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A dynamic scheduling mechanism in cellular networks
Qiuyang TangSupervisor : Prof. Riku JänttiInstructor : Zhonghong Ou
Aalto University
Department of Communications and Networking
Outline
• Introduction
• Background
• System model and assumptions
• Scheduling method
• Numerical study
• Conclusions
Introduction
• Increasingly more energy-hungry applications have been used by mobile users.
• Energy consumption of mobile handsets had increasingly become a concern for various parties.
• Signal strength plays an important role in energy consumption of mobile devices in cellular network.
• In this thesis, a dynamic scheduling mechanism is presented to optimize energy efficiency of mobile devices in HSDPA and LTE networks.
Background
Figure 1: UMTS system architecture(Harri&Antti 2010)
Background
Figure 2: Basic LTE system architecture(Harri&Antti 2011)
System model and assumptions
• HSDPA simulation topology and link characteristics
System model and assumptions
• LTE simulation topology
System model and assumptions
• The propagation model includes distance loss and fast fading models.
• The distance loss model is described by Okumura-Hata model for medium cities:
where
• The fast fading model is based on Jakes model for Rayleigh fading.
System model and assumptions
• The energy consumption model contains transmission energy model and tail energy model.
• Downlink transmission energy model:
• Uplink transmission energy model:
• Tail energy model: tail-time = 6 seconds, tail-power=620 mW
Scheduling method• The basic idea of the scheduling mechanism is that the transmission is
suspended if the received signal strength is below the predefined signal strength threshold.
Scheduling method- signal smoothing• In order to remove the signal strength variations due to fast fading, the
LOWESS signal smoothing algorithm is applied along with the scheduler.
Numerical study-HSDPA• Impact of signal strength
• Simulation tool: NS-2.
• Simulation time: 10 seconds
• Cell radius: 1000 m
Numerical study-HSDPA • Simulation tool: NS-2. • Simulation time: 600 seconds X 3 iterations• UE mobility: Random waypoint model with speed from 5 m/s to 30 m/s• Number of UEs: [20, 200] • Received power threshold: -89 dBm
Numerical study-HSDPA • Opportunistic transmission: data transmission is triggered only when the
signal strength is larger than the threshold value.
• Continuous transmission: data transmission is triggered independent of the signal strength
• Average UE throughput
Numerical study-HSDPA• Instant throughput CDF• Number of UEs: 200
Numerical study-HSDPA • Energy consumption for downloading a 100 MB file
• Number of UEs: 200
• Average energy saving: 62.35%
Numerical study-LTE• Impact of signal strength
• Simulation tool: NS-2.
• Simulation time: 10 seconds
• Cell radius: 1000 m
Numerical study-LTE• Simulation tool: NS-3. • Simulation time: 600 seconds X 3 iterations• UE mobility: Random waypoint model with speed from 5 m/s to 30 m/s• Received power threshold: -89 dBm• Number of cells: 1• Number of UEs: 50
Downlink instant throughput CDF Uplink instant throughput CDF
Numerical study-LTE
• Average energy saving
Numerical study-LTE
• LOWESS signal smoothing algorithm
Numerical study -LTE• Energy consumption comparison using signal smoothing
Average downlink energy consumption Average uplink energy consumption
Conclusion
• Signal strength has significant impact on throughput and energy consumption.
• The dynamic scheduling mechanism works better when the number of users is relatively high.
• Average energy saving for HSDPA is 62.35%.• Average energy saving for LTE downlink is 25% and for
uplink is 27%.• Signal smoothing algorithm reduces 15%-25% energy
consumption.
Thank you!