Special quantitative model of the human thermoregulatory system (MTS) functioning with cardiovascular and lung systems is created. These systems form a human physiological supersystem (HPSS). MTS describes thermoregulatory responses to alterations of both external environmental physical characteristics and internal biological characteristics. Algorithms provide designing of scenarios including simulation of either short-time or long-time (hours or days) observations. Input data include different combinations of environmental variables (air or water temperature, air humidity, wind or water flow speed, light intensity, infrared radiation) for a naked or wear human, as well as for given dynamics of biological characteristics (rate of heat production including its components associated with metabolism and ATP molecules leasing during mental and physical activities). Human body is presented by a core, blood, and a skin compartments. Skin and lung evaporation are under hypothalamic control based on afferent impulse patterns from internal, and skin heat and cold receptors. Dynamic output data include blood, hypothalamic, and skin temperatures, hemodynamic parameters like heart rate, cardiac output, regional blood flows, vascular resistances, blood pressures, and regional blood volumes. Serotonin and melatonin concentrations modulating biological heat production rate are associated with a day/night light intensity. Currently, the PCbased simulator is autonomous software to be used both for educational purposes and for providing of special computer research. In a near future, this simulator has to be widened by models of kidneys, and a mechanism of liverpancreas interaction.

Problems in programming 2023; 3: 81-90

Grygoryan RD. The optimal circulation: cells contribution to arterial pressure. N.Y.: Nova Science,2017: 287p. ISBN 978-1-53612-295-4.

Grygoryan R.D., Sagach V.F. The concept of physiological super systems: New stage of integrative physiology. Int. J. Physiol. and Pathophysiology, 2018: 9,2,169-180. CrossRef

Grygoryan RD. The Optimal Coexistence of Cells: How Could Human Cells Create The Integrative Physiology. J. of Human Physiol. 2019,1 (01):8-28. DOI 10.30564/jhp.v1i1.1386.

Grygoryan R.D. Problem-oriented computer simulators for solving of theoretical and applied tasks of human physiology. Problems of programming. 2017, №3, Р. 102-111. CrossRef

Grygoryan R.D., Yurchak O.I., Degoda A.G., Lyudovyk T.V. Specialized software for simulating the multiple control and modulations of human hemodynamics. Prombles in programming. 2021; 2: 42-53. CrossRef

Grygoryan R.D., Degoda A.G., Lyudovyk.V., Yurchak O.I. Simulations of human hemodynamic responses to blood temperature and volume changes. Prombles in programming. 2023; 1: 19-29. CrossRef

Grygoryan R.D. Modeling of mechanisms providing the overall control of human circulation. Advances in Human Physiology Rsearch,2022,4,5 - 21, CrossRef

Fiala D., Lomas K.J., Stohrer M. Computer prediction of human thermoregulatory and temperature responses to a wide range of environmental conditions, Int. J. Biometeorol. 45 (2001) 143e159. CrossRef

Yermakova I.I., Montgomery L.D., Potter A.W. Mathematical model of human responses to open air and water immersion. Journal of Sport and Human Performance, 2022; 10(1), 30-45. CrossRef

Salloum M., Ghaddar N., Ghali K. A new transient bioheat model of the human body and its integration to clothing models. International Journal of Thermal Sciences. 2007, 46,4,371-384. CrossRef

Kobayashi Y., Tanabe S., Development of JOS-2 human thermoregulation model with detailed vascular system, Build. Environ. 66 (2013) 1e10,CrossRef

Katić K.Thermophysiological models and their applications: A review Building and Environment (Elsevier) 2016, 106, 286-300. CrossRef

Bhoopendra Choudhary, Udayraj, Local and overall convective heat transfer coefficients for human body with air ventilation clothing: Parametric study and correlations, Building and Environment, 229, 2023,109953 CrossRef