Training Process Modeling of Hammer Throwers Taking into
Account Peculiarities of Stress Adaptation
Alexander Bolotin and Vladislav Bakayev
Institute of Physical Education, Sports and Tourism, Peter the Great St. Petersburg Polytechnic University,
St. Petersburg, Russian Federation
Keywords: Stress Adaptation, Qualification Norm, Computer Simulations, Training Process Forecasting, Hammer
Throwers.
Abstract: The article considers the solution of the forecast problem to improve the efficiency of the training process of
hammer throwers taking into account the peculiarities of their adaptation to the load. This problem was
solved by computer modelling. To solve this problem, restrictions were set on the control and managed
parameters. The number of parameters that were entered into the model was determined by the methods of
expert assessments. These parameters were adjusted in the process of modelling the dynamics of the
training system in time on a personal computer. Basing on the results of forecasting it was revealed that
taking account the peculiarities of stress adaptation in hammer throwers training led to doubled number of
sportsmen’s who fulfilled the qualification norm successfully.
1 INTRODUCTION
At present the problem of increased efficiency of the
training process in hammer throwers is very urgent
(Bolotin et al., 2017). For this purpose, computer
modeling is widely used. The development of such a
model is intended for solving the problem of training
process prognostication in hammer throwers taking
into account their stress adaptation (Bolotin et al.,
2014; Hopkinset al., 2009). Practice has shown that
the organizational and pedagogic management of the
training process in hammer throwers becomes a
classical task in the management theory (Bartonietz
et al., 1997; Bartonietz et al., 1988; Murofushi et al.,
2007; Malcata and Hopkins, 2014). If limitations for
control and controlled parameters are set such
problem has a solution. Maximization of the number
of hammer throwers who fulfilled the qualification
norm successfully for participation in international
competitions was the target function in our problem
settings (Winter, 2005).
2 ORGANIZATION AND
METHODS
We consider the equation of computer model for
prognostication of training process efficiency in the
form of a year’s full training cycle.
The following flows act in the system:
information flow - I, number of training sportsmen’s
N
n
, number of trainers N
tr.
Let us designate the initial number of training
sportsmen as N
n0
and their number after completion
of the year’s full training cycle as N
nT
, where T is
the year’s full training cycle. N
nТ
is summed up
from: N
nТs,
the number of sportsmen who fulfilled
the qualification norm; N
nТn,
the number of
sportsmen which did not fulfill the qualification
norm and N
nl,
the number of sportsmen who left the
training camp and who were not selected for the
competitions because of different reasons.
The general objective of the organizational and
pedagogic ma nagement of the training process is to
maximize N
nТs
, i.e. the number of sportsmen who
fulfilled the qualification norm. The method of
computer modeling belongs to heuristic methods and
a significant number of parameters included in the
model are determined by the methods of expert
assessment. These parameters may be corrected
Bolotin, A. and Bakayev, V.
Training Process Modeling of Hammer Throwers Taking into Account Peculiarities of Stress Adaptation.
DOI: 10.5220/0006847300790083
In Proceedings of the 6th International Congress on Sport Sciences Research and Technology Support (icSPORTS 2018), pages 79-83
ISBN: 978-989-758-325-4
Copyright © 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
79
during the modeling process of training system
(model on PC) dynamics over time using PC.
Let us designate the number of intervals during
which the model will turn to the final condition as
M. It is convenient to use the number of training
cycles of 2 months each, i.e. 6 cycles, as M. Thus,
we obtain the possibility to compare the actual
training results with results revealed in the model
and to make quick correction (to implement
feedback). Then the model increment size is
Δt=T/N. At the initial time point: N
nТs0
= N
n0
(all
sportsmen wishing to fulfill the qualification norm)
and N
nТn0
= N
l0
. So, the number of sportsmen was
determined successfully. The values introduced for
components of this flow at any time point i are the
level of this flow.
The finite-difference equation of the simulation
model for the flow of the number of training
sportsmen has the form:
N
ni+1
= N
ni
+ N
ni+
- N
ni-
,
N
ni+1
≤ N
n0
,
here N
ni+
is the rate (increase rate of sportsmen
number). If we consider that reinstatement is
impossible after dismissal of sportsmen from the
training process, then N
ni+
=0.
If reinstatement is possible after appearance of
vacancies then Nni+=1 at the time of appearance of
a vacancy in the team.
N
ni-
– decrease rate of sportsmen number.
This rate is summed up from a complex of
factors favoring the effective continuation of the
training process:
- psychologic compatibility of sportsman with a
trainer,
- selection of the training program and training
method in accordance with individual resources of
sportsmen,
- successful sportsmen’ adaptation to the training
process,
- efficient fulfillment of the training program by
a sportsman,
- sportsmen’s motivation to achieving high sports
results etc.
The trainer’s role should be considered in the
form of coefficient which is composed from the
requirements to the trainer.
The linear relationship is usually supposed at the
initial stage of modeling basing on the results of the
previous training cycle. The pedagogic methods
such as subject-subject relations between a
sportsman and a trainer, current and midterm test
should be used to minimize N
ni
, i.e. to implement the
organizational and pedagogic management.
The information flow is described by the
following equation:
I
кn+1
= I
ni
+ I
ni+
- I
ni-
,
where I
ni+1
is information about sportsmen at
time point i+1, I
ni+
is rate of positive information
about sportsmen (fulfillment of control norms,
participation in interim competitions, increase of
physical fitness parameter values etc.); I
ni-
is rate of
negative information (disciplinary misdeeds,
violations of sports regimen, non-fulfillment of the
training program etc.).
If I
ni-
has non-zero value (negative feedback
functions) it is necessary to correct the rate N
ni+
immediately (listen to the trainer’s and sportsman’s
report, provide assistance in training of sportsmen
etc.).
The model validity is checked by solving the
prognostication problem for several previous periods
(training cycles) because when modeling the process
for previous periods the modeling result is known in
advance, therefore, it is possible to select some
model coefficients as per the program.
3 RESULTS AND DISCUSSION
Constructing the simulation model is bаsed on the
reports on results of the training process for a
sufficiently long time period and our additional
studies. Table 1 presents a fragment of summarized
reporting data on training of hammer throwers in
2013-2016.
Table 1: Summarized reported results of training for 2013-2016 used for selecting initial and final conditions.
Analyzed years
Number of training
sportsmen
Number of sportsmen who
fulfilled the qualification norm
2013
16
8
2014
12
5
2015
20
5
2016
15
2
Standardized mean
1.00
0.31
icSPORTS 2018 - 6th International Congress on Sport Sciences Research and Technology Support
80
Basing on Table 1 we form the initial and final
conditions for solving the problem of determining
simulation model coefficients (solving the
prognostication problem from known past to known
present events).
When solving prognostication problems
standardized units are commonly used because the
trend in change of the test parameters is of the main
interest.
When selecting the computer modeling program
we used the AnyLogic program
(www.anylogic.com). It is recommended for
construction of the computer model as the most
general one and at the same time it has an
understandable interface.
During the preliminary study we revealed factors
determining the efficiency of the training process of
hammer throwers. For this purpose, we conducted
questioning of coaches and sportsmen. Results of
this study are presented in Table 2. Of course, the
transition from non-parametric criteria to parametric
ones (ranking: r
1
, …, r
8
) requires parameter
standardization. Therefore, it is necessary to
standardize them by rank size, thereby, to make the
variable models “equal in rights”.
Therefore, in accordance with Table 2 we obtain
eight independent variables (x
1
, …, x
8
) where x
1
=r
1
/0,198 etc. x
8
=r
8
/0.052.
Practice has shown that the main causes for
leaving the training process by sportsmen include
impossibility of sportsmen ‘adaptation to physical
stress or other force-major circumstances (Bakaev et
al., 2015; Bakaev et al., 2016; Bolotin and Bakayev,
2016; Bolotin and Bakayev, 2017; Bakayev and
Bolotin, 2017; Bolotin et al., 2015; Osipov et al.,
2016; Rojas-Ruiz and Gutiérrez-Dávila, 2009; Kim
et al., 2011). In order to remove these causes it is
necessary to create appropriate psychologic and
pedagogic conditions required for successful
adaptation of hammer throwers to the training
process. When solving this study task we questioned
72 respondents. Results of this study are presented in
Table 3.
The similar method is used to standardize also
the conditions favoring effective sportsmen’ stress
adaptation after transition to parametric values (y
1
,
…, y
8
) where y
1
=r
1
/0,213 etc. y
8
=r
8
/0,037. The
decrease and increase rate of the number of
sportsmen N
ni-
and N
ni+
are linear functions of
independent variables (x
1
, …, x
8
) and (y
1
, …, y
8
),
Table 2: Factors determining the training process efficiency of hammer throwers (n=72).
Factors
Rank test (%)
Optimum height and weight parameters of hammer throwers
19.2
Use of individual approach to training of hammer throwers
17.3
Orientation of the training of hammer throwers to fulfillment of the qualification norm
15.7
Availability of favorable environment during the training process
14.4
Availability of target nature of the training process of hammer throwers
10.6
Objective registration sportsmen ‘ training process quality
9.3
High level of trainers’ personal responsibility for high-quality training of sportsmen
7.7
Availability of permanent monitoring of physical fitness level of hammer throwers in the
year’s training cycle
5.8
Table 3: Rank structure of psychologic and pedagogic conditions required for effective adaptation of hammer throwers to
the training process (n=72).
Psychologic and pedagogic conditions
Rank (%)
Inclusion of separate programs for formation of skills of training by sportsmen themselves in
their training process
21.3
Formation of aspiration for permanent growth of sport results in sportsmen
19.7
Use of innovative training methods during training of hammer throwers
15.2
Formation of hammer throwers’ striving for fulfillment of the qualification norm
12.8
Development of a complex of measures for controlling the level of physical and psychologic
parameters in sportsmen required for achievement of high sports results
12.2
Development of objective assessment criteria of the level of physical and psychological
parameters in sportsmen
9.8
Implementation of measures for searching ways to increase sportsmen’ interest and motivation to
the training process
5.3
Creating the environment for manifestation of high sports mastery of hammer throwers
3.7
Training Process Modeling of Hammer Throwers Taking into Account Peculiarities of Stress Adaptation
81
Figure 1: Solving the prognostication problem from known to present events (innovative technologies and new training
conditions are included in 2016).
coefficients of which are calculated by the program
when solving the problem of computer modeling.
4 CONCLUSIONS
When using developed pedagogic methods for
increasing the training process efficiency:
implementation of individual-oriented approach to
selection of training means and methods, optimum
selection of physical stress in accordance with
sportsmen’ individual resources, continuous
methodical support of the training process with
trainer's participation, criterion conditions presented
in Tables 2 and 3 will be met (Bolotin and Bakayev,
2016; Bolotin and Bakayev, 2017).
Figure 1 presents forecasting results for 2018
with existing organization of the training process
and in case of introduction of the innovative training
methods suggested by us (meeting conditions of
Tables 2 and 3). Figure shows sportsmen number
dynamics with the standard training system and the
prognostication result in case of introduction of the
innovative training process technologies in 2018.
The use of simulation modeling has shown the
high efficiency for solving the problem of training
process prognostication in hammer throwers taking
into account peculiarities of their stress adaptation. It
is found that if limitations for controlling and
controlled parameters of the training process of
hammer throwers are set the problem for
prognostication of training efficiency has solution.
Maximization of the number of hammer throwers
who fulfilled the qualification norm successfully for
participation in the international competitions was
the target function for solving our problem.
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