Spectral Efficiency and Energy Consumption Tradeoffs for Reconfigurable Devices in Heterogeneous Wireless Systems
Rahul Amin, Dr. Jim MartinClemson University, Clemson SC Contact: [email protected]://www.cs.clemson.edu/~jmarty
Dr. Ahmed Eltawil, Amr Hussien
University of California, Irvine CA
This project was sponsored in part by NSF through contract ECCS-0948132
Talk Overview Introduction Problem Statement Background System Description Simulation Methodology Results and Discussion Conclusions
Introduction Next Generation Wireless Networks (HetNets)
Made up of several Radio Access Technologies (RATs) such as 2G/3G/4G and Wi-Fi User devices are reconfigurable (or multi-modal) and support a multitude of RATs Joint allocation of network-wide resources in this hetnet environment is shown to be
more efficient than ‘independent’ resource allocation by each RAT Frameworks to support network-wide resource allocation process have been defined
by 3GPP (CRRM, MRRM, JRRM) and IEEE (802.21, P1900.4) working groups
Our Previous Work Studied the spectral efficiency vs. energy consumption tradeoffs while using
reconfigurable devices in a hetnet system For a ‘balanced’ network topology, Random Waypoint mobility model, and an FPGA-
based reconfigurable device, we showed an increase in spectral efficiency of 75% at the cost of twice (2x) the energy consumption
The network topology, mobility model and hardware assumptions had a significant impact on ‘moderate’ improvements (75%) in spectral efficiency that were shown in our previous work
Problem Statement Analyze spectral efficiency vs. energy consumption tradeoffs
resulting from realistic hetnet assumptions that show a ‘significant’ improvement in spectral efficiency
Explore an ‘unbalanced’ network topology where resources of one cellular operator exceed those of another operator
Implement a clustered node movement pattern that changes a highly unfavorable situation to a favorable situation when network-wide resources are jointly allocated
Study the differences in energy consumption for several reconfigurable radio hardware assumptions:▪ (i) ASIC-based radio▪ (ii) FPGA-based radio▪ (iii) Combination of ASIC and FPGA based radio
Background Towards widespread adoption of HetNet system concept
Need: Due to proliferation of smartphones, user data demand is outpacing operator capacity
Steps taken: (i) ‘Wi-Fi offloading’ problem is being rigorously studied by cellular operators where cellular systems interoperate with 802.11 Wi-Fi networks (ii) ‘Femto-cell’ is utilized in practice today to increase spectral efficiency by supplementing the macro-cell with an overlay of smaller, co-operative networks
Energy-efficient reconfigurable device architectures (MPSoC) are being investigated Based on various hardware components such as ASICs, FPGAs and DSPs
System Model
System Description• Nodes (user devices) either have (ASIC-based) static radios
capable of operating in limited number of connectivity modes or they have (ASIC+FPGA or FPGA-based) reconfigurable radios capable of operating in any connectivity mode
• Nodes can connect to one or more Autonomous Wireless Systems (AWS) simultaneously
• Each AWS has a controller that represents all nodes in the AWS and that serves as gateway connecting the AWS with other AWSs or external networks
• A Global Resource Controller (GRC) implements a centralized scheduler that maps users to access technologies
• Wireless Virtual Link Layer multiplexes/de-multiplexes data for users associated to multiple AWSs
• Vertical Handovers are initiated by the GRC Reconfiguration handoff - Radio reconfigures itself to operate over a
different AWS
System Use Cases We formulate use cases that assume presence of 2
major cellular carriers in a given area Use Case 1
No co-operation between the two carriers Users use multiple static radios that can connect to its own
carrier’s access technologies Use Case 2
Co-operation exists between the two carriers Reconfigurable radios are used to support access
technologies implemented by the other carrier
Centralized Resource Allocation Select trade-offs between two conflicting objectives
Maximize overall system throughput (Max sum-rate) Maximize fairness amongst users (Max-Min Fair)
Comes up with user to access technology mappings every 1 second
Scheduler properties Wi-Fi resources are evenly distributed Cellular resources are distributed using a two-step approach:▪ Allocate minimum required throughput to each user using its best cellular radios▪ Allocate unused resources to a window of users with best connectivity
parameters in increments of ▪ Any user assigned total throughput of 1 Mbps is not assigned any further cellular
resources The parameters , and help tune the fairness and overall system
throughput characteristics obtained by the scheduler For the results presented in this study, we use (α,β,ω) = (100k, 100k, 10)
Simulation Description• 2 * 2 km2 grid• Carrier 1 – bad coverage area
– 2 EVDO (3G) base-stations at the edge of the grid• Carrier 2 – good coverage area
– 1 HSPA (3G) and 1 LTE (4G) base-station at the center of the grid and 6 IEEE 802.11g (Wi-Fi) APs spread throughput the topology
• Each technology supports adaptive Modulation and Coding Scheme (MCS)• MCS mapping for each user is determined based on distance of the user
from the Base-Station• 100 nomadic users (50 subscribed to Carrier 1 and 50 to Carrier 2)
– Carrier 1 users grouped in 2 clusters; one cluster located at left edge of grid and the other at the right edge of the grid
– Carrier 2 users are grouped in 1 cluster located at the center of the grid– Movement of each user follows Random Waypoint Model and is restricted to an
area of 500 * 500 m2 from its initial starting position• Experimental Parameters
– Network Outage: Varied between 0-25% in increments of 5%– Impact of Reconfiguration: Increased Energy Consumption and Communications
Downtime multiplied by a scalar ∈ [0,1]• Simulation run for 10,000 seconds
Simulation Topology
Simulation Topology from Previous Study (Comparison Purposes Only)
Carrier 2: WiFi
Carrier 1: WiFi
Carrier 1: WiFi
Carrier 1: WiFi
Carrier 2: WiFi
Carrier 2: WiFi
Carrier 1: WiMAX
Carrier 2: LTE
Carrier 2: HSPA
Carrier 1: EVDO
Results and Discussion – Spectral Efficiency
• Worst Case: For no network outage and impact of reconfiguration equal to 1, the spectral efficiency gain for use case 2 (1.43 bits/sec/Hz) when compared to use case 1 (0.34 bits/sec/Hz) is 314.30%.
• Best Case: For 25% network outage and no impact of reconfiguration, the spectral efficiency gain for use case 2 (2.73 bits/sec/Hz) when compared to use case 1 (1.79 bits/sec/Hz) is 553.70%.
• Due to an unbalanced network topology and clustered movement pattern, the spectral efficiency increase which is in the range [314.3%, 553.7] is ‘significantly’ higher compared to [14.3%, 75%] obtained for our previous study
314.3%
553.7%
Results and Discussion – Energy Consumption
• Energy Consumption Model:
where: Pdyn,FPGA represents run-time energy consumption of FPGA-based hardware Pdyn,ASIC represents run-time energy consumption of ASIC-based hardware Prec,FPGA represents energy consumption of FPGA-based hardware during reconfiguration Prec,ASIC represents energy consumption of ASIC-based hardware when switching from ‘off’ to an ‘on’ mode ∝run represents percentage of time system operates in regular mode ∝rec represents percentage of time system operates in reconfiguration mode β percentage of hardware built using FGPA components 1 – β percentage of hardware built using ASIC components λ impact of reconfiguration
• The ratio of Pdyn,FPGA:Pdyn,ASIC is 12:1• Prec,FPGA and Prec,ASIC values are the same
Results and Discussion – Energy Consumption
• Hardware Setting 1: Use Case 1 (Made up of completely ASIC components, i.e. β = 0) vs. Use Case 2 (Made up of completely FPGA components, i.e. β = 1 )
• For increase in spectral efficiency of 314.30% shown earlier, for these hardware assumptions, the increase in energy consumption is 104.90%
• For increase in spectral efficiency of 553.70% also shown earlier, for these hardware assumptions, the increase in energy consumption is 614.9%
• Most pessimistic hardware implementation for a reconfigurable radio in practice. Almost linear tradeoff for worst case increase in energy consumption
104.9%
614.9%
Results and Discussion – Energy Consumption
• Hardware Setting 2: Use Case 1 (Made up of completely ASIC components, i.e. β = 0) vs. Use Case 2 (Made up of 50% ASIC, 50% FPGA components, i.e. β = 0.5 )
• For increase in spectral efficiency of 314.30% shown earlier, for these hardware assumptions, the increase in energy consumption is 70.0%
• For increase in spectral efficiency of 553.70% also shown earlier, for these hardware assumptions, the increase in energy consumption is 355.40%
• Most likely hardware implementation for a reconfigurable radio in practice. Increase in spectral efficiency is greater than increase in energy consumption
70.0%
355.4%
Results and Discussion – Energy Consumption
• Hardware Setting 3: Use Case 1 (Made up of completely ASIC components, i.e. β = 0) vs. Use Case 2 (Made up of completely ASIC components, i.e. β = 0 )
• For increase in spectral efficiency of 314.30% shown earlier, for these hardware assumptions, the increase in energy consumption is 35.10%
• For increase in spectral efficiency of 553.70% also shown earlier, for these hardware assumptions, the increase in energy consumption is 98.80%
• Hardware setting 3 is not really possible in practice. But gives an estimate of increase in energy consumption if the only difference between two use cases is the number of ‘reconfiguration handoffs’ experienced by devices
35.1%
98.8%
Conclusions The gains in spectral efficiency are much greater (increase from
75.5% to 553.7%) for an unbalanced network topology and clustered node movement pattern when compared to a balanced network topology and random waypoint movement pattern studied in our previous work
Based on the hardware choices, the increase in energy consumption can range from 98.80% to 614.90% for the corresponding increase in spectral efficiency of 553.7%
Depending on the number of possible modalities supported by user devices, it might be possible to attain a tradeoff in terms of lower energy consuming ASIC radios at the cost of decreased reconfigurable options
In the worst case, our results show a more or less linear trade-off between spectral efficiency and power consumption
This result is an artifact of our workload assumptions that assume traffic flows are always backlogged. In future work, we will explore more realistic scenarios that involve on/off traffic flows
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