Center for the Built Environment
Parent: Center for Environmental Design Research
eScholarship stats: Breakdown by Item for January through April, 2025
| Item | Title | Total requests | Download | View-only | %Dnld |
|---|---|---|---|---|---|
| 4qq2p9c6 | Developing an adaptive model of thermal comfort and preference | 1,273 | 490 | 783 | 38.5% |
| 3f4599hx | The skin's role in human thermoregulation and comfort | 1,099 | 835 | 264 | 76.0% |
| 935461rm | Quantifying the Comprehensive Greenhouse Gas Co-Benefits of Green Buildings | 585 | 50 | 535 | 8.5% |
| 2gq017pb | Workspace satisfaction: The privacy-communication trade-off in open-plan offices | 396 | 226 | 170 | 57.1% |
| 2048t8nn | Climate, comfort, & natural ventilation: a new adaptive comfort standard for ASHRAE standard 55 | 377 | 52 | 325 | 13.8% |
| 11m0n1wt | Human thermal sensation and comfort in transient and non-uniform thermal environments | 346 | 184 | 162 | 53.2% |
| 2m34683k | A better way to predict comfort: the new ASHRAE standard 55-2004 | 344 | 115 | 229 | 33.4% |
| 78v8055h | Indoor air movement acceptability and thermal comfort in hot-humid climates | 341 | 42 | 299 | 12.3% |
| 6s44510d | Ceiling Fan Design Guide | 305 | 59 | 246 | 19.3% |
| 5kz1z9cg | Indoor Humidity and Human Health--Part I: Literature Review of Health Effects of Humidity-Influenced Indoor Pollutants | 296 | 98 | 198 | 33.1% |
| 2tm289vb | Thermal sensation and comfort models for non-uniform and transient environments: Part III: whole-body sensation and comfort | 286 | 79 | 207 | 27.6% |
| 7897g2f8 | Air quality and thermal comfort in office buildings: Results of a large indoor environmental quality survey | 276 | 135 | 141 | 48.9% |
| 25x5j8w6 | Indoor Air Quality in 24 California Residences Designed as High Performance Green Homes | 252 | 189 | 63 | 75.0% |
| 2kd0135t | Analysis of the accuracy on PMV – PPD model using the ASHRAE Global Thermal Comfort Database II | 248 | 100 | 148 | 40.3% |
| 13s1q2xc | Extending air temperature setpoints: Simulated energy savings and design considerations for new and retrofit buildings | 245 | 68 | 177 | 27.8% |
| 9rf7p4bs | Occupant satisfaction with indoor environmental quality in green buildings | 240 | 37 | 203 | 15.4% |
| 89m1h2dg | Modeling the comfort effects of short-wave solar radiation indoors | 237 | 40 | 197 | 16.9% |
| 6nx97049 | Quantifying Office Building HVAC Marginal Operating Carbon Emissions and Load Shift Potential: A Case Study in California | 234 | 26 | 208 | 11.1% |
| 5ts1r442 | Thermal Adaptation in the Built Environment: a Literature Review | 231 | 71 | 160 | 30.7% |
| 3sq8z441 | A model of human physiology and comfort for assessing complex thermal environments | 224 | 94 | 130 | 42.0% |
| 3f73w323 | A Standard for Natural Ventilation | 215 | 43 | 172 | 20.0% |
| 1876400c | Assessing Overheating Risk and Energy Impacts in California's Residential Buildings | 213 | 51 | 162 | 23.9% |
| 2pn696vv | Thermal comfort in naturally ventilated buildings: revisions to ASHRAE Standard 55 | 207 | 64 | 143 | 30.9% |
| 3338m9qf | Dynamic predictive clothing insulation models based on outdoor air and indoor operative temperatures | 198 | 52 | 146 | 26.3% |
| 4db4q37h | Web application for thermal comfort visualization and calculation according to ASHRAE Standard 55 | 197 | 63 | 134 | 32.0% |
| 98n759dr | Evaluation of the cooling fan efficiency index. | 182 | 108 | 74 | 59.3% |
| 5zt7n382 | Air movement and thermal comfort: The new ASHRAE Standard 55 provides information on appropriate indoor air velocities for occupant comfort | 171 | 10 | 161 | 5.8% |
| 3fh0x2vm | Reducing Gas Consumption in Existing Large Commercial Buildings | 169 | 34 | 135 | 20.1% |
| 4x57v1pf | Operable windows, personal control and occupant comfort. | 168 | 36 | 132 | 21.4% |
| 1nv5k5qx | Human comfort and self-estimated performance in relation to indoor environmental parameters and building features | 165 | 122 | 43 | 73.9% |
| 3sw061xh | Thermal sensation and comfort models for non-uniform and transient environments: Part I: local sensation of individual body parts | 165 | 95 | 70 | 57.6% |
| 18d174zs | Personal comfort models—A new paradigm in thermal comfort for occupant-centric environmental control | 163 | 33 | 130 | 20.2% |
| 2qd7r5mp | Fans for cooling people guidebook | 161 | 21 | 140 | 13.0% |
| 4cd386s7 | Natural Ventilation for Energy Savings in California Commercial Buildings | 160 | 43 | 117 | 26.9% |
| 4kv4f2mk | A review of the corrective power of personal comfort systems in non-neutral ambient environments | 160 | 46 | 114 | 28.8% |
| 1wc7t219 | Quantitative relationships between occupant satisfaction and satisfaction aspects of indoor environmental quality and building design | 157 | 78 | 79 | 49.7% |
| 4vq936rc | High-performance facades design strategies and applications in North America and Northern Europe | 157 | 64 | 93 | 40.8% |
| 2hf4r1pg | Experimental evaluation of the effect of body mass on thermal comfort perception | 156 | 33 | 123 | 21.2% |
| 9kt889fn | The effect of thermochromic windows on visual performance and sustained attention | 156 | 7 | 149 | 4.5% |
| 3qs8f8qx | Quantifying energy losses in hot water reheat systems | 155 | 15 | 140 | 9.7% |
| 9pj5g228 | Spatial Thermal Autonomy (sTA): A New Metric for Enhancing Building Design Towards Comfort, Heat Resilience and Energy Autonomy | 153 | 27 | 126 | 17.6% |
| 9s12q89q | Comfort under personally controlled air movement in warm and humid environments | 151 | 31 | 120 | 20.5% |
| 89d4871t | The adaptive model of thermal comfort and energy conservation in the built environment | 150 | 67 | 83 | 44.7% |
| 3sx6n876 | Influence Of Three Dynamic Predictive Clothing Insulation Models On Building Energy Use, HVAC Sizing And Thermal Comfort | 143 | 2 | 141 | 1.4% |
| 54n6b7m3 | Personal comfort models: Predicting individuals' thermal preference using occupant heating and cooling behavior and machine learning | 143 | 45 | 98 | 31.5% |
| 6zw3x4rt | Re-optimizing Optimal Start and Morning Warmup | 142 | 10 | 132 | 7.0% |
| 7hx9338z | Review of fan-use rates in field studies and their effects on thermal comfort, energy conservation, and human productivity | 142 | 17 | 125 | 12.0% |
| 28x9d7xj | Energy savings from extended air temperature setpoints and reductions in room air mixing | 140 | 48 | 92 | 34.3% |
| 92z5q2qb | Progress in thermal comfort research over the last twenty years | 139 | 89 | 50 | 64.0% |
| 84r525hj | Impacts of life satisfaction, job satisfaction and the Big Five personality traits on satisfaction with the indoor environment | 137 | 82 | 55 | 59.9% |
Note: Due to the evolving nature of web traffic, the data presented here should be considered approximate and subject to revision. Learn more.