.


International Journal of Economics and Financial 
Issues

ISSN: 2146-4138

available at http: www.econjournals.com

International Journal of Economics and Financial Issues, 2016, 6(4), 1965-1972.

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 2016 1965

Innovative Approach to the Development of the Logistics System 
of Supply of the Arctic Region Space

Mikhail Nikolayevich Dudin1*, Natalia Pavlovna Ivashchenko2, Еvgenia Еvgenevna Frolova3,  
Aslan Huseynovich Abashidze4, Anait Sergeevna Smbatyan5

1Russian Presidential Academy of National Economy and Public Administration, 82, Vernadsky prosp., Moscow 119571, Russian 
Federation, 2Lomonosov Moscow State University, GSP-1, Leninskie Gory, Moscow 119991, Russian Federation, 3Pеоples 
Friendship University of Russia (RUDN University), 6, Miklouho-Maclay Street, Moscow 117198, Russian Federation, 4Pеоples 
Friendship University of Russia (RUDN University), 6, Miklouho-Maclay street, Moscow 117198, Russian Federation, 5ANO 
“Centre of Expertise for the World Trade Organization,” 8/1, Pokrovsky Boulevard, Moscow 109028, Russian Federation.  
*Email: dudinmn@mail.ru

ABSTRACT

This article reviews the basic methodological approaches to the arrangement of the logistics supply of manufacturing, research or tourism facilities 
based in the Arctic. The main purpose of this article was to optimize the processes of supply the Arctic territories with the use of high-tech approach, 
which integrates the concept of “green” logistics technology (reverse logistics, in particular) and methods of economic and mathematical modeling 
for inventory management and planning the purchase of resources necessary to ensure the proper functioning of the Arctic facilities. Taking into 
account the fact that the Arctic holds interests of many countries and corporations, as well as taking into account the fact that further development of 
the Arctic must be environmentally responsible, the integration of traditional and new approaches to the arrangement of supply of the Arctic facilities 
through the use of reverse logistic technologies of economic and mathematical modeling using the correlation-regression analysis were proposed.

Keywords: Arctic, Supply Logistics, Reverse Logistics, Correlation-regression Analysis, Ecosystem, Environmental Responsibility 
JEL Classifications: Q57, Q28

1. INTRODUCTION

Development and exploration of the Arctic region is currently 
unfolding very actively in both scientific and industrial production 
context. Almost all countries that are part of the Arctic Council 
have their own strategies for development of the Arctic, but only 
five countries (Russia, the USA, Canada, Denmark and Norway) 
have direct access to the coast of the Arctic Ocean. Given that the 
territorial disputes between the five Arctic states in many respects 
are still not completed, the competition for the most rapid, effective 
and large-scale development of the Arctic is constantly increasing 
(Lukin, 2010; Smith, 2010; Mazur, 2010).

Along with increased competition, there is also diversification of 
approaches to the exploitation of natural and resource potential 
(Chater, 2012; Cooke, 2011; UNESCO, 2009; Hodgson, 2007). For 

example, the US abandoned the development of some deposits of 
hydrocarbon resources on their part of the shelf in 2015, but did not 
fold the scientific and research activities. Russia, Canada, Norway 
and Denmark are planning to develop the Arctic tourism and create 
a new transport infrastructure (Northern Sea Route, transnational 
northern transportation network with the arrangement of cross-
polar flights). In the meantime, Russia does abandon its deposits 
on the Arctic shelf, large-scale in development and commercial 
operation, even despite the fact that many transnational mining 
corporations have left the Arctic or folded (suspended) facilities 
for the exploration, development and production of hydrocarbon 
resources in this region.

Due to the fact that the Arctic will not lose its commercial and 
scientific appeal in the long run, it can be assumed that the traffic 
flows in this region will show a constant increase in the near future. 



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 20161966

This is primarily due to the fact that it is impossible to conduct 
commercial or research activities in the Arctic without optimally 
organized logistics of supply.

2. METHODS

We use an integrated knowledge-intensive approach to 
optimization of the Arctic logistics in this article, using an 
environmentally-focused concept and methods of economic and 
mathematical modeling. The article suggests using correlation-
regression analysis for inventory management and procurement 
planning (Orlova et al., 2015; Box et al., 2015), which allows to 
define the conditional expectation of one dependent variable (y) 
as a function of a set of independent variables (xi) in terms of 
the nth number of observations taking into account the regression 
coefficients (βi) and the random component (ε):

yi=β1+β2 x2+…+βk xki+εi,i=1,…,n (1)

A special correlation coefficient (r) is calculated in order to 
identify or determine the relationship between the effective and 
factorial signs:

r
x-x y-y

x-x y-y
2 2

=
( )( )

( ) ( )
∑
∑ ∑  (2)

It is recommended to use a standardized Wilson formula or one of 
its modifications to calculate the optimal and economically feasible 
size of the order for the supply of certain resources (Bowersox 
et al., 1991):

Q=
2CR

H
 (3)

Where:
Q is the optimal size of the order for the supply of resource 
(resources);
C is costs of order placement;
R is the planned demand for resources (the required number of 
units);
H is the costs associated with storing the unit of the reserves.

We gave developed the following formulas to calculate the 
individual parameters of the economic and mathematical 
model proposed in the article and recommended for inventory 
management and planning of the resources procurement for the 
functioning of the Arctic facilities:

S=eb-ed+↓et (4)

L
T=1-

nL
∑
∑

 (5)

I=
sq

w
 (6)

Where:

S is environmental damage from supply to the Arctic facilities and 
their storage of secondary resources to be exported to the mainland 
for disposal or recycling, corrected and assessed in terms of value;

T is stability and reliability of resource supplies carried by the 
logistics aggregator to the Arctic facilities;

I is a coefficient of immobilization of resource reserves at the 
Arctic facilities;

eb, ed, ↓et are respectively the economic (cost) assessment of the 
benefit of functioning of the Arctic facility, the environmental 
damage it causes, and the level of decline in environmental damage 
per unit of purchased resource or stored reserve;

ΣL и ΣnL are the total amount of supplies of resources to the 
Arctic facilities carried, respectively, in violation of the terms 
and conditions of the supply contracts and in compliance with the 
terms and conditions of the supply contracts;

sq and w are a shaped reserve of resources that are stored at the 
Arctic facility and the planned demand for resources (units of 
reserve and units of supply).

3. RESULTS

The World Ocean can be considered as a global transport system, 
which provides up to 80% of the total cargo turnover transported 
using the water transport. At the same time, the main burden of the 
cargo transportation in the share distribution falls on the Atlantic 
Ocean (Figure 1).

The Arctic Ocean provides only 5% of the world maritime cargo 
turnover. But at the same time, it is an important transport route 
for Russia and European countries (Norway, Denmark, Iceland). 
For example, the Northern Sea Route provides Russia with 
transportation of about 40 mln tons of various cargoes. At the same 
time, more than 70% is transportation of dry cargo, the rest is liquid 
cargo. There is a year-round navigation by the Norwegian coast; 
the main cargo is fish, liquid and solid hydrocarbons, iron ore and 
timber. Greenland and Denmark regularly carry out transportation 
of various cargoes: Greenland supplies fish and mining products, 
while Denmark supplies food and consumer goods. Coasting 
trade is very well developed in the coastal waters of Iceland. The 
North-West Passage (along the coast of North America through 
the Canadian Arctic Archipelago) is less often used (Tsetlin and 
Krasnova, 2014, The Arctic Council, 2016).

The Arctic Ocean is also used for the military and defensive 
purposes. During the Second World War, the path of the Arctic 
convoys went through the European part. Currently, the Royal 
Danish Navy and the Royal Norwegian Navy have ships for work 
in light ice. The Royal Canadian Navy (Coast Guard) includes 11 
icebreakers. Russia’s Northern Fleet, which is based on the coast 
of the Barents and White Seas, includes 40 icebreakers, and 5 
of them are nuclear. The US Pacific Fleet is not equipped with 
nuclear icebreakers (it includes a total of 6 vessels equipped for 
work in heavy ice), but includes nuclear submarines, which carry 



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 2016 1967

out both intelligence and research. Russia is an undisputed leader 
among the Arctic countries by the composition and quantity of the 
icebreaker fleet units (Figure 2).

One should not forget about the active research work in the Arctic. 
For example, the International Arctic Science Committee (IASC, 
2016) was created in 1990, under which five working groups 
function on a regular basis (on atmospheric research, on marine 
research, on social and human development, on the ice cover 
research, as well as of the water area, the landscapes and biota). 
During the International Polar Year alone (2007-2008), about 286 
different national research programs for the study of the biota and 
ecosystems of the Arctic and Polar territories were realized. Of 
them, 85% of all completed projects (i.e. 243 projects) fell for the 
Arctic countries (USA, Canada, Norway, Finland, Russia, Sweden, 
Denmark). The exception is Iceland, which has not realized its 
own projects, but has participated in projects of the European 
countries (Figure 3).

As such, active research and socio-economic exchange between 
the Arctic territories and the mainland requires new knowledge-
intensive approaches to the construction of the functional logistics 
of supply, given that nearly all equipment, goods and household 
items, food, medicines and surgical dressing generally require the 
arrangement of special supply.

In Russia, northern territories, including the Arctic, have been 
supplied and are still supplied with the required goods, household 
items and equipment primarily under the “northern delivery” 
program. In European countries, as well as in the countries of 
North America, Polar and Subpolar territories are supplied on 
a constant basis, but the most important and valuable goods are 
usually delivered in the spring-summer period, when navigation 
(air and sea) is not complicated by the harsh climate. In other 
words, Russia uses target-oriented approach to supply the Arctic 
territories, while the countries of North America and Europe 
(European North) use a mixed approach (process of regular supply 
of Arctic territories includes the programs of delivery of special 
goods during the spring-summer navigation) (Dudin et al 2016; 
Lukin 2010; Smith 2010).

At the same time, it should be taken into account that the 
environmental damage to the Arctic ecosystem constantly 
increases, in part because goods imported into the Arctic are not 
always fully utilized (which determines the appearance of the 
waste that is not disposed of in a natural way and is preserved 
in permafrost). Besides, the Arctic has already accumulated 
a sufficient amount of returnable packaging units, as well as 
disposable and reusable packaging that clutters and pollutes 
the natural space and water, poisons biota, etc. Therefore, it is 
objectively obvious that there is a need to change the existing 
approaches and organization of supply to the construction of the 
relevant logistics processes.

4. DISCUSSION

The logistics scientific paradigm has changed in recent decades. 
These changes primarily relate to the greening of building socio-

Figure 1: Structure of the global marine cargo turnover, 2014-2015. 
(Lappo and Danilova, 2015; Tarvainen et al., 2015)

Figure 2: Number of icebreaking vessels in possession of the major 
Arctic states, 2014-2015 (Lappo and Danilova, 2015; Tarvainen et al., 

2015; Tsetlin and Krasnova, 2014)

Figure 3: Specific contribution of the Arctic countries to the 
realization of research projects during the International Polar Year 

(2007-2008) (IASC, 2016; The Arctic Council, 2016)

economic functional processes and other processes that directly 
relate to them. The environmental aspect of the global social and 
economic development was first raised in the 90s of the last century, 
which resulted in the concept of “sustainable development” that 
dominated for two decades. Currently, the concept of “sustainable 
development” has evolved into the concept of “green economy,” 
which includes the aspect of social equality in addition to the 
environmental aspect. “Green” or environmentally responsible 
logistics is a derivative functionality from the “green economy.”



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 20161968

Increase in environmental responsibility in the transport and 
logistics field was called “green logistics” (Chapple, 2008; 
McKinnon et al., 2015; Ehrhart, 2012). “Green” logistics 
(including in terms of the development of the transport and 
logistics potential of the Arctic) is an arrangement of movement 
of cargoes and passengers and other transport and logistics 
services, the provision of which to the economic agents and 
agents of socio-residential sector is carried out with the use of 
environmentally friendly technologies that do not increase and 
at the same time reduce the level of anthropogenic and industrial 
impact on the global ecosystem. The key idea of the “green” 
logistics, which does not deny the traditional scientific postulates, 
is to “…deliver more using less…” (Bowersox et al., 1991; Coyle 
et al., 1992; Apostol, 2012; McKinnon et al., 2015). In other 
words, green logistics includes two conceptual methodological 
provisions:
• Firstly, it requires a gradual and systematic abandonment of 

environmentally harmful and aggressive transport that uses 
gasoline and similar fuels with a high level of emission of 
carbon dioxide;

• Secondly, it requires intensification of the use of transport 
capacity, not only to reduce the pressure on the ecosystem, 
but also to reduce the burden on the transport and logistics 
infrastructure, the restoration of which is always characterized 
by high capacity of capital.

For the Arctic, with its unique and at the same time very fragile 
environment, the environmentally responsible logistics (including 
in the context of the supply of the Arctic territories) is an urgent 
scientific and applied concept. In this context, the logistics 
solutions can have several basic options:
a. Long-term solutions focused on the complete modernization 

of transport used in the Arctic (switching to environmentally 
friendly fuel, avoiding the use of machines non-resistant 
to the Arctic climate). The solutions to improve transport 
and logistics infrastructure can also be implemented here 
(autonomous automated terminals for storing reserves, used 
cooperatively, etc.);

b. Medium-term solutions focused on reducing the industrial 
impact, including that associated with the supply of the Arctic 
territories with essential goods (commodities, food, equipment, 
etc.). In this case, various forms of collective procurement can 
be used, as well as phasing out environmentally aggressive 
environmental aviation and navigation, transition to the 
fragmented delivery of small cargoes using environmentally 
friendly biopilot aircrafts;

c. Short-term solutions focused on the current ecological 
optimization of logistics procurement process through the 
construction of their most rational models and the use of 
reverse logistics technologies.

The reverse logistics can be considered as a “green” logistics 
technology focused on the ensuring, through the collection 
(accumulation) of the obsolete, corrupted or damaged product, 
its packaging and transport packing, including for subsequent 
secondary or tertiary processing (recycling) or for the 
environmentally safe disposal that does not create an additional 

industrial or anthropogenic load on the environment (Dyckhoff 
et al., 2013). In turn, modeling is based on the use of economic 
and mathematical methods and, in particular, correlation-
regression analysis. Since we talked about the multiple 
regression equation in the method section, then, respectively, 
it is advisable in the first place to identify the main factors that 
will determine the optimal amounts of goods and supplies that 
are necessary to ensure the normal functioning of commercial 
firms, research expeditions, tourist groups or environmental 
volunteers.

The second important aspect is that the process of supply should be 
described by a direct and return flow. Hence, the process of supply 
of the Arctic facilities with the necessary resources (commodities, 
raw materials, medicines and other goods) should be as follows 
(Figure 4). In other words, each supply of the resources to the 
Arctic facilities should be:
• Firstly, optimized and economically feasible taking into 

account the required reserve;
• Secondly, rationalized taking into account the reduction of 

the environmental, transaction and other costs;
• Thirdly, always be described by the presence of a reverse 

logistics flow (returnable packaging, flawed commodities, 
items that are out of operation).

At the same time, management of the process of supply and 
formation of reserves should be described by simultaneous 
centralization (supply by a specialized logistics aggregator) 
and decentralization (requirements for the optimal and rational, 
economically sound volume of the order are set by each 
Arctic facility independently). In addition, each Arctic facility 
independently forms a return flow (secondary resources recycling 
and disposal).

Wilson formula and its modification for the calculation of the 
optimum size of the order are well known and presented in the 
method section of this article. Therefore, we are not going to dwell 
on the methodological approaches to the calculation of the optimal 
and economically feasible size of the order; we will just take into 
account that the size of the order for the supply will depend on:
1. The current (formed) size (volume) of the reserve, frequency 

and certainty of supply;
2. The cost of the physical movement of the cargo in space;
3. The potential environmental damage associated with the 

delivery of the cargo, as well as the accumulated environmental 
damage (non-recycled packaging, packing, flawed goods);

4. The willingness of suppliers to use the returnable logistics 
flow to increase environmental supply and optimization of 
the logistics process.

In view of the above, we can logically assume that the economic 
and mathematical model describing the state of reserves, as well 
as the logistics process of supply of the Arctic facilities with 
necessary resources (commodities, raw materials, equipment, 
medicines, etc.), should include the following set of variables:
1. The planned demand for some type of resource for a certain 

time period (e.g., month, quarter, 6 months, etc.), i.e. the 



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 2016 1969

number of stock units to be purchased (supplied) to meet the 
needs of functioning of the Arctic facility. This, in accordance 
with Wilson formula, also takes into account the resource 
consumption over a certain period, which is reflected in the 
calculation of the planned and economically feasible size of 
the order;

2. The estimated and corrected environmental damage in terms 
of value per unit of reserve/order. Here the difference can be 
used between the economic evaluation of potential direct or 
indirect benefits from the operation of the Arctic facility and 
the economic evaluation of environmental damage associated 
with the operation of the facility per unit of stock/order. In 
this case, the estimated environmental damage needs to be 

corrected (per unit of reserve/order), bearing in mind that the 
load on the ecosystem of the Arctic will be reduced. This will 
be achieved through the return logistics flow (coordinated 
in time with direct logistics flow), during which secondary 
resources for recycling and/or disposal will be sent to the 
mainland;

3. The market price of the delivery and storage of the reserve unit, 
the price includes not only the actual value of the resource, 
but also the value of its physical movement in space from 
the supplier to the logistics aggregator and from the logistics 
aggregator to the Arctic facility;

4. The stability and certainty of supply of resources by the 
logistics aggregator to the Arctic facility. This indicator is 

Figure 4: Model of the process of supply of the Arctic facilities with necessary resources



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 20161970

of economic and mathematical model of multiple regression. In 
particular, let’s assume that the nth Arctic facility needs the ith 
resource, while the demand for this resource and the key variables 
of the model have been described by the following basic values 
over the past 27 months (Table 1).

At the same time, we should take into account that the reverse 
logistics flow for minimization of the environmental damage was 
used at the nth Arctic facility from the 10th month, which reduced 
the level of environmental damage from the operation of this Arctic 
facility, as well as reduced the cost of the delivery of the unit of 
the reserve of resource. But considering that Arctic conditions 
cannot guarantee high stability and certainty of supply of resources 
from the mainland to the nth Arctic facility, the current volume of 
reserves and the reserves immobilization coefficient also increases. 
The multiple regression model for this example will be described 
by the following values of the variables (Table 2).

best calculated as the ratio of the quantity of deliveries carried 
out in violation of the terms of contracts to the quantity of 
deliveries made on time and in compliance with the key terms 
of the contracts;

5. The current level of the reserves of resources (including 
safety stock in the case of a failure in supply) in terms of 
quantity, which is in storage at the Arctic facility at a given 
time;

6. The coefficient of immobilization of reserves of resources, 
which are in storage at the Arctic facility at a given time. This 
figure represents the ratio of the current amount of the reserve 
to the target demand for the resource.

All the necessary formulas for the calculation of the indicators 
listed above can be found in the methodological section of 
this article, while we suggest to plan the demand for supply of 
resources and make decisions on the current reserves on the basis 

Table 1: Source data for inventory management and planning the procurement of the ith resource at the nth Arctic facility
Period Target demand for the 

resource (amount of purchases), 
units

Estimated and corrected 
environmental damage, 

$ per unit

Price of 
delivery per 

unit, $ 

Stability/certainty 
of supply

Current 
volume of 
reserves, 

units

Coefficient of 
immobilization

1 1.019 16.2 305 0.9 31 0.03
2 1.031 16.4 330 0.9 31 0.03
3 1.076 16.5 330 0.9 32 0.03
4 1.124 17 330 0.9 34 0.03
5 1.144 17 331 0.9 34 0.03
6 1.163 18.5 331 0.75 35 0.03
7 1.004 18.6 331 0.7 70 0.07
8 1.017 19.2 331 0.75 71 0.07
9 1.025 19.4 331 0.6 72 0.07
10 1.063 19.5 331 0.75 117 0.11
11 1.187 19 298 0.8 131 0.11
12 1.209 18.3 293 0.8 133 0.11
13 1.215 17.4 290 0.8 134 0.11
14 1.296 16.4 287 0.9 143 0.11
15 1.333 15.3 280 0.9 147 0.11
16 1.387 14.7 276 0.75 153 0.11
17 1.400 14.4 273 0.7 196 0.14
18 1.515 14 273 0.75 212 0.14
19 1.599 13 273 0.6 224 0.14
20 1.602 12.7 273 0.75 224 0.14
21 1.659 12.7 273 0.8 232 0.14
22 1.721 12.5 273 0.55 275 0.16
23 1.800 12.6 273 0.55 288 0.16
24 2.066 12.5 273 0.9 331 0.16
25 2.231 12.1 273 0.9 424 0.19
26 2.503 12.1 273 0.8 476 0.19
27 2.765 12 273 0.7 525 0.19

Table 2: Coefficients of the multiple regression model for inventory management and planning of procurement of the ith 
resource at the nth Arctic facility
Variable of the model Coefficients
Y-crossing (target demand for the resource, i.e., target size of the order) 2150.624367
Variable x1 Estimated and corrected environmental damage per unit of the reserve of the resource −3.38558792
Variable x2 Price of delivery per unit of the reserve of the resource −1.60613002
Variable x3 Stability and certainty of supply of resources 35.65185294
Variable x4 Current (formed) volume of reserves of resources 4.577582564
Variable x5 Coefficient of immobilization of reserves of resources −5193.523483
Multiple regression model view
y ̂x=2150.62-3.39x1 − 1.61x2 + 35.66x3 + 4.58x4 − 5193.52x5



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 2016 1971

The multiple regression model shows that variables x1, x2, 
x5 will adversely affect the target volume of the order and, 
respectively, reduce the demand of the nth Arctic facility for 
the ith resource. In this case, the regression statistics shows 
that there is a very close connection between the effective 
and factorial signs in the economic and mathematical model 
(Table 3).

Next, using the pair correlation, let’s construct paired linear 
regression equations for each factor, and then for an effective 
sign for the upcoming 10 periods (months). Hence, the predictive 
model of inventory management and planning of procurement of 
the ith resource at the nth Arctic facility will have the following 
form (Table 4).

T h u s ,  t h e  o b t a i n e d  d a t a  a l l o w  t o  c o n c l u d e  t h a t 
inventory management and planning of procurement of the 
ith resource at the nth Arctic facility require to consider the 
following:
• Firstly, if the specifics of operation of the Arctic facility does 

not change, then all other things being equal the demand for 
the ith resource will increase over the next 10 months by an 
average of 20-21%;

• Secondly, the corrected and estimated environmental 
damage will significantly reduce at least by 19% over the 
period under study, but the procurement costs will reduce 
by only 10%;

• Thirdly, the stability and certainty of supply of reserves of 
resources is likely to be insufficiently high, which in turn will 
cause an increase in the current level of reserves of resources 
and, accordingly, the level of immobilization of reserves at 
this Arctic facility.

5. CONCLUSIONS

Thus, summarizing this article, we consider it necessary to note 
that the transition to environmentally responsible logistics supply 
in the Arctic is an objective necessity. In this case, the solutions 
on the greening of the logistics of supply of the Arctic facilities 
(research, commercial or tourist) can be implemented in the short 
term through the use of reverse logistics technologies. The idea 
is to create a forward and reverse logistics flows, consistent in 
time, which will provide both the supply to the Arctic facilities 
of necessary resources (commodities, equipment, medicines, 
foods, etc.) and the simultaneous transfer to the mainland of the 
accumulated volume of secondary resources (accumulated stocks 
of returnable packaging, packing, flawed goods, unused supplies 
and equipment), which can create a significant threat to the 
ecosystem of the Arctic. In this case, the planning of the resource 
supply and inventory management should be implemented with 
the use of economic and mathematical modeling. This paper 
proposes a multiple regression model, which includes five 
most important variables that determine the sizes of the target 
procurements of resources based not only on the current formed 
volume of reserves and the level of immobilization of resources 
in reserves, but also on environmental damage.

The suggested approach to the organization of supply, 
construction of logistics processes, as well as to the management 
of reserves at the Arctic facilities (research, commercial 
or tourist) can be regarded as innovative and knowledge-
intensive. This approach is based on the concept of “green” 
logistics (including the technology of reverse logistics) with the 
integration of economic and mathematical methods in inventory 
management and procurement planning, taking into account 
such an important parameter as the environmental damage 
from the supply of the Arctic facilities with resources (research, 
commercial or tourist).

The authors did not consider separate methodological issues on 
improving the institutional environment of the arctic logistics 
and harmonization of national and international organizational, 
economic and legal approaches to environmentally responsible 
development of Arctic territories in this article. These and other 
aspects of sustainable and environmentally-focused development 

Table 3: Statistics of the multiple regression model for 
inventory management and planning of procurement of 
the ith resource at the nth Arctic facility
Regression statistics
Multiple R 0.996849189
R2 0.993708306
Normalized R2 0.992210284
Standard error 41.84086047
Observations 27

Table 4: Predictive model for inventory management and planning of procurement of the ith resource at the nth Arctic facility
Period Target demand for the 

resource (amount of 
purchases), units

Estimated and corrected 
environmental damage, $ per 

unit

Price of 
delivery per 

unit, $ 

Stability/certainty of 
supply

Current 
volume of 
reserves, 

units

Coefficient of 
immobilization

28 2182.003 11.8 256.6 0.708 404.924 0.200
29 2234.278 11.5 253.8 0.703 421.220 0.206
30 2286.554 11.2 250.9 0.698 437.516 0.213
31 2338.829 10.9 248.0 0.693 453.812 0.219
32 2391.105 10.7 245.2 0.688 470.108 0.226
33 2443.380 10.4 242.3 0.683 486.404 0.232
34 2495.655 10.1 239.5 0.678 502.700 0.239
35 2547.931 9.9 236.6 0.673 518.996 0.245
36 2600.206 9.6 233.8 0.668 535.292 0.252
37 2652.481 9.3 230.9 0.663 551.588 0.259



Dudin, et al.: Innovative Approach to the Development of the Logistics System of Supply of the Arctic Region Space

International Journal of Economics and Financial Issues | Vol 6 • Issue 4 • 20161972

of the Arctic as a world heritage will be discussed in more detail 
in other articles.

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