1. ELEC 5270/6270 Spring 2009 Low-Power Design of Electronic Circuits Power Aware Microprocessors
Vishwani D. Agrawal
James J. Danaher Professor
Dept. of Electrical and Computer Engineering
Auburn University, Auburn, AL 36849
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

2. SIA Roadmap for Processors (1999)
Year
1999
2002
2005
2008
2011
2014
Feature size (nm)
180
130
100 70 50 35
Logic transistors/cm2
6.2M
18M
39M
84M
180M
390M
Clock (GHz)
1.25
2.1
3.5
6.0
10.0
16.9
Chip size (mm2)
340
430
520
620
750
900
Power supply (V)
1.8
1.5
1.2
0.9
0.6
0.5
High-perf. Power (W) 90
160
170
175
183
Source:
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

3. Power Reduction in Processors
Just about everything is used.
Hardware methods:
Voltage reduction for dynamic power
Dual-threshold devices for leakage reduction
Clock gating, frequency reduction
Sleep mode
Architecture:
Instruction set
hardware organization
Software methods
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

4. SPEC CPU2000 Benchmarks
Twelve integer and 14 floating point programs, CINT2000 and CFP2000.
Each program run time is normalized to obtain a SPEC ratio with respect to the run time of Sun Ultra 5_10 with a 300MHz processor.
CINT2000 and CFP2000 summary measurements are the geometric means of SPEC ratios.
LINPACK is numerically intensive floating point linear system (Ax = b) program used for benchmarking supercomputers.
SPECPOWER_ssj2008 measures power and performance of a computer system.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

5. Reference CPU s: Sun Ultra 5_10 300MHz Processor
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

6. CINT2000: 3.4GHz Pentium 4, HT Technology (D850MD Motherboard)
SPECint2000_base = 1341
SPECint2000 = 1389
Source:
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

7. Two Benchmark Results
Baseline: A uniform configuration not optimized for specific program:
Same compiler with same settings and flags used for all benchmarks
Other restrictions
Peak: Run is optimized for obtaining the peak performance for each benchmark program.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

8. CFP2000: 3.6GHz Pentium 4, HT Technology (D925XCV/AA-400 Motherboard)
SPECfp2000_base = 1627
SPECfp2000 = 1630
Source:
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

9. CINT2000: 1.7GHz Pentium 4 (D850MD Motherboard)
SPECint2000_base = 579
SPECint2000 = 588
Source:
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

10. CFP2000: 1.7GHz Pentium 4 (D850MD Motherboard)
SPECfp2000_base = 648
SPECfp2000 = 659
Source:
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

11. Energy SPEC Benchmarks
Energy efficiency mode: Besides the execution time, energy efficiency of SPEC benchmark programs is also measured. Energy efficiency of a benchmark program is given by:
1/(Execution time)
Energy efficiency = ────────────
joules consumed
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

12. Energy Efficiency Efficiency averaged on n benchmark programs: n
Efficiency = ( Π Efficiencyi )1/n
i=1
where Efficiencyi is the efficiency for program i.
Relative efficiency:
Efficiency of a computer
Relative efficiency = ─────────────────
Eff. of reference computer
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

13. SPEC2000 Relative Energy Efficiency
Always
max. clock
Laptop
adaptive clk.
Min. power
min. clock
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

14. Voltage Scaling
Dynamic: Reduce voltage and frequency during idle or low activity periods.
Static: Clustered voltage scaling
Logic on non-critical paths given lower voltage.
47% power reduction with 10% area increase reported.
M. Igarashi et al., “Clustered Voltage Scaling Techniques for Low-Power Design,” Proc. IEEE Symp. Low Power Design, 1997.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

15. Processor Utilization
Throughput = Operations / second
Compute-intensive
processes
Maximum
throughput
Low throughput
(background)
processes
Throughput
System
idle
Time
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

16. Examples of Processes
Compute-intensive: spreadsheet, spelling check, video decoding, scientific computing.
Low throughput: data entry, screen updates, low bandwidth I/O data transfer.
Idle: no computation, no expected output.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

17. Effects of Voltage Reduction
Voltage reduction increases delay, decreases throughput:
Slow reduction in throughput at first
Rapid reduction in throughput for VDD ≤ Vth
Time per operation (TPO) increases
Voltage reduction continues to reduce power consumption:
Energy per operation (EPO) = Power × TPO
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

18. Energy per Operation (EPO)
1.0
0.5
0.0
EPO
Power
TPO
VDD / Vth
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

19. Dynamic Voltage and Clock
Throughput
Time spent in:
Battery life
Fast mode
Slow mode
Idle mode
Always full speed
10% 0%
90%
1 hr
Sometimes full speed 1% 9%
5.3 hrs
Rarely full speed
0.1%
99%
0.9%
9.2 hrs
T. D. Burd and R. W. Brodersen, Energy Efficient Microprocessors,
Springer, 2002, pp
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

20. Example: Find Minimum Energy Mode
Processor data (rated operation):
2 GHz clock
1.5 volt supply voltage
0.5 volt threshold voltage
Power consumption
50 watts dynamic power
50 watts static power
Maximum clock frequency for V volt supply
f α (V – VTH)/V
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

21. Example Cont. Dynamic power: Pd = CV2f = C(1.5)2×2×109 = 50W
C = nF, capacitance switching/cycle
Pd = V2f
Dynamic energy per cycle:
Ed = Pd/f = V2
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

22. Example Cont. Clock frequency:
f = k (V – VTH)/V = k (1.5 – 0.5)/1.5 = 2 GHz
k = 3 GHz, a proportionality constant
f = 3(V – 0.5)/V GHz
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

23. Example Cont. Static power: Ps = k’ V2 = k’ (1.5)2 = 50W
k’ = mho, total leakage conductance
Ps = V2
Static energy per cycle:
Es = Ps/f = V3/[3(V – 0.5)]
= 7.41 V3/(V – 0.5)
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

24. Example Cont. Total energy per cycle:
E = Ed + Es = V V3/(V – 0.5)
To minimize E, ∂E/∂V = 0, or
5V2 – 4.6V = 0
Solutions of quadratic equation:
V = volt, volt
Discard second solution, which is lower than the threshold voltage of 0.5 volt.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

25. Example: Result Rated mode Low energy mode Reduction (%) Voltage 1.5 V
54.7%
Clock frequency
2 GHz
791 MHz
60%
Dynamic energy/cycle
25.00 nJ
5.12 nJ
79.52%
Static energy/cycle
12.96 nJ
48.16%
Total energy/cycle
50.0 nJ
18.08 nJ
63.84%
Dynamic power
50.0 W
4.05 W
91.90%
Static power
10.25 W
79.50%
Total power
100.0 W
14.20 W
85.80%
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

26. Problem of Process Variation in Nanometer Tecchnologies
Clock
specification
Power
specification
From a presentation: Power Reduction using LongRun2 in Transmeta’s
Efficon Processor, by D. Ditzel
May 17, 2006
Number of chips
Nominal
voltage
Lower voltage operation
Higher voltage operation
Yield loss
due to high
leakage
Yield loss
due to slow
speed
Lower Vth Vth Higher Vth
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

27. Pipeline Gating A pipeline processor uses speculative execution.
Incorrect branch prediction results in pipeline stalls and wasted energy.
Idea: Stop fetching instructions if a branch hazard is expected:
If the count (M) of incorrect predictions exceeds a pre-specified number (N), then suspend fetching instruction for some k cycles.
Ref.: S. Manne, A. Klauser and D. Grunwald, “Pipeline Gating: Speculation Control for Energy Reduction,” Proc. 25th Annual International Symp. Computer Architecture, June 1998.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

28. Slack Scheduling Application: Superscalar, out-of-order execution:
An instruction is executed as soon as the required data and resources become available.
A commit unit reorders the results.
Delay the completion of instructions whose result is not immediately needed.
Example of RISC instructions:
add r0, r1, r2; (A)
sub r3, r4, r5; (B)
and r9, x1, r9; (C)
or r5, r9, r10; (D)
xor r2, r10, r11; (E)
J. Casmira and D. Grunwald,
“Dynamic Instruction Scheduling
Slack,” Proc. ACM Kool Chips
Workshop, Dec
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

29. Slack Scheduling Example
Standard scheduling A B C D E
Slack scheduling A B C D E
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

30. Slack Scheduling Re-order buffer Low-power execution units Slack bit
Scheduling logic
Low-power
execution units
Slack bit
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

31. Clock Distribution clock Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

32. Clock Power Pclk = CLVDD2f + CLVDD2f / λ + CLVDD2f / λ2 + . . .
stages – 1 1
= CLVDD2f Σ ─
n = 0 λn
where CL = total load capacitance
λ = constant fanout at each stage in distribution
network
Clock consumes about 40% of total processor power.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

33. Clock Network Examples
Alpha 21064
Alpha 21164
Alpha 21264
Technology
0.75μ CMOS
0.5μ CMOS
0.35μ CMOS
Frequency (MHz)
200
300
600
Total capacitance
12.5nF
Clock gating used. Total power W
Clock load
3.25nF
3.75nF
Clock power
40%
40% (20W)
Max. clock skew
200ps (<10%)
90ps
D. W. Bailey and B. J. Benschneider, “Clocking Design and Analysis for
a 600-MHz Alpha Microprocessor,” IEEE J. Solid-State Circuits, vol. 33,
no. 11, pp , Nov
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

34. Power Reduction Example
Alpha 21064: 3.45V, power dissipation = 26W
Reduce voltage to 1.5V, power (5.3x) = 4.9W
Eliminate FP, power (3x) = 1.6W
Scale 0.75→0.35μ, power (2x) = 0.8W
Reduce clock load, power (1.3x) = 0.6W
Reduce frequency 200→160MHz, power (1.25x) = 0.5W
J. Montanaro et al., “A 160-MHz, 32-b, 0.5-W CMOS RISC Microprocessor,” IEEE J. Solid-State Circuits, vol. 31, no. 11, pp , Nov
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12

35. For More on Microprocessors
T. D. Burd and R. W. Brodersen, Energy Efficient Microprocessor Design, Springer, 2002.
R. Graybill and R. Melhem, Power Aware Computing, New York: Plenum Publishers, 2002.
Copyright Agrawal, 2007
ELEC6270 Spring 09, Lecture 12