Development of simulation data visulization framework for high-performance buildings (Softcopy is also available) (Record no. 56566)
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| 000 -LEADER | |
|---|---|
| fixed length control field | 03707nam a2200181 4500 |
| 082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER | |
| Classification number | MBEP TH-0026 |
| Item number | JAI |
| 100 ## - MAIN ENTRY--PERSONAL NAME | |
| Personal name | Jain, Yashima (PT501417) |
| 245 ## - TITLE STATEMENT | |
| Title | Development of simulation data visulization framework for high-performance buildings (Softcopy is also available) |
| 260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
| Date of publication, distribution, etc | 2019 |
| 300 ## - PHYSICAL DESCRIPTION | |
| Extent | xii,ii,62p. |
| 505 ## - FORMATTED CONTENTS NOTE | |
| Formatted contents note | Contents <br/>Declaration i <br/>Approval . iii <br/>Abstract v <br/>Acknowledgements . vii <br/>List of figures xi <br/>List of tables xi <br/>1. Introduction 1 <br/>1.1. Background . 1 <br/>1.2. Purpose statement . 2 <br/>1.3. Research question . 2 <br/>1.4. Research objectives. 2 <br/>1.5. Significance of the study . 2 <br/>2. Literature Review 3 <br/>2.1. Data visualization 3 <br/>2.1.1. Components of data visualization 4 <br/>2.1.2. Principles of a good visualization design 5 <br/>2.2. Communication of complex energy simulation data 5 <br/>2.2.1. Energy simulation related data and tools 5 <br/>2.2.2. Spatial and temporal representations 6 <br/>2.3. Integrating energy analysis with design stages 7 <br/>2.4. Summary 8 <br/>3. Research Methodology 9 <br/>3.1 Interviews 9 <br/>3.1.1. Preparation of an outline for the interview 9 <br/>3.1.2. Conducting the interviews 9 <br/>3.1.3. Qualitative analysis of literature review and interviews. 10 <br/>3.2. Classification of existing representations . 10 <br/>3.2.1. Collection and classification of representations . 10 <br/>3.2.2. Identification of the representation gap 12 <br/>3.3. Demonstration of representations . 12 <br/>3.3.1. Building selection criteria . 12 3.3.2. Identification of a building . 12 <br/>3.3.3. Building the energy model . 12 <br/>3.3.4. Development of representations to address the gap 12 <br/>4. Analysis and Results 13 <br/>4.1. Interviews . 13 <br/>4.2. Classification of design decisions and corresponding metrics 15 <br/>4.2.1. Pre-design Stage . 15 <br/>4.2.2. Concept Design Stage. 15 <br/>4.2.3. Preliminary Design Stage . 16 <br/>4.2.4. Analysis of the relationship between design decisions and output metrics 17 <br/>4.3. Classification of representations . 18 <br/>4.3.1. Pre-design Stage . 18 <br/>4.3.2. Concept Design Stage. 19 <br/>4.3.3. Preliminary Design Stage . 20 <br/>4.4. Proposed representations 21 <br/>4.4.1. Solar Insolation . 22 <br/>4.4.2. Heat Flux 22 <br/>4.4.3. Indoor Temperature 23 <br/>4.4.4. Envelope Load in the space 25 <br/>4.4.5. Cooling Load 26 <br/>4.4.6. Comfort hours . 27 <br/>4.5. Discussion . 28 <br/>5. Conclusions . 28 <br/>5.1. Recommendations for future study . 29 <br/>References 30 <br/>Appendix 33 <br/>1. Appendix A: Components of data visualization . 33 <br/>2. Appendix B: Principles of data visualization 35 <br/>3. Appendix C: List of architects and energy consultants interviewed . 37 <br/>4. Appendix D: Questions for the interview . 38 <br/>5. Appendix E: Representations in the pre-design stage . 39<br/>i. Climate Analysis 39 <br/>ii. Site Analysis 40 <br/>6. Appendix F: Representations in the concept design stage 40 <br/>i. Orientation . 41<br/>ii. Orientation + Aspect Ratio 41<br/>iii. Massing + Space Planning . 41 <br/>iv. Window Design . 42 <br/>v. Shading Device 44 <br/>vi. Envelope Assembly . 45 <br/>vii. Envelope assembly + Shading Device . 45 <br/>7. Appendix G: Representations in the preliminary design stage . 46 <br/>i. Window Design . 46 <br/>ii. Envelope Assembly + Window Design . 47 <br/>iii. Envelope Assembly . 48 <br/>iv. HVAC System . 48 <br/>v. Shading Device 50 <br/>8. Appendix H: Scripts prepared in Grasshopper using Ladybug and Honeybee . 51 <br/>i. Solar Shade Benefit 51 <br/>ii. Surface Energy Flux 52 <br/>iii. Operative Temperature 53 <br/>iv. Envelope Load with Daylight Autonomy and Annual Sun Exposure . 54 <br/>v. Energy shade benefit 55 <br/>vi. Comfortable hours . 56 <br/> |
| 700 ## - ADDED ENTRY--PERSONAL NAME | |
| Personal name | Sarraf, Saket (Guide) |
| 890 ## - Country | |
| Country | India |
| 891 ## - Topic | |
| Topic | FT-PG |
| 891 ## - Topic | |
| Topic | 2017 Batch |
| 891 ## - Topic | |
| Topic | Masters of Technology in Building Energy Performance |
| 942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
| Source of classification or shelving scheme | Dewey Decimal Classification |
| Withdrawn status | Lost status | Source of classification or shelving scheme | Damaged status | Not for loan | Collection code | Withdrawn status | Home library | Current library | Date acquired | Source of acquisition | Full call number | Barcode | Date last seen | Price effective from | Koha item type |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Dewey Decimal Classification | Faculty of Technology | CEPT Library | CEPT Library | 08/08/2019 | Faculty of Technology | MBEP TH-0026 JAI | 021363 | 08/08/2019 | 08/08/2019 | Thesis |