Abstract
Waveform distortion is a serious problem in higher-frequency signals on printed circuit boards (PCBs). To overcome this problem, we have already proposed the segmental transmission line (STL) method, which divides transmission lines into several segments with different line widths. Each line width is adjusted to make the reflection noises cancel each other out in order to minimize the signal distortion. In this research, we first analyze the waveform reshaping mechanism of STL. Next, we apply STL to a dual in-line memory module (DIMM) clock-line for high-speed computers. The results give helpful guidelines for STL designs, which shows the efficiency of STL.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Explore related subjects
Discover the latest articles, news and stories from top researchers in related subjects.References
Sekine T, Kobayashi K, Yokokawa S (2000) Transient analysis of nonuniform transmission line using the finite-difference time-domain method (in Japanese). J IEICE A J83-A(9):1062–1070
Sekine T, Kobayashi K, Yokokawa S (2001) Transient analysis of lossy nonuniform transmission line using the finite-difference time-domain method (in Japanese). J IEICE A J84-A(8):1018–1026
Delaurenti M, Graziano M, Masera G, et al. (2001) Switching noise analysis framework for high-speed logic families. 14th International Conference on VLSI Design, IEEE Computer Society Press, Bangalore, India, pp 524–530
Nishi T (2003) Foundations of circuit theory towards the 21st century, V. Analysis of distributed circuits (in Japanese). J IEICE 81(2):202–210
Yasunaga M, Yoshihara I, Kimm JH (2003) The design of a segmental transmission line for high-speed digital signals using genetic algorithms. Proceedings of CEC 2003, IEEE Press, Canberra, Australia, pp 1748–1755
Yasunaga M, Yoshihara I (2004) Ensuring signal integrity on highspeed digital signals using the segmental transmission line (in Japanese). IEICE SIG-FIIS 04, No. 143, pp 1–6
Yasunaga M, Yoshihara I (2005) The segmental transmission line and its design methodology: line trace ensuring high signal integrity in VLSI mounting boards (in Japanese). J IEICE D-I, J88-D-I (5):915–929
Koizumi N, Yoshihara I, Yamamori K, Yasunaga M, et al. (2005) Variable-length segmental transmission line and its parameter optimization based on GA. Proceedings of CEC 2005, IEEE Press, Edinburgh, UK, pp 1576–1582
Koizumi N, Yoshihara I, Yamamori K, et al. (2006) Enhancement of the variable-length transmission line design method for multi-point optimization. Proceedings of CEC 2006, IEEE Press, Vancouver, Canada (CD-ROM)
Satoh H, Yamamura M, Kobayashi S (1996) Minimal generation gap model for gas considering both exploration and exploitation. Proceedings of the International Conference on Soft Computing, Japan Society for Fuzzy Theory and Systems, Iizuka, Japan, pp 494–497
Sato H, Ono I, Kobayashi S (1997) A new generation alternation model of genetic algorithms and its assessment (in Japanese). Trans JSAI 12:734–744
Takahashi O, Kita H, Kobayashi S (2000) A real-coded genetic algorithm using a distance-dependent alternation model for complex function optimization. Proceedings of GECCO 2000, Morgan Kaufmann, Las Vegas, USA, pp 219–226
Yoshida K, Yamamura M, Kobayashi S (1996) Generating Pareto optimal decision trees by GAs. Proceedings of the 4th International Conference on Soft Computing, Japan Society for Fuzzy Theory and Systems, Iizuka, Japan, pp 854–859
Fonseca, Fleming (1993) Genetic algorithms for multiobjective optimization: formulation, discussion and generalization. Proceedings of the 5th ICGA, Morgan Kaufmann, San Mateo, USA, pp 416–423
Srinivas N, Deb K (1994) Multiobjective optimization using nondominated sorting in genetic algorithms. Evolut Comput 2: 221–248
Deb K, Pratap A, Agarwal S, Meyarivan T, et al. (2002) A fast and elitist multiobjective genetic algorithm: NSGA-II. IEEE Trans Evolut Comput 6:182–197
Eshelman W, Schaffer JD (1993) Real-coded genetic algorithms and interval-schemata. Foundations Genetic Algorithms 2:187–202
Ono I, Kobayashi S (1997) A real-coded genetic algorithm for function optimization using unimodal distribution crossover. Proceedings of the 7th ICGA, Morgan Kaufmann, San Francisco, USA, pp 246–253
Higuchi T, Tsutsui S, Yamamura M (1999) Multi-parent recombination with simplex crossover in real-coded genetic algorithms. Proceedings of GECCO99, Morgan Kanfmann, Orlando, USA, pp 657–664
Author information
Authors and Affiliations
Corresponding author
About this article
Cite this article
Koizumi, N., Hayashi, K., Yasunaga, M. et al. Variable-length segmental transmission line and its design guidelines. Artif Life Robotics 12, 214–218 (2008). https://doi.org/10.1007/s10015-007-0493-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10015-007-0493-1