Lecture Notes in Computer Science 4917

More documents

Recommendations

Info

Implementation of an UWB Impulse-Radio Acquisition and Despreading Algorithm 95 Large reductions have been accomplished by: – Optimization and simplification of the algorithm, – Adding custom operations, – Removing unused register files, issue slots and functional units, – Introducing a loopcache, – Introducing top-level clock gating, – Introducing power gating of elements in SIMD operations. The algorithmic optimization and simplification combined with custom operations resulted in a reduced cycle count with a factor between 2 and 11, also the number of words was reduced from 180 to 110 instruction words. Custom operations resulted in a speed-up of a factor 5. Customizing the architecture of the processor resulted in a reduced instruction word size from 224 to 91 bit. Top-level clock gating reduced the Idlepower consumption with a maximum of 1.2 mW. A loopcache reduced the power consumption to fetch an instruction word with a factor 4. When the processor is combined with features such as adaptive voltage control, leakage power reduction and is tuned further to the application we believe that the energy dissipation for each net data bit, compared to the ASIC, can be reduced with a maximum of 70%. Acknowledgement This work is part of an innovation project at the High Tech Campus Eindhoven where Silicon Hive and the Holst Centre cooperate. This paper is written in partial fulfillment of obtaining a master’s degree in Electrical Engineering at the Eindhoven University of Technology. Thanks go out to M. Berekovic from IMEC-NL, J. Huisken from Silicon Hive, J. van Meerbergen from Philips Research and O. Rousseaux from IMEC-NL for their guidance and feedback. References 1. IEEE Std P802.15.4a/d6, PART 15.4: Wireless medium access control (MAC) and physical layer (PHY) specifications for low-rate wireless personal area networks (LR-WPANs): Amendment to add alternate PHY (2006) 2. Badaroglu, M., Desset, C., Ryckaert, J., et al.: Analog-digital partitioning for low-power UWB impulse radios under CMOS scaling. EURASIP Journal on Wireless Communications and Networking 2006, Article ID 72430 8 (2006) 3. Ryckaert, J., Badaroglu, M., Desset, C., et al.: Carrier-based UWB impulse radio: simplicity, flexibility, and pulser implementation in 180 nm CMOS. In: CU 2005. Proceedings of the IEEE International Conference on Ultra-Wideband, Zurich, Switzerland, pp. 432–437 (2005) 4. Ryckaert, J., Badaroglu, M., DeHeyn, V., et al.: A 16mA UWB 3-to-5GHz 20MPulses/s quadrature analog correlation receiver in 180 nm CMOS. In: Proceedings of IEEE International Solid-State Circuits Conference, Digest of Technical Papers, San Francisco Marriott, California, USA (2006)
96 J. Govers et al. 5. Kastrup, B., van Wel, A.: Moustique: Smaller than an ASIC and fully programmable. In: International Symposium on System-on-Chip 2003, Silicon Hive, Philips Technology Incubator, The Netherlands, vol. 2003 (2003) 6. Patterson, D.A., Hennessy, J.L.: Computer organization and design, 2nd edn. The hardware/software interface. Morgan Kaufmann Publishers Inc, San Francisco (1998) 7. Munch, M., Wurth, B., Mehra, R., Sproch, J., Wehn, N.: Automating RT-level operand isolation to minimize power consumption in datapaths. In: DATE 2000. Proceedings of the conference on Design, automation and test in Europe, pp. 624–633. ACM Press, New York (2000) 8. Li, H., Bhunia, S., Chen, Y., Vijaykumar, T.N., Roy, K.: Deterministic clock gating for microprocessor power reduction. In: HPCA 2003. Proceedings of the 9th International Symposium on High-Performance Computer Architecture, p. 113. IEEE Computer Society Press, Washington, DC, USA (2003) 9. Garrett, D., Stan, M., Dean, A.: Challenges in clockgating for a low power ASIC methodology. In: ISLPED 1999. Proceedings of the 1999 international symposium on Low power electronics and design, pp. 176–181. ACM Press, New York (1999) 10. Heo, S.: A low-power 32-bit datapath design. Master’s thesis, Massachusetts Institute of Technology (2000) 11. Jiang, H., Marek-Sadowska, M., Nassif, S.R.: Benefits and costs of power-gating technique. In: ICCD 2005. Proceedings of the 2005 International Conference on Computer Design, pp. 559–566. IEEE Computer Society, Washington, DC, USA (2005) 12. Agarwal, K., Deogun, H.S., Sylvester, D., Nowka, K.: Power gating with multiple sleep modes. In: ACM/IEEE International Symposium on Quality Electronic Design (2006) 13. Arnold, M., Corporaal, H.: Automatic detection of recurring operation patterns. In: CODES 1999, pp. 22–26. ACM Press, New York (1999) 14. Athanas, P.M., Silverman, H.F.: Processor reconfiguration through instruction-set metamorphosis. Computer 26(3), 11–18 (1993) 15. Ysebodt, L., Nil, M.D., Huisken, J., Berekovic, M., Zhao, Q., Bouwens, F.J., van Meerbergen, J.: Design of low power wireless sensor nodes on energy scanvengers for biomedical monitoring. In: Vassiliadis, S., Bereković, M., Hämäläinen, T.D. (eds.) SAMOS 2007. LNCS, vol. 4599, Springer, Heidelberg (2007)
Page 1 and 2:
Lecture Notes in Computer Science 4
Page 3 and 4:
Volume Editors Per Stenström Chalm
Page 5 and 6:
VI Preface The planning of a confer
Page 7 and 8:
VIII Organization Mahmut Kandemir P
Page 9 and 10:
Invited Program Table of Contents S
Page 11:
Table of Contents XIII Turbo-ROB: A
Page 14 and 15:
4 M. Valero and J. Labarta future s
Page 17 and 18:
MIPS MT: A Multithreaded RISC Archi
Page 19 and 20:
2.2 VPEs as Scheduling Domains MIPS
Page 21 and 22:
MIPS MT: A Multithreaded RISC Archi
Page 23 and 24:
6.1 Thread Context Virtualization M
Page 25 and 26:
8 Experimental Results MIPS MT: A M
Page 27 and 28:
Cycles/ Iteration MIPS MT: A Multit
Page 29:
9 Conclusions MIPS MT: A Multithrea
Page 32 and 33:
MPI: Message Passing on Multicore P
Page 34 and 35:
Page 36 and 37:
Page 38 and 39:
overhead per word (cycles) 1200 100
Page 40 and 41:
speedup 3.5 3 2.5 2 1.5 1 0.5 0 rMP
Page 42 and 43:
speedup 9 8 7 6 5 4 3 2 1 0 rMPI: M
Page 44 and 45:
Page 46 and 47:
Page 48 and 49:
Modeling Multigrain Parallelism on
Page 50 and 51:
Page 52 and 53:
Page 54 and 55: Modeling Multigrain Parallelism on
Page 63 and 64: BRAM-LUT Tradeoff on a Polymorphic
Page 65 and 66: 32 L0 L1 BRAM-LUT Tradeoff on a Pol
Page 73: BRAM-LUT Tradeoff on a Polymorphic
Page 76 and 77: Architecture Enhancements for the A
Page 92 and 93: Implementation of an UWB Impulse-Ra
Page 107 and 108: Fast Bounds Checking Using Debug Re
Page 121: Fast Bounds Checking Using Debug Re
Page 124 and 125: Studying Compiler Optimizations on
Page 130 and 131: avg normalized execution time 1.000
Page 140 and 141: CLI as an Effective Deployment Form
Page 155 and 156:
Compilation Strategies for Reducing
Page 157 and 158:
Page 159 and 160:
Page 161 and 162:
Page 163 and 164:
Page 165 and 166:
Page 167 and 168:
180% 160% 140% 120% 100% 80% 60% 40
Page 169 and 170:
Experiences with Parallelizing a Bi
Page 171 and 172:
Page 173 and 174:
Page 175 and 176:
Page 177 and 178:
Page 179 and 180:
Page 181 and 182:
Page 183:
Page 186 and 187:
Drug Design Issues on the Cell BE 1
Page 188 and 189:
Page 190 and 191:
Page 192 and 193:
Page 194 and 195:
speed-up 8 6 4 2 0 FFT3D 256 64-A F
Page 196 and 197:
Page 198 and 199:
Page 201 and 202:
COFFEE: COmpiler Framework for Ener
Page 203 and 204:
Page 205 and 206:
Benchmark Source Code * transformed
Page 207 and 208:
Page 209 and 210:
RTL for each Component * Gate−lev
Page 211 and 212:
Page 213 and 214:
Normalized Cycle Count 1.00 0.90 0.
Page 215 and 216:
Page 217 and 218:
Integrated CPU Cache Power Manageme
Page 219 and 220:
Page 221 and 222:
Page 223 and 224:
Page 225 and 226:
Page 227 and 228:
Page 229 and 230:
Page 231:
Page 234 and 235:
Variation-Aware Software Techniques
Page 236 and 237:
Page 238 and 239:
Page 240 and 241:
Page 242 and 243:
Page 244 and 245:
Average leakage-power saving (%) Va
Page 246 and 247:
Page 248 and 249:
Page 250 and 251:
244 Y. Sazeides et al. of mispredic
Page 252 and 253:
246 Y. Sazeides et al. Affector BB1
Page 254 and 255:
248 Y. Sazeides et al. 2.3 How to U
Page 256 and 257:
250 Y. Sazeides et al. Cumulative D
Page 258 and 259:
252 Y. Sazeides et al. ijpeg, andbo
Page 260 and 261:
254 Y. Sazeides et al. Misses/KI 12
Page 262 and 263:
256 Y. Sazeides et al. Mahlke and N
Page 265 and 266:
Turbo-ROB: A Low Cost Checkpoint/Re
Page 267 and 268:
260 P. Akl and A. Moshovos Original
Page 269 and 270:
262 P. Akl and A. Moshovos Oldest I
Page 271 and 272:
264 P. Akl and A. Moshovos new firs
Page 273 and 274:
266 P. Akl and A. Moshovos throttli
Page 275 and 276:
268 P. Akl and A. Moshovos 80% 70%
Page 277 and 278:
270 P. Akl and A. Moshovos 25% 20%
Page 279:
272 P. Akl and A. Moshovos [4] Burg
Page 282 and 283:
274 A. García et al. execution tim
Page 284 and 285:
276 A. García et al. whenever LPA
Page 286 and 287:
278 A. García et al. @12: load r2,
Page 288 and 289:
280 A. García et al. Target Loop E
Page 290 and 291:
282 A. García et al. reduction 100
Page 292 and 293:
284 A. García et al. IPC speedup 7
Page 294 and 295:
286 A. García et al. SPECfp benchm
Page 297 and 298:
Complementing Missing and Inaccurat
Page 299 and 300:
90 100 100 25 75 25 25 100 100 10 1
Page 301 and 302:
Page 303 and 304:
Page 305 and 306:
Page 307 and 308:
6.1 Filling Edge Profile from Verte
Page 309 and 310:
Page 311 and 312:
Using Dynamic Binary Instrumentatio
Page 313 and 314:
L1 D-Cache Miss Rate (%) CPI 5 4 3
Page 315 and 316:
Page 317 and 318:
Page 319 and 320:
CPI Error (%) 10 5 0 -5 -10 FP Resu
Page 321 and 322:
CPI Error (%) 40 30 20 10 0 Using D
Page 323 and 324:
Page 325:
Page 328 and 329:
Phase Complexity Surfaces: Characte
Page 330 and 331:
Page 332 and 333:
Page 334 and 335:
Page 336 and 337:
( log10) phases of Number 4.0 3.5 3
Page 338 and 339:
Page 340 and 341:
Page 343 and 344:
MLP-Aware Dynamic Cache Partitionin
Page 345 and 346:
Page 347 and 348:
Page 349 and 350:
Page 351 and 352:
Page 353 and 354:
(a) IPC as we vary the number of as
Page 355 and 356:
Page 357 and 358:
Page 359 and 360:
Compiler Techniques for Reducing Da
Page 361 and 362:
Page 363 and 364:
Page 365 and 366:
Page 367 and 368:
Page 369 and 370:
Page 371 and 372:
40 35 30 25 ) te ( % 20 -ra M is s
Page 373 and 374:
References Compiler Techniques for
Page 375 and 376:
Code Arrangement of Embedded Java V
Page 377 and 378:
Page 379 and 380:
Page 381 and 382:
Page 383 and 384:
Page 385 and 386:
Page 387 and 388:
Page 389:
Page 392 and 393:
Aggressive Function Inlining: Preve
Page 394 and 395:
f1(){ ...g();....} f2(){....q();...
Page 396 and 397:
Page 398 and 399:
Page 400 and 401:
foo:(80 times) BB1: Call bar BB2: C
Page 402 and 403:
Page 404 and 405:
Page 406:
400 Author Index Shajrawi, Yousef 3
show all

Lecture Notes in Computer Science 4917

You also want an ePaper? Increase the reach of your titles

Delete template?

Save as template?