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8th JIEEECAmman, Jordan17 April 2013

Pavel Loskotp.loskot@swan.ac.uk

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• April 2008 workshops defined 2 targets:• identify cross-layer techniques to obtain 100x energy reduction• identify green network architecture including backhaul

Green Radio project (Jan. 2009 – June 2012)

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Why and How of Green Communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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Why and how of Green communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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Green comms – first look• energy together with information is one of the most complex and

fundamental subjects

1) Primary contributors to CO2 emissions:

• electric power generation, transport, manufacturing• ICT accounts for only 3% (electronics in household 5%)

2) Rising fuel cost:• Base Stations in Radio Access Network (RAN) consumes 80% of

total energy of cellular systems• total energy bill to operate RAN represents only 7% of total cost

Why to bother with energy efficiency then?

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Green comms – main motivations• Growth of wireless access: • from 3.3mil BS in 2007 to 11.2mil BS in 2020

with energy consumption from 49TWh to 98TWhwith average data rate from 60kbit/s to 18Mbit/s

• i.e., energy cost from 28 J/kbits to mere 0.2 J/kbits

Future wireless access has to be a lot more energy efficient!

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Green comms – resource management

Spectrum • shared resource• strictly limited• one-off cost• generate income

Energy• shared resource• unlimited (almost)• recurring cost• eat profits

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Energy consumption – first look

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Why and how of Green communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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RAN – operational energy

life time: 10-15 yrs 1-1.5 yrs

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Base station – money matters

• Return-on-Investment (ROI)• Take-up rate

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Base station – power budget

• overall efficiency < 10%• total power 600-800W (GSM), 300-500W (WCDMA)

with typical 10W per channel/sector

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Cellular networks – traffic trends

• majority of traffic indoors• strong spatial and temporal variations

(e.g. urban areas, hotspots, time of day)• mobile broadband rapidly growing

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Green comms – market drivers• Developed countries:• good infrastructure• almost saturated• bottleneck is QoS and

inbuilding coverage• key to improve profits

• Emerging countries:• less infrastructure• good growth opportunities• large geographical areas• bottleneck is power supply• key is energy efficiency

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Why and how of Green communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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Energy consumption – modeling

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Energy consumption – modeling• Power states: power consumption when• transmitting P

tx

• receiving Prx

• iddle Piddle

• sleep Psleep

Rule of thumb:• the smaller the node, the smaller differences between

power state values• for marcrocell base station, may consider only P

tx

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Energy – measurements• 1. Energy metrics• what quantities to report (peak, average, effective values)• equipment or whole sub-systems

• 2. Measurement procedures• methodology, conditions, vendor-neutral

• Standardization efforts:• European Telecommunications Standards Institute (ETSI)• Alliance for Telecommunications Industry Solutions (ATIS)• International Telecommunication Union (ITU)• Energy Consumption Rating (ECR) Initiative

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Energy – metrics• Energy Consumption Rating

• Energy Efficiency Rate

• Telecommunications Energy Efficiency Ratio (ATIS)

• ITU metrics

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Energy metrics – Radio Access Networks• Energy Consumption Rate

• Energy Reduction Gain

• Energy Consumption Gain

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Why and how of Green communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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Energy efficiency – improvements

1) Reduce transmission distances • small cells (pico, femto …) with macrocell overlays• distributed antennas, mesh architectures• relays and other cooperative transmissions

•

• 2) Use spectrum more efficiently• reduce interference (e.g. coordinated mutipoint)

3) Sleep modes• turn off components or whole nodes• modify protocols (e.g. MAC)

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Energy efficiency – improvements4) Shape traffic

• incentives for energy efficient behavior

5) Improve hardware• BS design (Power Amp, Cooling, Remote Radio Heads)• lower switching times (for sleep modes)

6) Concentrate traffic• to smaller sub-networks (e.g. shared base stations)• to smaller time epochs (e.g. delay agile traffic)

Transmit as fast as possible!

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Green comms – green baseband • Integrated circuits (IC):• power proportional to silicon area• area proportional to throughput• throughput proportional to bandwidth

• Making IC greener:• functions reuse (reduce area)• turn more SW into hardware

(sacrifice flexibility)

• Ultimately:• replace semiconductors

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Telecom equipment – powering• Alternative energy sources• need to be used continuously• lack of integration• lack of remote monitoring• onerous deployment

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Battery lifetime – drivers• Wireless sensor networks:• driving Internet of Things and initially

also techniques for Green Comms• improving battery lifetime is key• energy harvesting

• Mobile handsets:• battery lifetime less important• transceivers may be very

energy inefficient

• New technologies

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Why and how of Green communications

1. Initial considerations

2. Statistics and observations

3. Metrics and measurements

4. Approaches and solutions

5. Future trends

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Green comms – main players

Overall energy strategic priorities

Spectrum and max RF powers, total energy

Max embodied energy,max operational energy

Coverage and QoS, energy per bit

Coverage and QoS, battery lifetime

Operational energyRF power

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Green comms – conflicts of interest

max RF powers

min operational energy

limit RF powers

max battery life max QoS

min overall energy

limit RF powers

min embodied energy

min operational energy

min RF powers

min RF powers

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Green comms – future• Policies and regulations• trade energy in transport for energy in ICT• cooperation among network operators• define how much ICT services

• ICT as utility• new business models• incentives for energy efficiency• highly flexible (adaptive)• selective availability, beyond best effort

• Hardware to lead signal processing• batteries, power amplifiers, plastic electronics

•

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Green comms – concluding remarks• Energy minimization• holistic approach is mandatory• how to align aims of all players is still unclear

• Publications• energy issues is more art than science, papers written by

industrial practitioners more impressive than by academics

• Standards• energy consumption strongly related to implementation, yet

all standards abstract from implementation

For now, it is profits not energy what drives telecom industry!

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Thank you!

Questions?