Information Technology in 2050

1. Team Green IT: Joshua Blum and Jesika Haria Background • Internet use and data transfer are ever growing • This growth is associated with an enormous energy consumption  • Architectural and structural modifications are needed in the IT infrastructure. Information Technology in 2050 Source: CTR, Jan 2011 Recommended Solutions Issues and Constraints • Reduce system inefficiencies • Integrated Si photonics • Scale down size of Ge photodetector to reduce power consumption • Data center inefficiencies • Circuit inefficiencies • Moore's Law limitations Principles of Engineering Practice 2011 UT-MIST-MIT International Seminar on Materials

2. Presentation Summary

3. Background (Trends vs. current technology) Energy consumed by IT has increased 10x since 2006 to 15% of total energy consumption  A PC runs at 6% efficiency, data centers run at 56% efficiency  The IT industry accounts for 2% of the world's GHG emissions, higher than the airline industry Power Usage Effectiveness (PUE), Data Center Performance Efficiency (DCPE) and Input-Output Operations (IOPs)/ Watt are some metrics that can be used to measure data center efficiency 

4. By 2030, IT traffic will consume 100% of Japan's current energy production Energy (TWh) IP Routers Internet traffic Time (years) Source: METI and MIC

5. Data centers have huge losses, mostly cooling, low utilization and UPS • Only 2.5% of energy entering a data center goes to useful computing  System Constraints Source: Rocky Mountain Institute

6. Circuit Constraints • Moore's Law states that the number of transistors that can be placed inexpensively on a circuit doubles every year • Moore's Law is approaching its limit now • Current metal interconnect technologies are hugely inefficient due to power losses  P: Power C: Capacitance V: Voltage f : Frequency  Source: Moore's Law, Wikipedia Architectural and structural changes need to be made

7. Architectural Recommendations • Nano-Data Centers • Energy Proportional Computing  • Cloud Computing Recommendations 

8. Structural Recommendations • Integrated Si photonics • Ge photodetectors Recommendations  Source: Characterizing the Business Environment

9. Nano-Data Centers (NaDa) • P2P network • Saves in cooling costs • Less data travel distance • Estimated to save 30-40% of cooling costs Architectural Recommendations  • Energy Proportional Computing (EPC) • Servers & computers typically operate at 10%-50% of utilization • Eliminates baseline power waste • Technology present in mobile device • Cloud Computing • Works hand and hand with NaDa and EPC • Distributes workload over many devices • Allows instant access to files Source: Case for EPC 2007

10. Si Integrated photonics • Convergence on the "last mile" of photonics and electronics • Inter-chip communications & all connections less than 5cm Structural Recommendations  • Ge Photodetectors • Used for large difference in index of refraction from Si (4.0 vs. 3.5) • Power consumption proportional to area (capacitance) and applied voltage • Need a 1000x reduction to limit consumption curve (IT in Japan) Source: Si Integrated Ge JFET Photodetector, J Wang

11. Architectural modifications will eliminate system inefficiencies present • For long term energy reduction, photonics will take the lead • Goal is to reduce power consumption by 1000x by scaling down and integrating photonic devices.  Analysis Source: Intel Corporation, 2010

12. Consequences • Growth is sustainable if technology creates efficiencies. • As needs scale up, efficiency must scale up proportionately. • By making IT more efficient, other sectors can become more efficient as well.  Energy (TWh) IP Routers Internet traffic Implementation Time (years) Source: METI and MIC • In 10 years, bring in architectural changes and begin implementing structural modifications • In 50 years, physical limitations of photonics will be reached, beginning of a new learning curve.   • Beyond 50 years, begin new learning curve for IT with new technologies... ... along with time travel, teleportation, and lightsabers?