
x2 n21 n22... n2j... n2l n2.................. sum of row
xi ni1 ni2... nij... nil ni..................
xk nk 1 nk 2... nkj... nkl nk
Σ n 1 n 2... n j... n l n total sum

sum of column
Here
nij = absF(X = xi ∩ Y = yj ) is the absolute frequency with which the combination
(xi , yj ) was observed,
Pl Pk
ni = j =1 nij or n j = i =1 nij the absolute frequency with which xi or yj was
observed. ⇒ marginal frequency

3. Two dimensional distributions 74
 Scatterplot and joint distribution

Real life example: Routes of three soccer players at Bayern Munich

Task: Match the following players to their respective contingency tables:
1. Thomas Müller
2. Franck Ribéry
3. Arjen Robben

A B C

This representation of the contingency table is also called a heat map.
Solution: 1B, 2C, 3A

3. Two dimensional distributions 75
 Scatterplot and joint distribution

A representation with relative frequencies is also common. For this purpose, the
absolute frequencies, including the marginal frequencies, are divided by n.

y1 y2... yj... yl Σ
x1 h11 h12... h1j... h1l h1
x2 h21 h22... h2j... h2l h2.................. sum of row
xi hi1 hi2... hij... hil hi..................
xk hk 1 hk 2... hkj... hkl hk
Σ h 1 h 2... h j... h l 1 total sum

Here sum of column

hij = relF(X = xi ∩ Y = yj ) is the relative frequency with which the combination
(xi , yj ) was observed,
Pl Pk
hi = j =1 hij or h j = i =1 hij the relative frequency with which xi or yj was
observed. ⇒ marginal frequency

3. Two dimensional distributions 76
 Marginal distributions

Definition:
The one-dimensional distributions
ni
hi = relF(X = xi ) = , i = 1,... , k
n

and
n j
h j = relF(Y = yj ) = , j = 1,... , l
n

are called marginal distributions of the statistical variables X and Y.

3. Two dimensional distributions 77
 Marginal distributions

Calculation of mean and variance:
The mean and variance of individual components X and Y of two- or multidimensional
random variables are easily calculated using the marginal distributions (for cardinally
measurable variables):
k
X l
X
x̄ = hi xi ȳ = h j yj
i =1 j =1
k
X l
X
2 2 2 2
sX = hi (xi − x̄ ) sY = h j (yj − ȳ )
i =1 j =1

3. Two dimensional distributions 78
 Marginal distributions
Example

Abstract calculation example for a two-dimensional frequency distribution:

Characteristic values for X : x1 = 30, x2 = 60; andY : y1 = 1, y2 = 2, y3 = 4

Observed data: (30, 1), (30, 2), (60, 4), (30, 2), (60, 1), (30, 4),... , (60, 2).

Sort and count: 24 × (30, 1), 24 × (30, 2), 32 × (30, 4),... , 68 × (60, 4)

Contingency table
Y
1 2 4
30 24 24 32 80
X
60 16 36 68 120
40 60 100 200

3. Two dimensional distributions 79
 Marginal distributions
Example

The relative frequencies are obtained by dividing all values by n = 200

Y

marginal distribution of X
1 2 4
30 0.12 0.12 0.16 0.4
X
60 0.08 0.18 0.34 0.6
0.2 0.3 0.5 1

marginal distribution of Y

3. Two dimensional distributions 80
 Marginal distributions
Example

The marginal distribution for X :
k
X
x̄ = hi xi = 48
xi 30 60 i =1
k
hi 0.4 0.6 2
X 2
sX = hi (xi − x̄ ) = 216
i =1

The marginal distribution for Y :
l
X
ȳ = h j yj = 2.8
yj 1 2 4 j =1
l
h j 0.2 0.3 0.5 2
X 2
sY = h j (yj − ȳ ) = 1.56
j =1

3. Two dimensional distributions 81
 Conditional distributions and statistical correlations

We now consider the distribution of X , given that (conditional on) Y has a fixed value yj.

Definition:
Normalizing the columns of the contingency table to a column sum of 1 leads to a total
of l one-dimensional distributions for j = 1,... , l. These are called conditional distri-
butions of X (conditional on Y = yi ),
hij
hi |Y =yj = relF(X = xi |Y = yj ) =.
h j

Similarly, normalizing the rows to a row sum of 1 for i = 1,... , k leads to the conditional
distributions of Y (conditional on X = xi ),
hij
hj |X =xi = relF(Y = yj |X = xi ) =.
hi

3. Two dimensional distributions 82
 Conditional distributions and statistical correlations

Example:
For the joint distribution of the previous numerical example, there are three conditional
distributions of X and a marginal distribution of X :

X hi |Y =1 hi |Y =2 hi |Y =4 hi
30 0.60 0.40 0.32 0.4
60 0.40 0.60 0.68 0.6
1 1 1 1... and two conditional distributions of Y and a marginal distribution of Y

Y 1 2 4
hj |X =30 0.300 0.300 0.400 1
hj |X =60 0.133 0.300 0.567 1
h j 0.2 0.3 0.5 1

Observation: The conditional distributions differ. This gives an indication of a
dependence of the statistical variables X andY.

3. Two dimensional distributions 83
 Conditional distributions and statistical correlations

Definition:
If the joint distribution hij of the statistical variables X and Y is equal to the product of
the two marginal distributions
hij = hi · h j
fori = 1,... , k andj = 1,... , l, then X and Y are called statistically independent.

Otherwise, there is a statistical correlation. We can distinguish between linear and
nonlinear statistical correlations.

3. Two dimensional distributions 84
 Conditional distributions and statistical correlations

Properties of independent statistical variables
For independent statistical variables, the conditional distributions are identical and
equal to the marginal distribution.

Thus, for all j = 1,... , l conditional distributions of X , it holds that

hi |Y =yj = hi , i = 1,... , k

and for all i = 1,... , k conditional distributions of Y

hj |X =xi = h j , j = 1,... , l

3. Two dimensional distributions 85
 Conditional distributions and statistical correlations

Practical example: stock returns in the US (since 1963)
Are daily stock returns on announcement days (AD = FED meetings and labor statistics)
different from non-announcement days (ND)?

absolute frequency
≤−2 % (−2 %,−1 %] (−1 %,0 %] (0 %,1 %] (1 %,2 %] >2 %

AD 27 63 305 385 111 31 922
ND 286 963 4341 5349 1003 264 12206
313 1026 4646 5734 1114 295 13128

relative frequency
≤−2 % (−2 %,−1 %] (−1 %,0 %] (0 %,1 %] (1 %,2 %] >2 %

AD 0.0021 0.0048 0.0232 0.0293 0.0085 0.0024 0.0702
ND 0.0218 0.0734 0.3307 0.4074 0.0764 0.0201 0.9298
0.0238 0.0782 0.3539 0.4368 0.0849 0.0225 1

3. Two dimensional distributions 86
 Conditional distributions and statistical correlations

conditional distribution
≤−2 % (−2 %,−1 %] (−1 %,0 %] (0 %,1 %] (1 %,2 %] >2 %

hj |X =AD 0.0293 0.0683 0.3308 0.4176 0.1204 0.0336 1
hj |X =ND 0.0234 0.0789 0.3556 0.4382 0.0822 0.0216 1
h j 0.0238 0.0782 0.3539 0.4368 0.0849 0.0225 1

Daily returns in the U.S. are dependent from AD or ND!

3. Two dimensional distributions 87
 Conditional distributions and statistical correlations

conditional distribution
≤−2 % (−2 %,−1 %] (−1 %,0 %] (0 %,1 %] (1 %,2 %] >2 %

hj |X =AD 0.0293 0.0683 0.3308 0.4176 0.1204 0.0336 1
hj |X =ND 0.0234 0.0789 0.3556 0.4382 0.0822 0.0216 1
h j 0.0238 0.0782 0.3539 0.4368 0.0849 0.0225 1

Daily returns in the U.S. are dependent from AD or ND!
Question: Given independence, how would the joint distribution look like if we keep the
marginal distributions the same?

relative frequency
≤−2 % (−2 %,−1 %] (−1 %,0 %] (0 %,1 %] (1 %,2 %] >2 %

AD 0.0702
ND 0.9298
0.0238 0.0782 0.3539 0.4368 0.0849 0.0225 1

3. Two dimensional distributions 87
 Conditional distributions and statistical correlations

Mean of the sum and the difference:
The elements ωi , i = 1,... , n, of a statistical mass Ω of extent n have been analyzed for
two characteristics, and the statistical variables xi = X (ωi ) and yi = Y (ωi ) have been
collected as paired data.
From both variables, both the means and the variances have been calculated.
It holds that:

The mean value of a sum (difference) is equal to the sum (difference) of the mean
values:
x + y = x̄ + ȳ x − y = x̄ − ȳ

This is true regardless of the joint distribution and equally true for statistically
independent as well as statistically dependent variables.

3. Two dimensional distributions 88
 Conditional distributions and statistical correlations

Variance of the sum and the difference:
The variance is calculated by applying the binomial formula:

Variance of the sum
n
2 2 2 1X
sX +Y = sX + sY + 2 · (xj − x̄ )(yj − ȳ )
n
j =1

Variance of the difference
n
2 2 2 1X
sX −Y = sX + sY − 2 · (xj − x̄ )(yj − ȳ )
n
j =1

Special case :

n
2 2 2 1X
sX ±Y = sX + sY , if cXY := (xj − x̄ )(yj − ȳ ) = 0
n
j =1

3. Two dimensional distributions 89
 Covariance

Definition:
The quantity calculated from the n pairs of values (xi , yi )
n
1X
cXY := (xj − x̄ )(yj − ȳ )
n
j =1

is called the empirical covariance or, in short, the covariance between the statistical
variables X and Y and is a measure for the linear dependency between X and Y.

Simplified calculation :

n
1X
cXY := xj · yj − x̄ · ȳ = x · y − x̄ · ȳ
n
j =1

3. Two dimensional distributions 90
 Covariance

Illustration of the covariance:

3. Two dimensional distributions 91
 Covariance

The covariance can also be calculated using the relative frequencies from the contin-
gency table:
k X
X l
cXY := hij (xi − x̄ )(yj − ȳ )
i =1 j =1

Simplified calculation :

k X
X l
cXY := hij xi yj −x̄ · ȳ
i =1 j =1
| {z }
x ·y

3. Two dimensional distributions 92
 Covariance
Covariance and dependency

Proposition :
If two variables X and Y are statistically independent, then the covariance cXY between
them is zero.

This proposition is not reversible because the covariance measures only the linear part of
the statistical dependence.

correct: X andY are independent ⇒ cXY = 0

correct: cXY ̸= 0 ⇒ X andY are linearly dependent

incorrect: cXY = 0 ⇒ X andY are independent

3. Two dimensional distributions 93
 Correlation coefficient

Definition:
The ratio
cXY
rXY :=
sX · sY
is called (empirical) correlation coefficient between X and Y

Scatter plots and correlation coefficients:

rXY = 0.97 rXY = −0.52 rXY = 0.06

3. Two dimensional distributions 94
 Correlation coefficient

Properties :

The correlation coefficient represents a normalized measure of the strength of the
linear statistical relationship:
−1 ≤ rXY ≤ 1
The absolute value of the correlation coefficient remains unchanged if one or both
variables are transformed linearly. Suppose that

U := a1 + b1 X and V := a2 + b2 Y with b1 , b2 ̸= 0.

Then we obtain
cUV b1 · b2 · cXY b1 · b2
rUV = = = rXY.
sU · sV |b1 | sX · |b2 | sY |b1 | · |b2 |

This means that |rUV | = |rXY |.

3. Two dimensional distributions 95
 Correlation coefficient

Example: Calculation of the correlation coefficient
For the joint distribution from the numerical example (slide 79 ff.), one obtains for the
covariance using the simplified calculation approach
2 X
X 3 2 X
X 3
cXY = hij (xi − x̄ )(yj − ȳ ) = hij xi yj − x̄ · ȳ = x · y − x̄ · ȳ
i =1 j =1 i =1 j =1

= 138 − 48 · 2.8 = 138 − 134.4 = 3.6

The correlation coefficient is thus

3.6
rXY = √ √ = 0.1961 ,
216 · 1.56
which indicates a weak positive correlation.

3. Two dimensional distributions 96
 Correlation coefficient
Examples

goals against

age of trainer
body weight

body height goals scored league position

Note: The covariance or the correlation coefficient do not necessarily mean a causal
relationship between the characteristics. Merely the just available observations show a
statistical tendency, which however could also be purely by chance.

Correlation of the day: www.correlated.org :-)

3. Two dimensional distributions 97
 Correlation vs. causality

Son’s height (inch)

Father’s height (inch)

causality?

correlation
Father’s height Son’s height

causality?

3. Two dimensional distributions 98
 Rank correlation

Besides the correlation coefficient according to B RAVAIS -P EARSON there is another one,
namely the one according to S PEARMAN, also called rank correlation coefficient.

Definition:
The rank correlation coefficient or correlation coefficient named after C HARLES E D -
WARD S PEARMAN
Sp
rXY := rrg(X ),rg(Y )
is the correlation coefficient between the ranks of the observations.

It is used for ordinally scaled characteristics.

3. Two dimensional distributions 99
 Rank correlation
Example school grades

The following table shows the results of the Abitur examinations of ten students in the
subjects German (feature G) and History (feature H). The maximum achievable score is
15 in each case.

Pupil i German (G) History (H) rg(G) rg(H)

1 13 15 4 1
2 14 8 2.5 (2) 4 (3)
3 8 1 9 10
4 10 7 7 6.5 (6)
5 15 9 1 2
6 1 5 10 9
7 14 8 2.5 (3) 4 (4)
8 12 7 5 6.5 (7)
9 9 6 8 8
10 11 8 6 4 (5)

3. Two dimensional distributions 100
 Rank correlation
Example school grades

Question: Are the grades correlated? Does good performance in German go along
with good knowledge of history?
First, we determine the rankings for each student in each of the two subjects. To do this,
we arrange the students according to the results they obtained in the subjects. Students
with the same result are assigned the arithmetic mean of those rankings they would have
received if they had been arranged randomly (given in parentheses in each case). This
may result in rankings like 2.5 or 6.5.
Then we compute variances, standard deviations, and the covariance of the ranks and
obtain with
Sp 6.95
rGH = = 0.8581
2.8636 · 2.8284
a fairly positive correlation, which was to be expected.
(Compare: rGH = 0.549 )

Question: When should rank correlation be preferred to normal correlation?

3. Two dimensional distributions 101
 Control questions

1. What is the difference between univariate and multivariate statistics? Think about an
example of bivariate statistics.

2. What is the structure and function of contingency tables? Are there also contingency
tables for more than two characteristics?

3. How many marginal distributions does a 3-dimensional statistical distribution have?

4. When is the variance of a sum smaller than the sum of the variances?

5. What is statistical independence? What is the relationship between covariance and
independence?

6. What is the meaning of the correlation coefficient? Does an empirical correlation
coefficient of 0 imply that there is no factual relationship between the characteristics
under consideration?

7. What is a rank correlation? How do you measure it?

3. Two dimensional distributions 102
 4 Linear regression

4.1 The regression line.................................................................. 104
4.2 Properties of regression lines....................................................... 110
4.3 Nonlinear and multiple regression...................................................118

according to: [Schira, 2016], chapter 4
see also: [Anderson et al., 2012], chapter 14;
and [Newbold et al., 2013], chapter 11
4. Linear regression 103
 The regression line

Correlation and regression calculation:
Covariance and correlation coefficient are only measures. In correlation analysis, the
statistical variables (X , Y ) are considered completely equal.
The regression calculation goes one step further: The average linear relationship
between the characteristic values of a two-dimensional statistical variable (X , Y ) is now
to be represented by a linear function, i.e. a straight line

y = a + bx

in the scatter plot. Here we distinguish between an (in the mathematical sense)
independent variable X and a dependent variable Y.

This straight line is supposed to be a mean straight line, that is, it is supposed to pass
through the observed characteristic values (xi , yi ) in such a way that it indicates the
location and main direction of the point cloud in the scatter plot.

4. Linear regression 104
 The regression line
Example

scatter plot regression line

4. Linear regression 105
 The regression line

y = a + bx

„deviation“ ei

Point cloud and straight line in scatter plot

The method of least squares (LSM) uniquely assigns a mean straight line to the scatter
plot.

4. Linear