Parameterized Sets of Dataflow Modes And Their Application to Implementation of Cognitive Radio Systems
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- 作者:Shuoxin Lin (1)
Lai-Huei Wang (1)
Aida Vosoughi (2)
Joseph R. Cavallaro (2)
Markku Juntti (3)
Jani Boutellier (3)
Olli Silv茅n (3)
Mikko Valkama (4)
Shuvra S. Bhattacharyya (1)
1. Department of Electrical and Computer Engineering ; Institute for Advanced Computer Studies ; University of Maryland ; College Park ; MD ; 20742 ; USA
2. Department of Electrical and Computer Engineering ; Rice University ; Houston ; TX ; 77005 ; USA
3. Department of Communications Engineering ; Department of Computer Science and Engineering ; University of Oulu ; Oulu ; FI-90014 ; Finland
4. Department of Communications Engineering ; Tampere University of Technology ; Tampere ; FI-33101 ; Finland - 关键词:Cognitive radio ; Dataflow graphs ; Embedded signal processing ; Heterogeneous multiprocessors ; Model ; based design
- 刊名:The Journal of VLSI Signal Processing
- 出版年:2015
- 出版时间:July 2015
- 年:2015
- 卷:80
- 期:1
- 页码:3-18
- 全文大小:973 KB
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16. Plishker, W, Sane, N, Kiemb, M, Bhattacharyya, SS (2008) Heterogeneous design in functional DIF. Samos, Greece
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18. Sane, N, Hsu, C, Pino, JL, Bhattacharyya, SS (2010) Simulating dynamic communication systems using the core functional dataflow model. Dallas, Texas
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21. Siyoum, F., Geilen, M., Moreira, O., Nas, R., Corporaal, H. (2011). Analyzing synchronous dataflow scenarios for dynamic software-defined radio applications. In: Proceedings of the International Symposium on System-on-Chip, pp. 14鈥?1. - 刊物类别:Engineering
- 刊物主题:Electrical Engineering
Circuits and Systems
Computer Imaging, Vision, Pattern Recognition and Graphics
Computer Systems Organization and Communication Networks
Signal,Image and Speech Processing
Mathematics of Computing - 出版者:Springer New York
- ISSN:1939-8115
文摘
Cognitive radio networks present challenges at many levels of design, including configuration, control, and cross-layer optimization. To meet requirements of bandwidth, flexibility and reconfigurability, systematic methods to model and analyze cognitive radio designs on signal processing platforms are desired. To help address these challenges, we present in this paper a novel dataflow modeling technique, called parameterized set of modes (PSM). PSMs allow efficient representation, manipulation and application of related groups of processing configurations for functional design components in signal processing systems. PSMs lead to more concise formulations of actor behavior, and a unified modeling methodology for applying a variety of techniques for efficient implementation. We develop the formal foundations of PSM-based modeling, and demonstrate its utility through two case studies involving the mapping of reconfigurable wireless communication functionality into efficient implementations.