Geodesic
Computer modelling «Smart building»
Modelirovanie i analiz informacionnyh sistem, Tome 23 (2016) no. 4, pp. 427-439 Cet article a éte moissonné depuis la source Math-Net.Ru

Voir la notice de l'article

Currently "Smart building" or "Smart house" technology is developing actively in industrialized countries. The main idea of "Smart building" or "Smart house" is to have a system which is able to identify definite situations happening in house and respond accordingly. Automated house management system is made for automated control and management and also for organization of interaction between separated systems of engineering equipment. This system includes automation subsystems of one or another engineering equipment as separated components. In order to perform study of different functioning modes of engineering subsystems and the whole system, mathematical and computer modeling needs to be used. From mathematical point of veiw description of "Smart building" is a continuous-discrete or hybrid system consisting of interacting elements of different nature, whose behavior is described by continuous and discrete processes. In the article the authors present a computer model "Smart building" which allows to model the work of main engineering subsystems and management algorithms. The model is created in Simulink Matlab system with "physical modeling" library Simscape and Stateflow library. The peculiarity of this model is the use of specialized management and control algorithms which allow providing coordinated interaction of subsystems and optimizing power consumption.
Keywords: "Smart building", ABMS, hybrid system, computer model, Simulink, Stateflow. 
@article{MAIS_2016_23_4_a3,
     author = {O. Yu. Maryasin and A. S. Kolodkina and A. A. Ogarkov},
     title = {Computer modelling {{\guillemotleft}Smart} building{\guillemotright}},
     journal = {Modelirovanie i analiz informacionnyh sistem},
     pages = {427--439},
     year = {2016},
     volume = {23},
     number = {4},
     language = {ru},
     url = {http://geodesic.mathdoc.fr/item/MAIS_2016_23_4_a3/}
}
TY  - JOUR
AU  - O. Yu. Maryasin
AU  - A. S. Kolodkina
AU  - A. A. Ogarkov
TI  - Computer modelling «Smart building»
JO  - Modelirovanie i analiz informacionnyh sistem
PY  - 2016
SP  - 427
EP  - 439
VL  - 23
IS  - 4
UR  - http://geodesic.mathdoc.fr/item/MAIS_2016_23_4_a3/
LA  - ru
ID  - MAIS_2016_23_4_a3
ER  - 
%0 Journal Article
%A O. Yu. Maryasin
%A A. S. Kolodkina
%A A. A. Ogarkov
%T Computer modelling «Smart building»
%J Modelirovanie i analiz informacionnyh sistem
%D 2016
%P 427-439
%V 23
%N 4
%U http://geodesic.mathdoc.fr/item/MAIS_2016_23_4_a3/
%G ru
%F MAIS_2016_23_4_a3
O. Yu. Maryasin; A. S. Kolodkina; A. A. Ogarkov. Computer modelling «Smart building». Modelirovanie i analiz informacionnyh sistem, Tome 23 (2016) no. 4, pp. 427-439. http://geodesic.mathdoc.fr/item/MAIS_2016_23_4_a3/

[1] Repin V., “Intellektualnoe zdanie. Koncepcija krupnym planom”, StrojPROFil, 2001, no. 8 (in Russian)

[2] Tabunshhikov Ju. A., “Intellektualnye zdanija”, AVOK, 2001, no. 3, 6–14 (in Russian)

[3] Harke V., Umnyj dom. Obedinenie v set bytovoj tehniki i sistem kommunikacij v zhilishhnom stroitelstve, Tehnosfera, M, 2006, 288 pp. (in Russian)

[4] TRNSYS, http://sel.me.wisc.edu/trnsys/index.html

[5] ESP-r, http://www.esru.strath.ac.uk/Programs/ESP-r.htm

[6] IDA ICE, http://www.equa.se/en/ida-ice

[7] Parijskaia E. Ju., “The Comparative Analysis of Mathematical Models and Simulating Approaches for Continuous-discrete Systems”, Differential Equations and Control Processes, 1998, no. 1, 367–417 (in Russian) | MR

[8] Harel D., “Statecharts: a Visual Formalism for Complex Systems”, Sci. Comput. Prog., 8 (1987), 231–274 | DOI | MR | Zbl

[9] Stateflow, http://matlab.exponenta.ru/stateflow

[10] Buch G. et al., Jazyk UML. Rukovodstvo polzovatelja, DMK Press, M., 2006, 496 pp. (in Russian)

[11] Shalyto A. A., Switch-tehnologija. Algoritmizacija i programmirovanie zadach logicheskogo upravlenija, Nauka, SPb, 1998, 628 pp. (in Russian) | Zbl

[12] AnyLogic — instrument mnogopodhodnogo imitacionnogo modelirovanija (in Russian)

[13] Boev V. D. et al., Kompjuternoe modelirovanie: Posobie dlja kursovogo i diplomnogo proektirovanija, VAS, SPb, 2011, 348 pp.

[14] Modelica and the Modelica Association, https://modelica.org

[15] Dymola, http://www.3ds.com/products-services/catia/products/dymola

[16] MapleSim, http://www.maplesoft.com/products/maplesim/index.aspx

[17] Wolfram SystemModeler, http://www.wolfram.com/system-modeler/features/

[18] Welcome to OpenModelica, http://www.openmodelica.org/index.php

[19] JModelica, http://www.jmodelica.org

[20] Modelica_StateGraph2, https://github.com/modelica/Modelica_StateGraph2

[21] MATLAB and Simulink, http://matlab.ru/products

[22] Stateflow User's Guide, The MathWorks, Inc., 2012

[23] Simscape User's Guide, The MathWorks, Inc., 2012

[24] Simulink Coder, http://matlab.ru/products/simulink-coder

[25] Embedded Coder, http://matlab.ru/products/embedded-coder