1. Space Allocation Optimization at NASA Langley Research Center Rex K. Kincaid, College of William & Mary Robert Gage, NASA Langley Research Center Raymond Gates, NASA Langley Research Center

2. Goals Integrated planning system –Schedule allocation of office and technical space based on current and projected organizational and project requirements –Maintain organizational synergy by co-locating within/between related organizations –Comply with space guidelines/requirements –Plan for changes in available space due to new construction, demolition, rehab, lease –Minimize moves –Save money

3. 3,500 employees 6,200 rooms 1,600 labs 300 buildings Center Characteristics

4. Visualization Problems –Buildings are sparsely distributed –Disjoint E/W areas –Floors overlay –Difficult to provide a single image that conveys all the details necessary

5. Visualization Spatial Subdivision Diagram –Permits display of large amounts of information in a compact form –Rectangular features are proxies for the actual spatial entities such as buildings –Features are scaled relatively to represent any quantity such as gross area, office area, or capacity

11. Data Sources Data Analysis / Preparation Low Level Algorithmic Components Mid Level Algorithmic Components High Level Algorithmic Components User Interface System Architecture

12. Data Sources Data Analysis / Preparation Low Level Algorithmic Components Mid Level Algorithmic Components High Level Algorithmic Components User Interface Existing Data Personnel Space Utilization GIS Center and Floor Plan Spatial Data New Data Technical Space Features Technical Function Requirements

13. Data Sources Data Analysis / Preparation Low Level Algorithmic Components Mid Level Algorithmic Components High Level Algorithmic Components User Interface Dynamic Inconsistent and continually changing Planned and unplanned changes Planning based on snapshots Need to be reconciled often

14. Monthly Move Data Histogram

15. Monthly Move Data Histograms

16. Details of Move Data Time Period A: 8 months (July 2004—February 2005) - 1,791 total moves - 335 moves within same building Time Period B: 22 months (March 2005—December 2006) - 455 total moves - 7% of employees move each year - 13 moves within same building

17. Data Sources Data Analysis / Preparation Low Level Algorithmic Components Mid Level Algorithmic Components High Level Algorithmic Components User Interface Filter and Classify Input Data Problem Domain Reduction Examples Classify Personnel for Space Requirements Determine Pools of Compatible Space

18. Data Sources Low Level Algorithmic Components Mid Level Algorithmic Components High Level Algorithmic Components User Interface Components for modeling aspects of optimization problem Examples Space represents areas to be assigned, i.e. rooms Consumers represent any function that consumes space, i.e. people, technical functions, conference areas Data Analysis / Preparation

19. Data Sources Mid Level Algorithmic Components High Level Algorithmic Components User Interface Components for modeling requirements and goals of optimization problem Constraints Minimum necessary conditions May reduce problem domain Metrics Define the measures for an optimal solution Use a cost-based minimization approach Data Analysis / Preparation Low Level Algorithmic Components

20. Data Sources Mid Level Algorithmic Components High Level Algorithmic Components User Interface Examples Constraints Space Compatibility Minimal Area Requirements Consumer Compatibility Metrics Move Cost Office Area Per Person Synergy Data Analysis / Preparation Low Level Algorithmic Components

21. System Architecture Synergy Metric –Hierarchical, flat interaction model assumes equal interaction between peers in each organization –Reality is different –Organizations self-organize –Use current allocation to find probable interactions

22. Data Sources High Level Algorithmic Components User Interface Components for modeling techniques for searching problem domain Examples Local Greedy Heuristic Random Search, Tabu Search, Simulated Annealing, Genetic Algorithms, Hybrid Techniques Data Analysis / Preparation Low Level Algorithmic Components Mid Level Algorithmic Components

23. Search Techniques Large Search Space –Exhaustive Search not possible –Find the best local optima in a limited amount of time

24. Search Techniques Greedy Approach –From a random starting point, proceed in the most downhill direction –compare features of local optima Beyond Greedy –implement simple tabu search

25. Current NASA configuration

26. Local Optimum: NASA Space Allocation

27. Status Visualization tools largely complete Primary metrics and constraints for personnel defined and implemented Greedy Heuristic implemented to search from any initial state to a local optimum Continuing to tune heuristic to improve speed and adjust definition of local neighborhood with new operators

28. Status Plan to extend local search by including simple tabu search features Plan to experiment with long term memory by keeping track of high (low) quality partial solutions