Aliyarova, L., Uzakov, G., & Toshmamatov, B. (2021). The efficiency of using a combined solar plant for the heat and humidity treatment of air. IOP Conference Series: Earth and Environmental Science, 723(5), 052002.

Allayev, Q. (2021). Modern energy and its development prospects. Tashkent: Fan va texnika nashriyoti.

Beckman, W., Klein, S., & Duffy, J. (1982). Calculation of the solar heating system. Moscow: Energoizdat.

El-Sayed, K., Samir, A., Manar, S., Jasna, T., Jutta, H., & Azra, K. (2020). Development of a Bio Solar House Model for Egyptian Conditions. Energies(13), 817. doi:10.3390/en13040817

Esen, H., Esen, M., & Ozsolak, O. (2017). Modelling and experimental performance analysis of solar-assisted ground source heat pump system. Exp. Theor. Artif. Intell., 29(1), 1-17.

Esen, M., & Ayhan, T. (1996). Development of a model compatible with solar assisted cylindrical energy storage tank and variation of stored energy with time for different phase change materials. Energy Convers. Manage, 37(12), 1775–1785.

Esen, M., Durmus, A., & Durmus, A. (1998). Geometric design of solar-aided latent heat store depending on various parameters and phase change materials. Sol. Energy(62), 19-28.

Gudina, T., & Sanderine, N. (2017). Alternative energy supply system to a rural village in Ethiopia. Tucho and Nonhebel Energy, Sustainability and Society(7), 33. doi:10.1186/s13705-017-0136-x

Kharchenko, V., Sychov, A., & Uzakov, G. (2019). Innovative instruments for extraction of low-grade heat from surface watercourses for heating systems with heat pump. EAI/Springer Innovations in Communication and Computing(2), 59-68.

Klen, A., & Yefremenko, V. (2015). Economic efficiency of using hot water systems based on solar collectors. Technological Audit and Production Reserves, 5/5(25), 10-14.

Krivoshein, Y., Tsvetkov, N., & Khutornoy, A. (2017). Automated dual hot water system using solar energy and gas boiler. Heat Supply, Ventilation, Air Conditioning, Gas Supply and Lighting, 163-173.

Liu, Y., Li, T., Song, C., Wang, D., & Liu, J. (2018). Field study of different thermal requirements based on the indoor activities patterns of rural residents in winter in Northwest China. Science and Technology for the, Built Environment, 24(8), 867-877.

Mamatkulova, S., & Uzakov, G. (2022). Modeling and calculation of the thermal balance of a pyrolysis plant for the production of alternative fuels from biomass. IOP Conference Series: Earth and Environmental Science, 1070(1), 012040.

Norbert, H., Zeljko, J., & Nikolai, V. (2015). Energy Consumption Modelling via Heat Balance Method for Energy Performance of a Building. Procedia Engineering(117), 786-794. doi:10.1016/j.pro-eng.2015.08.23

Paraschiv, S., & Paraschiv, L. (2020). Technical and economic analysis of a solar air heating system integration in a residential building wall to increase energy efficiency by solar heat gain and thermal insulation. Energy Reports(S6), 459-474.

Rakhmatov, A. (2021). Energy efficient solar water heater. Proceedings of the International Scientific-online Conference on Innovation in the Modern Education System. Washington.

Sychov, A., Kharchenko, V., Vasant, P., & Uzakov, G. (2019). Application of Various Computer Tools for the Optimization of the Heat Pump Heating Systems with Extraction of Low-Grade Heat from Surface Watercourses. Advances in Intelligent Systems and Computing(866), 310–319.

Uzakov, G., Elmurodov, N., & Davlonov, X. (2022). Experimental study of the temperature regime of the solar pond in the climatic conditions of the south of Uzbekistan. IOP Conference Series: Earth and Environmental Science, 1070(1), p. 012026.

Uzakov, G., Shomuratova, S., & et al. (2021). Study of a solar air heater with a heat exchanger – accumulator. IOP Conf. Series: Earth and Environmental Science, 723 , 052013. doi:10.1088/1755- 1315/723/5/052013

Uzakov, G., Toshmamatov, B., Kodirov, I., & Shomuratova, S. (2020). On the efficiency of using solar energy for the thermal processing of municipal solid waste. Journal of Critical Reviews, 7(5).

Uzokov, G., & Davlonov, X. (2021). Energy-efficient greenhouses with pyrolysis devices. Karshi: Intellect.

Uzokov, G., Khamrayev, S., Khujakulov, S., & Kamolov, B. (2021). Assessment of the potential of solar energy resources in Kashkadarya region. FarPI Journal of Scientific Techniques, 25(2), 82-90.

Wang, D., Zhang, R., Liu, Y., Zhang, X., & Fan, J. (2021). Optimization of the flow resistance characteristics of the direct return flat plate solar collector field. Sol. Energy(215), 388-402.

Wang, Y., Kang, W., Liu, Y., Huang, R., & Liu, J. (2018). A heating strategy for rural residential buildings based on behavior patterns of residents in shaanxi province. Acta Energiae Solaris Sinica(39), 3026-3031.

Yu, K., Tan, Y., Zhang, T., Zhang, J., & Wang, X. (2020). The traditional Chinese kang and its improvement: A review. Energy Build(218), 110051. doi:10.1016/j.enbuild.2020.110051

Zhuang, Z., Li, Y., Chen, B., & Guo, J. (2009). Chinese kang as a domestic heating system in rural northern China – A review. Energy Build, 41(1), 111-119.