PICMET 20 talk in Portland Oregon on August 4th 2011 - discussing energy and buildings and holistic service systems that delivery whole service to the people in them...

1. Sustainable Energy & Holistic Service Systems Dr. James (“Jim”) C. Spohrer [email_address] Innovation Champion and Director, IBM University Programs Worldwide PICMET 20, Portland, Oregon, USA August 4 th ,, 2011

2. PICMET: Happy 20 th Year!!!

4. IBM Centennial: Icon of Progress

5. Growth of Service in National Economies Daryl Pereira/Sunnyvale/IBM@IBMUS, Parallels the growth of cities and the digital knowledge economy High Talent Individuals High Tech Infrastructure 42% 64 33 3 1.4 Germany 37% 26 11 63 2.1 Bangladesh 19% 20 10 70 1.6 Nigeria 45% 67 28 5 2.2 Japan 64% 69 21 10 2.4 Russia 61% 66 14 20 3.0 Brazil 34% 39 16 45 3.5 Indonesia 23% 76 23 1 5.1 U.S. 35% 23 17 60 14.4 India 142% 29 22 49 25.7 China 40yr Service Growth S % G % A % Labor % WW Nation World’s Large Labor Forces A = Agriculture, G = Goods, S = Service 2010 2010 NationMaster.com, International Labor Organization Note: Pakistan, Vietnam, and Mexico now larger LF than Germany US shift to service jobs (A) Agriculture: Value from harvesting nature (G) Goods: Value from making products (S) Service: Value from IT augmented workers in smarter systems that create benefits for customers and sustainably improve quality of life.

6. Growth of Service Revenue at IBM SOFTWARE SYSTEMS (AND FINANCING) SERVICES 2010 Pretax Income Mix Revenue Growth by Segment Services Software Systems 44% 17% 39% IBM Annual Reports

7. What is service science? A service system? The ABC’s? Economics & Law Design/ Cognitive Science Systems Engineering Operations Computer Science/ Artificial Intelligence Marketing “ a service system is a human-made system to improve provider-customer interactions and value-cocreation outcomes, studied by many disciplines, one piece at a time.” “ service science is the transdisciplinary study of service systems & value-cocreation” The ABC’s: The provider (A) and a customer (B) transform a target (C)

9. The need for efficiency in buildings is clear 2 nd Real estate is the 2 nd largest expense on the income statement. 50% Up to 50% of energy and water in buildings are often wasted. 2025 By 2025, buildings will be the #1 consumer of energy. 2x Data center energy use doubling every 5 years .

10. The benefits from improving building efficiency are real 18% rise in productivity Employee productivity increased up to 18% on average. 91% occupancy Higher building usage and re- up rates in smarter buildings. 40% reduction Energy usage reduced by up to 40% and maintenance cost 10-30%. 65% of occupants Willing to help make their workplace more environmentally responsible.

11. How does a building operate today? Building Systems Building & Communications Services Facilities Management Processes Interaction with Externalities Portfolio Estates Mgmt Occupancy Space Mgmt Waste Mgmt Trash/Water/Recycle Compliance Environmental reports Tenant Services Help Desk Asset Mgmt Lifecycle Building Services Maintenance Industry Specific Hospital, hotel, etc. Energy Use Passive/Active Fire Functionality checks, Detector service Water Smart Meters, Use / Flow Sensing HVAC Fans, Variable Air Volume, Air Quality Elevators Maintenance, Performance Access/Security Badge in, Cameras, Integration Perimeter, Doors, Floors, Occupancy Lighting Occupancy Sensing 24/7 Monitoring Condition Monitoring, Parking Lot Utilization Energy Smart Meters, Demand response Community Services Transportation, Traffic, Events Utilities Demand Mgmt, Cost Control Weather Current Predictions Emergency Services Alerts, Actions Commercial Potential Advertisement

12. The New Normal: Smarter Systems Computational System Smarter Technology Requires investment roadmap Service Systems: Stakeholders & Resources 1. People 2. Technology 3. Shared Information 4. Organizations connected by win-win value propositions Smarter Buildings, Universities, Cities Requires investment roadmap

13. Corning: A Day Made of Glass (Our Homes) http://www.youtube.com/watch?v=6Cf7IL_eZ38

14. Complex Buildings: Luxury Hotels http://www.youtube.com/watch?v=Hm7MeZlS5fo

15. Complex Buildings: Urban University Campus “ When we combined the impact of Harvard’s direct spending on payroll, purchasing and construction – the indirect impact of University spending – and the direct and indirect impact of off-campus spending by Harvard students – we can estimate that Harvard directly and indirectly accounted for nearly $4.8 billion in economic activity in the Boston area in fiscal year 2008, and more than 44,000 jobs.”

16. U-BEEs: University-Based Entrepreneurial Ecosystems Universities as “Living Labs” for Host Cities UNIVERSITIES: Research Centers & Real-World Systems CITIES/METRO REGIONS: Universities Key to Long-Term Economic Development

19. What is a Smarter Planet? INSTRUMENTED We now have the ability to measure, sense and see the exact condition of practically everything. INTERCONNECTED People, systems and objects can communicate and interact with each other in entirely new ways. INTELLIGENT We can respond to changes quickly and accurately, and get better results by predicting and optimizing for future events. WORKFORCE PRODUCTS SUPPLY CHAIN COMMUNICATIONS TRANSPORTATION BUILDINGS IT NETWORKS

20. Our planet is a complex, dynamic, highly interconnected $54 Trillion system-of-systems (OECD-based analysis) Communication $ 3.96 Tn Transportation $ 6.95 Tn Leisure / Recreation / Clothing $ 7.80 Tn Healthcare $ 4.27 Tn Food $ 4.89 Tn Infrastructure $ 12.54 Tn Govt. & Safety $ 5.21 Tn Finance $ 4.58 Tn Electricity $ 2.94 Tn Education $ 1.36 Tn Water $ 0.13 Tn Global system-of-systems $54 Trillion (100% of WW 2008 GDP) Same Industry Business Support IT Systems Energy Resources Machinery Materials Trade Legend for system inputs Note: 1. Size of bubbles represents systems’ economic values 2. Arrows represent the strength of systems’ interaction Source: IBV analysis based on OECD This chart shows ‘systems‘ (not ‘industries‘)  Our planet is a complex system-of-systems 1 Tn

21. Economists estimate, that all systems carry inefficiencies of up to $15 Tn, of which $4 Tn could be eliminated How to read the chart: For example, the Healthcare system‘s value is $4,270B. It carries an estimated inefficiency of 42%. From that level of 42% inefficiency, economists estimate that ~34% can be eliminated (= 34% x 42%).  We now have the capabilities to manage a system-of-systems planet Source: IBM economists survey 2009; n= 480 Global economic value of $4 Trillion 7% of WW 2008 GDP Improvement potential $15 Trillion 28% of WW 2008 GDP Inefficiencies $54 Trillion 100% of WW 2008 GDP System-of-systems System inefficiency as % of total economic value Improvement potential as % of system inefficiency Education 1,360 Building & Transport Infrastructure 12,540 Healthcare 4,270 Government & Safety 5,210 Electricity 2,940 Financial 4,580 Food & Water 4,890 Transportation (Goods & Passenger) 6,950 Leisure / Recreation / Clothing 7,800 Communication 3,960 Analysis of inefficiencies in the planet‘s system-of-systems Note: Size of the bubble indicate absolute value of the system in USD Billions 42% 34% This chart shows ‘systems‘ (not ‘industries‘)

25. Systems-Discipline Matrix: More Detail disciplines systems Systems that focus on flows of things Systems that govern Systems that support people’s activities transportation & supply chain water & waste food & products energy & electricity building & construction healthcare & family retail & hospitality banking & finance ICT & cloud education &work city secure state scale nation laws social sciences behavioral sciences management sciences political sciences learning sciences cognitive sciences system sciences information sciences organization sciences decision sciences run professions transform professions innovate professions e.g., econ & law e.g., marketing e.g., operations e.g., public policy e.g., game theory and strategy e.g., psychology e.g., industrial eng. e.g., computer sci e.g., knowledge mgmt e.g., stats & design e.g., knowledge worker e.g., consultant e.g., entrepreneur stakeholders Customer Provider Authority Competitors resources People Technology Information Organizations change History (Data Analytics) Future (Roadmap) value Run Transform (Copy) Innovate (Invent) Starting Point 1: Observing the Stakeholders (As-Is) Starting Point 2: Observing their Resources & Access (As-Is) Change Potential: Thinking (Has-Been & Might-Become) Value Realization: Doing (To-Be)

26. What are T-shaped professionals? Ready for Life-Long-Learning Ready for T-eamwork Ready to Help Build a Smarter Planet SSME+D = Service Science, Management, Engineering + Design Many disciplines (understanding & communications ) Many systems (understanding & communications) Deep in one discipline (analytic thinking & problem solving) Deep in one system (analytic thinking & problem solving) Many multi-cultural-team service projects completed (resume: outcomes, accomplishments & awards) BREADTH DEPTH

27. How are advanced technologies changing the mix of jobs? Levy, F, & Murnane, R. J. (2004). The New Division of Labor: How Computers Are Creating the Next Job Market. Princeton University Press. Expert Thinking Complex Communication Routine Manual Non-routine Manual Routine Cognitive

28. What are the benefits of more education? Of higher skills? … But it can be costly, American student loan debt is over $900M

29. What are the benefits of top-ranked universities? % WW GDP and % WW Top-500-Universities Strong Correlation (2009 Data): National GDP and University Rankings http://www.upload-it.fr/files/1513639149/graph.html

31. Overview: Elements of Interest Policies & Investments Run-Transform-Innovate Governance Frameworks Theories Models Sept 27 th Workshop at IBM Almaden Infrastructure & Environment (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life & Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Infrastructure (Technologies Deployed) Individuals & Certified Competences (Skills) Institutions & Roles (Jobs) Information, Quality-of-Life Demographics (Careers) Region 1 Region 2 Future Present History Policies & Investments Run-Transform-Innovate Governance Policies & Investments Run-Transform-Innovate Governance Policies & Investments Run-Transform-Innovate Governance Policies & Investments Run-Transform-Innovate Governance

38. Stakeholder Priorities Education Research Business Government Service Systems Customer-provider interactions that enable value cocreation Dynamic configurations of resources: people, technologies, organisations and information Increasing scale, complexity and connectedness of service systems B2B, B2C, C2C, B2G, G2C, G2G service networks Service Science To discover the underlying principles of complex service systems Systematically create, scale and improve systems Foundations laid by existing disciplines Progress in academic studies and practical tools Gaps in knowledge and skills Develop programmes & qualifications Service Innovation Growth in service GDP and jobs Service quality & productivity Environmental friendly & sustainable Urbanisation & aging population Globalisation & technology drivers Opportunities for businesses, governments and individuals Skills & Mindset Knowledge & Tools Employment & Collaboration Policies & Investment Develop and improve service innovation roadmaps, leading to a doubling of investment in service education and research by 2015 Encourage an interdisciplinary approach The white paper offers a starting point to - The Birth of Service Science: A Framework for Progress ( http://www.ifm.eng.cam.ac.uk/ssme/ ) Source: Workshop and Global Survey of Service Research Leaders (IfM & IBM 2008) Glossary of definitions, history and outlook of service research, global trends, and ongoing debate 1. Emerging demand 2. Define the domain 3. Vision and gaps 4. Bridge the gaps 5. Call for actions

39. Priorities: Research Framework for the Science of Service (2010) Source: Global Survey of Service Research Leaders (Ostrom et al 2010) Pervasive Force: Leveraging Technology to Advance Service Strategy Priorities Execution Priorities Fostering Service Infusion and Growth Improving Well-Being through Transformative Service Creating and Maintaining a Service Culture Stimulating Service Innovation Enhancing Service Design Optimizing Service Networks and Value Chains Effectively Branding and Selling Services Enhancing the Service Experience through Cocreation Measuring and Optimizing the Value of Service Development Priorities

46. Urban-Age.Net Currently, the world’s top 30 cities generate 80% of the world’s wealth. The Urban Age For the first time in history more than 50% the earth’s population live in cities - by 2050 it will be 75% The Endless City

48. Time ECOLOGY 14B Big Bang (Natural World) 10K Cities (Human-Made World) sun (energy) writing (symbols and scribes, stored memory and knowledge) earth (molecules & stored energy) written laws (governance and stored control) bacteria (single-cell life) sponges (multi-cell life) money (governed transportable value stored value, “ economic energy”) universities (knowledge workers) clams (neurons) trilobites (brains) printing press (books) steam engine (work) Where is the “Real Science” - mysteries to explain? In the many sciences that study the natural and human-made worlds… Unraveling the mystery of evolving hierarchical-complexity in new populations… To discover the world’s architectures and mechanisms for computing non-zero-sum Entity Architectures (Є N ) of nested, networked Holistic-Product-Service-Systems (HPSS) 200M bees (social division-of-labor) 60 transistor (routine cognitive work)

56. Service system entities learn to systematically exploit technology: Technology can perform routine manual, cognitive, transactional work March, J.G. (1991) Exploration and exploitation in organizational learning. Organizational Science. 2(1).71-87. Sanford, L.S. (2006) Let go to grow: Escaping the commodity trap. Prentice Hall. New York, NY. L Learning Systems (“Choice & Change”) Exploitation (James March) Exploration (James March) Run/Practice-Reduce (IBM) Transform/Follow (IBM) Innovate/Lead (IBM) Operations Costs Maintenance Costs Incidence Planning & Response Costs (Insure) Incremental Radical Super-Radical Internal External Interactions “ To be the best, learn from the rest” “ Double monetize, internal win and ‘sell’ to external” “ Try to operate inside the comfort zone”

61. What about advanced manufacturing? http://www.youtube.com/watch?v=nd5WGLWNllA

62. Rethinking “Product-Service Systems” F B Service System Entity Product-Service-System B F SSE B F SSE B F SSE B F SSE B F SSE B F SSE B F SSE B F SSE B F SSE B F SSE B F F F B B Service Business Product Business Front-Stage Marketing/Customer Focus Back-Stage Operations/Provider Focus Based on Levitt, T (1972) Production-line approach to service. HBR. e.g., IBM e.g., Citibank “ Everybody is in service... Something is wrong… The industrial world has changed faster than our taxonomies.”.

63. Example Service Systems Innovation Framework “ The Ten Types of Innovation” by Larry Keeley, Doblin Inc. Innovate (inside and outside) systems that create value

64. Most Wanted: A CAD for Service System Design CBM: Component Business Model WBM and RUP: Work Practices & Processes SOA: Technical Service-Oriented Architecture Key Performance Indicators (KPIs) IBM IBV: Component Business Models IEEE Computer, Jan 2007

71. Understanding the Human-Made World See Paul Romer’s Charter Cities Video: http://www.ted.com/talks/paul_romer.html Also see: Symbolic Species, Deacon Company of Strangers, Seabright Sciences of the Artificial, Simon

72. Fun: CityOne Game to Learn “CityInvesting” Serious Game to teach problem solving for real issues in key industries, helping companies to learn how to work smarter. Energy, Water, Banking, Retail http://www.ibm.com/cityone

73. Where are the opportunities? Everywhere!

80. University: The Heart of Regional Innovation Ecosystems School of Public Policy School of Engineering School of Business Mngmnt School of Medicine School of Education School of Architecture School of Urban Planning School of Hospitality School of Information School of Science & Arts University: The Heart of Regional Innovation Ecosystems Incubator & Start-Ups $ Cities & Public Safety Government Service to Individuals & Institutions Education Transportation Energy ICT (Computing & Communications) Retail & Hospitality Food & Products Health Building Finance University: The Heart of Regional Innovation Ecosystems