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Evaluating a DVS Scheme for Real-Time Embedded Systems

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Title: Evaluating a DVS Scheme for Real-Time Embedded Systems


1
Evaluating a DVS Scheme for Real-Time Embedded
Systems
  • Ruibin Xu, Daniel Mossé and Rami Melhem

2
Introduction
  • Energy conservation is important for real-time
    embedded systems
  • Dynamic Voltage Scaling (DVS) is effective in
    power management
  • A popular problem minimizing energy consumption
    while meeting the deadlines

3
Focus
  • Frame-based systems that execute variable
    workloads
  • The problem becomes minimizing the expected
    energy consumption while meeting the deadlines


4
A New DVS Scheme (MEEC)
emsoft05
simplified problem
original problem
relax
efficient algorithm
Evaluations
fix
optimal solution
practical solution
parc05
5
Task and System Model
  • N periodic tasksT1, T2, , TN to be executed
    consecutively in each frame
  • The power function is p(f) c0c1f a

6
Review of Existing Schemes
Proportional Scheme
Greedy Scheme
Statistical Scheme
7
The MEEC Scheme
  • Incorporates the variability of the tasks into
    the speed schedule
  • The variability of the tasks are captured by the
    probability density function of the workload of
    the tasks
  • Aims to minimize the expected energy consumption
    in the system

probability
workload
8
The MEEC Scheme
slack
ß1
9
An Important Property
The optimal expected energy consumption for
10
Computing ßi
T1
T2
T3
T4
11
Applying PACE
  • PACE is a technique in which the execution speed
    is gradually increased as the task progresses

12
The MEEC Scheme
  • The ß values (optimal) are computed based on the
    assumption of unrestricted continuous frequency
  • We need to deal with
  • Minimum and maximum speed restriction
  • Discrete speed
  • We have solutions and will use simulation to test
    them

13
Evaluations Power models
  • Synthetic processor
  • Strictly conforms to p(f)f3
  • 10 frequencies 100MHz, 200MHz,, 1000MHz
  • Intel Xscale
  • Power numbers from Intel datasheets
  • p(f) 801520(f/1000)3

14
Evaluation Synthetic Workload
  • We simulated systems that have 5,10,15,20 tasks
  • The WCEC of each task is randomly generated from
    10M to 1G cycles
  • The probability distribution of each task is
    randomly chosen from 6 representative
    distributions
  • Frame length

15
Evaluation Synthetic Workload
  • We evaluated 8 schemes
  • Proportional with and without PACE
  • Greedy with and without PACE
  • Statistical with and without PACE
  • MEEC with and without PACE
  • We simulated 100,000 frames and computed the
    average energy consumption per frame for each
    scheme

16
Results Synthetic Workload
  • For synthetic CPU, the best scheme is always MEEC
    (with or without PACE), but MEEC with PACE is
    only better than MEEE without PACE 13.6 of the
    time with an average saving of 1.2
  • For Intel Xscale, the best scheme is always MEEC
    without PACE
  • Conclusion PACE is not recommended in the MEEC
    scheme

17
Why PACE Is Not Good in MEEC scheme?
PACE (under the assumption of unrestricted
continuous frequency)
18
Results Synthetic Workload
19
Evaluation Automatic Target Recognition (ATR)
  • The ATR application does pattern matching of
    targets in images
  • The regions of interest (ROI) in the image are
    detected and each ROI is compared with all the
    templates
  • Image processing time is proportional to the
    number of ROIs

20
Evaluation Automatic Target Recognition (ATR)
  • A front-end is responsible for collecting images
    and send them to the back-end periodically for
    target recognition
  • This application can be modeled as a frame-based
    real-time system in which all the tasks have the
    same workload distribution

front-end

back-end
21
Evaluation Automatic Target Recognition (ATR)
  • Simulation setup
  • Use Intel Xscale
  • The period is 100ms
  • The front-end sends 1 to 6 images to the back-end
  • The number of ROIs in an image varies from 1 to 8
  • The back-end precomputes 6 speed schedules

22
Results - Automatic Target Recognition (ATR)
23
Summary
  • In this paper, we demonstrate and evaluate a new
    DVS scheme that aims to minimize the expected
    energy consumption in the system

24
Conclusions
  • The MEEC scheme achieves significant energy
    savings over the existing schemes
  • Using only static information or aggregating
    dynamic information, even with probabilistic
    techniques, will not produce as good results as
    when dynamic information for each task in
    considered separately

25
  • Thank you

26
A Simple Example
  • 3 tasks, the frame length is 14 time units
  • For the CPU, c00, c11, fmin0, and fmax1
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