- Comprehensive estimation model for the health economic impact of the residential environment. In: Building and Environment, v. 267 (Januar 2025). (2025):
- Analyzing multiple elements of physical office environment for maximizing perceived work efficiency: Insights from surveys of 58 offices during summer. In: Building and Environment, v. 267 (Januar 2025). (2025):
- Item response theory in building environment engineering: A novel approach to identifying key residential environment items. In: Building and Environment, v. 262 (August 2024). (2024):
- PV/T solar panel for supplying residential demands of heating/cooling and hot water with a lower environmental thermal load. In: Energy and Buildings, v. 297 (Oktober 2023). (2023):
- Economic benefits of the effects of office environment on perceived work efficiency and presenteeism. In: Building and Environment, v. 243 (September 2023). (2023):
- Resiliency evaluation of a collective residence with an independent power outage system. In: Japan Architectural Review, v. 6, n. 1 (21 November 2022). (2022):
- Influence of residential performance on residents' health status (part II ): Nationwide survey of environmental performance of apartment buildings and residents' health status. In: Japan Architectural Review, v. 5, n. 4 (September 2022). (2022):
- Energy Consumption for Building Operation and Lighting. In: Journal of the Illuminating Engineering Institute of Japan, v. 87, n. 9 ( 2003). (2003):
- Quantitative Evaluation of the Contributions of Improved Housing Performances Toward Delivering Sustainable Development Goals by a Building Energy Simulation Tool. In: Sustainable Cities and Society, v. 79 (April 2022). (2022):
- Human response to the indoor environment under fluctuating temperature. In: Science and Technology for the Built Environment, v. 22, n. 6 (August 2016). (2016):
- Quantitative improvement in workplace performance through biophilic design: A pilot experiment case study. In: Energy and Buildings, v. 177 (Oktober 2018). (2018):
- A study on a porous residential building model in hot and humid regions part 2—reducing the cooling load by component-scale voids and the emission reduction effect of the building model. In: Building and Environment, v. 41, n. 1 (Januar 2006). (2006):
- A study on a porous residential building model in hot and humid regions: Part 1—the natural ventilation performance and the cooling load reduction effect of the building model. In: Building and Environment, v. 41, n. 1 (Januar 2006). (2006):
- Sustainability assessment of cities: SDGs and GHG emissions. In: Building Research & Information, v. 46, n. 5 ( 2018). (2018):
- Development of a comprehensive city assessment tool: CASBEE-City. In: Building Research & Information, v. 39, n. 3 ( 2011). (2011):
- Influence of residential performance on residents' health status: Nationwide survey of environmental performance of detached houses and residents' health status. In: Japan Architectural Review, v. 1, n. 2 (April 2018). (2018):
- A Forecast of Effective Global Warming Countermeasures for the Residential Sector in China for the year 2050. In: Journal of Asian Architecture and Building Engineering, v. 10, n. 1 (Mai 2011). (2011):
- Forecast of CO2Emissions from Construction and Operation of Buildings in Japan Up to 2050. In: Journal of Asian Architecture and Building Engineering, v. 1, n. 2 (November 2002). (2002):