Title :
Thermal-aware task mapping for reconfigurable channel decoding
Author :
Shu-Yen Lin ; Cheng-Hung Lin ; Ho-Yun Su
Author_Institution :
Dept. of Electr. Eng., Yuan Ze Univ., Jungli, Taiwan
Abstract :
Low-Density Parity-Check (LDPC) and Turbo codes are the most popular channel coding for wire-line and wireless communication systems. The reason is that their error-correcting abilities are much closer to the Shannon limit. In real design, many channel decoders are designed with the reconfigurable architectures to support multiple communication systems. In the reconfigurable architectures, only parts of the function units works in runtime, and the task mapping become very important. The unfair task mapping may result in the unbalanced thermal distribution and increase the hotspots in the channel decoder chip. In this work, we propose three thermal-aware task mapping schemes for a reconfigurable radix-4 soft-input soft-output (SISO) kernel of channel decoding. By the proposed thermal-aware task mapping, the peak temperature can reduce up to 4.8°C in our experiments.
Keywords :
biomedical communication; biomedical equipment; channel coding; decoding; parity check codes; reconfigurable architectures; LDPC; SISO; Shannon limit; channel coding; channel decoder chip; error-correcting abilities; function units; low-density parity-check; multiple communication systems; peak temperature; reconfigurable architectures; reconfigurable channel decoding; reconfigurable radix-4 soft-input soft-output kernel; runtime; temperature 4.8 degC; thermal-aware task mapping schemes; turbo codes; unbalanced thermal distribution; unfair task mapping; wire-line communication systems; wireless communication systems; Decoding; Iterative decoding; Kernel; Thermal analysis; Timing; WiMAX; Hotspot; LDPC code; Thermal mapping; Turbo code;
Conference_Titel :
Bioelectronics and Bioinformatics (ISBB), 2014 IEEE International Symposium on
Conference_Location :
Chung Li
Print_ISBN :
978-1-4799-2769-2
DOI :
10.1109/ISBB.2014.6820914
