FACTA UNIVERSITATIS  
Series: Economics and Organization Vol. 15, N

o
 2, 2018, pp. 177 - 187 

https://doi.org/10.22190/FUEO1802177T 

© 2018 by University of Niš, Serbia | Creative Commons Licence: CC BY-NC-ND 

Review Paper 

MODELS OF DISTRIBUTION OF GDP AT THE GLOBAL LEVEL
1
 

UDC 658.86/.87(100) 

Zoran Tomić*, Ognjen Radović 

University of Niš, Faculty of Economics, Serbia 

Abstract. The problem of distribution has been drawing the attention of researchers for 

years. In their research they analyze the uniformity of distribution using Pareto model of 

distribution, the Lorenz curve and the Gini coefficient. Also some authors are testing the 

applicability of models from statistical physics to the problem of distribution to better 

describe it. In addition to the analysis of distribution at the level of states and certain groups 

such as the Forbes list, the problem is spreading to the global level, where we analyze the 

distribution of GDP as a measure of the wealth of individual countries.  

In this paper we analyzed the distribution of GDP of countries applying the Pareto 

model, Lorenz curve, Gini coefficient and Boltzmann Gibbs distribution from statistical 

physics. The analysis was done for 2015, while the Gini coefficient analysis was done 

during the period from 1990 to 2015. 

Key words: The distribution of wealth, GDP, Pareto distribution, Lorenz curve, 

Gini coefficient, Boltzmann Gibbs distribution 

JEL Classification: D31, R12, C46 

INTRODUCTION 

For macroeconomic policy holders, it is important to consider the distribution of 

wealth. One of the goals that every government wants to achieve is the satisfactory rate of 

economic growth and development. Besides a large number of indicators, according to 

Cvetanović (2005) the degree of uniformity of distribution of wealth occupies an 

important place. 

One of the aspects of the impact of policy development is the emergence of imbalances. 

Economic development is characterized by a marked inequality in time, space and population 

                                                           
Received December 04, 2017 / Revised April 12, 2018 / Accepted April 17, 2018 
Corresponding author: Zoran Tomić 
* 
PhD student at University of Niš, Faculty of Economics 

University of Niš, Faculty of Economics, Trg kralja Aleksandra 11, 18000 Niš, Serbia  
E-mail: zoranzoca@gmail.com 



178 Z. TOMIĆ, O. RADOVIĆ 

terms. Poor distribution of wealth and income in an economy can have negative effects on 

economic growth and development. The research by the World Bank in 1996 in the case of 

East Asia confirms that countries with a more even distribution of wealth and income have 

higher rates of economic growth. In each East Asian economy that has achieved solid 

economic growth rates in the period between 1965 and 1990, the inequality in income 

distribution was reduced (Kitanović & Golubović, 2006, p 345). 

The issue of distribution of wealth and money is topical today. A large number of 

authors studies the distribution of wealth and money using various models and types of 

distributions, of which Pareto is the most common. This model was successfully applied 

in the papers of Levy & Solomon (1997); Klass et al. (2006); Dunford et al. (2014). 

Over time, new models are forming that aim to better describe the distribution of wealth as 

the polynomial model by Oltean & Kusmartsev (2014). Also models from statistical physics 

which describe the process of money creation, exchange and distribution of wealth are used. 

These models made from statistical physics are gas models without savings, savings and 

uneven savings. Based on the well-known laws of thermodynamics these models describe 

economic processes of distribution. Some of the authors who have dealt with the development 

of these models are Yakovenko V. (2008), Dragulescu (2002) and Chakrabarti & Chatterjee 

(2003).  

As we have seen, economists and physicists are mainly engaged in the issue of distribution 

of money, wealth and income to the level of a particular community, such as a country's 

population. A small number of papers deals with the application of the model distribution of 

wealth at the global level, but where countries are taken as individual entities. This problem 

was dealt with by Dunford et al. (2014), and also by Skipper R. (2011). In their they have 

successfully applied the Pareto distribution model which showed that at the global level there 

is also uneven distribution of wealth, where GDP is taken as a measure of wealth of a 

particular country. Also in paper Dunford et al. (2014) analyzed whether Pareto's 80-20 rule 

applies, where it is determined that the rule applied in 1989, while in the later period it is not 

confirmed. 

The aim of this paper is to analyze the changes in disparities in the distribution of 

GDP at the global level by using Gini coefficient and checking whether the Pareto's 80-

20 rule applies or a new rule can be found to this type of distribution. In the second part 

of paper the goal is to see if Boltzmann Gibbs distribution can be applied for the analysis 

of distribution of GDP worldwide. 

1. DISTRIBUTION MODELS 

In economics Lorenz curve is often used to study the distribution of wealth, income or 

assets. This model was developed by Max Lorenz in 1905 to present the inequality of 

wealth distribution. In addition to this problem, this model is used to study the disparities 

in the size of plants in ecology and biodiversity studies. 

Together with the Lorenz curve, the Gini coefficient is used. The Gini coefficient was 

developed by the Italian statistician Corrado Gini and published in his paper "Variability 

and mutability". Its value represents the percentage of the area between the line of perfect 

uniformity of distribution and the observed Lorenz curve in the area between the two 

extreme positions of the Lorenz curve. This indicator is now often used as a measure of 

inequality in the distribution. The value ranges between 0 and 1. Higher values for the Gini 



 Models of Distribution of GDP at the Global Level 179 

coefficient indicates uneven distribution, while Gini = 1 means full uneven distribution 

(Cvetanović, 2005, p. 94-95). In order to get the true Pareto Principle "80-20", the value of 

the Gini coefficient should be around 0.76 (Dunford et al., 2014, p. 143). 

Vilfredo Pareto discovered in 1879 that the high levels of wealth (but also income) 

distribution is done according to the law degree distribution. Distribution parameters can be 

changed from one society to another, but regardless of the social and political conditions 

Pareto found that the distribution of wealth respects the general law of distribution, which is 

known as Pareto's law. If N is the number of people who have the wealth (money) exceeds 

the amount x, and A and α are constants, then N = A/x
α
 respectively, 

log( ) log( ) log( )N A x            (1) 

In other words, the amount of logarithmic number of people with wealth above a 

certain limit on the logarithmic graph is a straight line. The coefficient α is determined by 

the slope and the right and is called the Pareto exponent which determines the degree of 

uniformity of the distribution of resources in the observed population (Dunford Ret al., 

2014, p. 141). General Pareto distribution is given by the following probability density 

function: 

 
(1 )

0( ) ,P W c WrW fo W
 

  for                                       (2) 

 

where W is a wealth, P(W) is a function of density, Wo is the lower limit of the level of 

richness and C is a constant and α is known as the Pareto-exponent (Levy & Solomon, 

1997, p. 90). 

A number of researchers proved that the model is excellent with the empirical data 

(Class. et al., 2006), but with certain corrections of the model itself (Clementi & 

Gallegati, 2005, p. 3). In the last few years a lot of papers point out that Pareto model is 

not ideal for the description of the overall distribution of wealth, but describes perfectly 

only the lower part of distribution, i.e. the distribution between the richest of society 

(about 3 to 5%), while in the poorer part which relates to the problem of divergence, 

which is described by Boltzmann Gibbs distribution (Dragulescu, 2002, p. 10). 

This model of distribution has an important use as an indicator of the degree of 

inequality in the society in the distribution of the fluctuations in the stock markets (Levy 

& Solomon, 1997, p. 90). 

Pareto originally developed the model to describe the distribution of wealth among 

individuals, since it seemed that most of the wealth of the society is in the possession of a 

small number of the members of the same community. It is known as Pareto principle 

"80-20", which says that 20% of the population controls 80% of the wealth of the 

community. When the value of the Pareto exponent is equal to 1.16, this means that in the 

observed population there is the "80-20" principle (Dunford et al., 2014, p. 142). 

Many authors confirmed that the probability distribution and the cumulative 

probability of agent-based models can be described by Boltzmann Gibbs distribution in 

physics. A fundamental law of equilibrium in statistical physics is the Boltzmann Gibbs 

law, which states that the probability of P(ε) in order to find the physical system or sub-

system in a state of energy ε is determined by an exponential function: 

   



180 Z. TOMIĆ, O. RADOVIĆ 

( ) TP ce






        (3) 

In the equation c is the constant of normalization, and T is a temperature which is 

equal to the average energy per particle. The probability value may range to 1. In order 

equations described function in the system must apply the law of the conservation of 

energy, i.e. that is the summation of the energy that each particle has the same total sum 

of energy of the system that is constant and that the probability of the particles having 

energy equal to the sum of energy of two particles is equal to the probability that the 

product particles have a particle from that particular energy. 

Dragulescu and Yakovenko (2001) used Boltzmann Gibbs distribution to describe the 

distribution of money between agents: 

( )

m

TP m ce


     (4) 

where m is the amount of money that each agent has, and T is the "money temperature" 

that is equal to the average value of money which each agent has (Yakovenko, 2010). 

Dragulescu and Yakovlenko (2001) have shown that this model can be applied to 

describe the distribution of money and income on the example of the US and the UK. 

Based on the performance of the distribution function, it is obtained that the 

normalization constant is equal to the reciprocal value of "money temperature". 

For the purposes of this study we will use the Gini coefficient for the analysis of 

uneven distribution for the period 1990 - 2015, while we apply Pareto's model and 

Boltzmann Gibbs model for 2015. 

2. ANALYSIS OF THE EXISTENCE OF PARETO PRINCIPLE AT THE GLOBAL LEVEL  

In the analysis we used the statistical data for GDP from United Nations, and we 

looked at the value of GDP in US dollars. The reporting period was from 1990 to 2015 

for which data are available. The sample consists of 208 countries that existed in 2015 

and the analysis was done for those 208 countries. The analysis was performed in the 

program Gretl. 

Based on the values gained from the analysis that are seen in Figure 1 we can see that 

the value of the Gini coefficient in the period from 1990 to 1994 is moving upwards, 

indicating the increase of disparities in the distribution worldwide. This is the period of 

the disintegration of the USSR, Czechoslovakia and Yugoslavia, which has changed 

completely the distribution of power at the global level and the period of domination of 

the West and the USA lasted until 2002 when the Gini coefficient reached its maximum 

value. After that period, the distribution of power changes, as among the world's 

economies Asian tigers country are emerging, Russia is recovering from the period of the 

USSR disintegration and China is becoming more powerful. Also this is the period when 

BRICS slowly strengthen on the world economic scene, which leads to a drop in the 

value of the Gini coefficient which reaches its minimum value in 2013.  

Also since 2008, the economic crisis has contributed to increasing the uniformity of 

distribution, but the Gini coefficient rises again in the period after 2013. Figure 2 shows 

the Lorenz curve for 2015.  

 



 Models of Distribution of GDP at the Global Level 181 

 

Fig. 1 Value of the Gini coefficient for the period 1990 - 2015 
Source: Data processed by the author 

 

Fig. 2 Lorenz curve for 2015 
Source: Data processed by the author 



182 Z. TOMIĆ, O. RADOVIĆ 

The value of the Gini coefficient shows a high degree of uneven distribution of the 

value of GDP at the global level, which is certainly caused by a number of factors: 

population, natural resources, the size of the territory, the technological development of 

the country, the structure of the economy, the education system and so on. 

Based on the obtained value of the Gini coefficient when it comes to the distribution of 

GDP Pareto Principle does not apply because the Gini coefficient is much greater than the 

value necessary for the "80-20" rule, i.e. 0.76. It is better to say that for this distribution we 

can apply the "90-20" rule. This conclusion can be drawn from the values shown in Figure 

3 which shows the relationship between the value of the richness of individual groups of 

countries. 

Based on the values from Figure 3 in the initial period, the share of the richest 20% 

went up to nearly 95% of the total wealth, while in 2015 this amount was reduced to a 

little over 91%, which thus proves that when we talk about the distribution of GDP at the 

global level, the Pareto rule does not apply. Also it is important to note that here we took 

into account distribution between countries rather than among the population, as in all 

countries, there are small groups that are extremely wealthy compared to the rest, so for 

future research it would be interesting to try to determine whether the Pareto Principle 

applies in the distribution of wealth (income, money, etc.) at the level of individual 

countries or countries of the world. 

 
Fig. 3 Percent share in the global GDP per year 

Source: Data processed by the author 



 Models of Distribution of GDP at the Global Level 183 

3. PARETO AND BOLTZMANN GIBBS DISTRIBUTION OF GDP AT THE GLOBAL LEVEL 

Testing the Pareto distribution will start by using the equation (1) where we will 

determine whether we can apply the Pareto distribution to determine the distribution of 

GDP of countries on the basis of their rank. The analysis was carried out in the Origin 

program and the results were as follows. 

Based on the analysis in Origin and from Figure 4, we can see that the Pareto 

distribution function best describes the initial part of the distribution, i.e. distribution of 

GDP between the richest countries (the richest 42 countries, i.e. the richest 20%). This 

version of the Pareto distribution, Zipf's function can describe the distribution of wealth 

(GDP, money,...) only for the richest. The rest of the countries in the graph we see that it 

does not provide the best description of distribution, i.e. it is a country that ranked lower 

theoretical value different from the empirical value that is recorded. This finding was 

confirmed in the work of Skipper (2011) that this form of Pareto distribution can best 

describe just distribution of the world's richest countries. Also, many authors have tested 

the Pareto distribution and found that in the case of the distribution of wealth among 

individuals, the Pareto model is best to describe the 3-5% of the richest members of the 

population, while other models describe the rest of the mode of distribution, such as in 

the papers of Dragulescu and Yakovenko (2001). 

 
Fig. 4 Pareto distribution 

Source: Data processed by the author 

The following will apply the general Pareto distribution and Boltzmann Gibbs 

distribution to determine its applicability. 

 



184 Z. TOMIĆ, O. RADOVIĆ 

 
Fig. 5 Pareto distribution of nominal GDP 

Source: Data processed by the author 

 
Fig. 6 Boltzmann Gibbs distribution of nominal GDP 

Source: Data processed by the author 

Based on Figure 5, we can see that the Pareto distribution describes well the distribution 

of GDP at world level. Our analysis took into account the 208 countries which are divided 

into groups depending on the value of their GDP. The coefficient of determination is very 



 Models of Distribution of GDP at the Global Level 185 

high which shows that this model a 99.9% change in the value of the parameter described 

by this model. On the same data, we applied Boltzmann Gibbs model which is given by the 

equation (5) and the obtained results are shown in Figure 6. The Boltzmann Gibbs model 

describes well the distribution of GDP. The coefficient of determination in this case is 

somewhat lower than for the Pareto model.  

We can conclude that both models describe well the distribution of world GDP 

countries. These models describe individual distribution made, not cumulative. Regarding 

the cumulative distribution, it is shown that the Pareto distribution model best describes 

the observed distribution of the richest part of the population, while the Boltzmann Gibbs 

model best describes the distribution of the rest. We will test the data for the distribution 

of world GDP which can be seen in Figure 7. 

 

Fig. 7 The cumulative probability distribution 
Source: Data processed by the author 

Based on the analysis we can see that the combination of the Boltzmann and Gibbs 

and Pareto distribution perfectly describes the distribution of GDP at world level. We 

confirmed what Drăgulescu and Yakovenko (2001) stated in their work using this data. 

Specifically, the Pareto function describes the part that refers to the richest countries, 

while the poorest countries are best described by the Boltzmann Gibbs function. The 

information in the case of 208 countries are processed in groups of countries, depending 

on the value of the country's GDP. Based on the data we can conclude that the Pareto 

model perfectly describes the cumulative distribution relating to the distribution of wealth 

by 2.4% of the richest countries in the world, while the Boltzmann Gibbs distribution 

describes the distribution of the rest of the countries, which is another confirmation of the 

conclusions reached in the research by Dragulescu and Yakovenko (2001). 



186 Z. TOMIĆ, O. RADOVIĆ 

CONCLUSION 

The problem of the distribution of money and wealth attracted the attention of many 

researchers. In addition to the Pareto model, which is most commonly used, there are 

other models that have been designed by econophysicists, like the Boltzmann Gibbs 

model from statistical physics.  

In this paper we first analyzed the existence of Pareto's rule "80-20". We did not confirm 

the existence of this rule for the distribution of world GDP. In this paper we found that rule 

"90-20", i.e. 90% of the world GDP is created by 20% of the richest countries in the world (42 

countries in total), exists and can be used as the Pareto rule when it comes to distribution of 

the world GDP. In future research, we can try to see if the new form of Pareto "80-20" exists, 

i.e. 80% of the world GDP is owned by 20 richest countries. 

Secondly, in this paper we tested the Boltzmann Gibbs model of distribution to 

describe the distribution of GDP among countries worldwide. Using a sample of 208 

countries, we found that the Boltzmann Gibbs distribution can be applied to describe the 

distribution of a number of the poorest countries, while the Pareto model can be applied 

to describe the distribution between the richest countries.  

This finding confirms the research of Dragulescu and Yakovenko (2001) as well as 

other authors. They did theirs research on the examples of the problems of distribution of 

wealth among individuals. In a study in 2015, we showed that the Pareto distribution 

model describes the cumulative GDP of 2.4% of the world's countries, while the rest is 

described by the Boltzmann Gibbs distribution.  

Further studies can test the application of other models, such as the Gamma function, 

to describe the distribution of GDP, as well as work on theoretical grounds for the 

applicability of the model to describe the distribution. 

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Wealth Distribution (pp.3-14). New York:  Springer. 

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Skipper, R. (2011). Zipf ’s Law and Its Correlation to the GDP of Nations. The University of Maryland McNair 

Scholars Undergraduate Research Journal, 3, 2011, 217-226. 
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Statistical base of UN, http://unstats.un.org/unsd/snaama/dnltransfer.asp?fID=2, accessed 31.08.2017. 

MODELI DISTRIBUCIJE BDP NA SVETSKOM NIVOU 

Problem distribucije okuplja pažnju istraživača godinama unazad. U svojim istraživanjima se 

bave analizom ravnomernosti raspodele primenom modela Paretove distribucije, Lorencove krive i 

Gini koeficijenta. Postoje i radovi gde se testiraju primenljivost modela iz statističke fizike kako bi 

se problem distribucije što bolje opisao. Pored analize distribucije na nivou država i određenih 

grupa poput Forbsove liste, problem se širi na svetski nivou gde se analizira distribucija BDPa kao 

mere bogatstva pojedinih zemalja. 

U ovom radu analizirali smo distribuciju BDPa zemalja primenom Paretovog modela, 

Lorencove krive, Gini koeficijenta i Bolcman Gibsove raspodele iz statističke fizike. Izvršena je 

analiza za 2015. godinu, dok je na osnovu Gini koeficijenta izvršena analiza dinamike promene 

ravnomernosti distribucije u periodu od 1990. do 2015. godine. 

Ključne reči: Distribucija bogatstva, BDP, Paretova distribucija, Lorencova kriva, Gini koeficijent, 

Bolcman Gibsova raspodela