Procedures and Methodologies for the Control and Improvement of Energy-Environmental Quality in Construction

© 2022 by the authors; CC BY-NC-ND license

CFD; enclosed building; wind environment; group layout; Hangzhou; China; indoor air quality; IAQ; enthalpy; humidity; thermal comfort; TC; dissatisfaction; panel tests; nearly zero energy building; NZEB; indoor environmental quality; IEQ; indoor air quality models; indoor air quality; indoor environmental quality; sustainable building; multi-criteria decision analysis; MCDM; MADM; user dissatisfaction; weights system; building comfort; PD; IAQ; IEQ; Residential users; Demand Response; Flexible loads; Dwellings clustering; building-integrated photovoltaics—BIPV; building heritage; energy efficiency; traditional materials; resilience; urban regeneration; adapting to change; climate performance; innovative technologies; smoke; natural exhaust; mechanical exhaust; smoke curtain; fire dynamics simulator; drying; heat and moisture transfer; hygro-thermal behavior; masonry walls; wet wall; in situ monitoring; energy benchmarking; university campus; energy performance certificate; CIBSE TM46; thermal energy efficiency; dynamic model; energy performance of buildings; low temperature district heating; indoor comfort; renovation; urban scale; energy requalification; building envelope; sustainable development and planning; standardized interventions of requalification; Geographic Information System; biometric data; biosignals; non-intrusive sensing; physiological metrics; environmental stimuli; stress detection; health; comfort; human thermal perception; comfort; multi-domain interactions; indoor air quality; noise sensation; cross-modal perception; n/a