Your search keyword '"Kuo SY"' showing total 7 results

1. Clock-Aware Placement for Large-Scale Heterogeneous FPGAs.

Author

Chen, Jianli, Lin, Zhifeng, Kuo, Yun-Chih, Huang, Chau-Chin, Chang, Yao-Wen, Chen, Shih-Chun, Chiang, Chun-Han, and Kuo, Sy-Yen

Subjects

GATE array circuits, FIELD programmable gate arrays, ALGORITHMS, COORDINATE transformations

Abstract

A modern field-programmable gate array (FPGA) often contains an ASIC-like clocking architecture which is crucial to achieve better skew and performance. Existing conventional FPGA placement algorithms seldom consider clocking resources, and thus may lead to clock routing failures. To address the special FPGA clocking architecture, this article presents an effective clock-aware placement algorithm for large-scale heterogeneous FPGAs. Our algorithm consists of four major technologies: 1) a combinatorial clock fence region method to effectively reduce the overuse of clocking resources; 2) a smoothed heterogeneous density function to lead heterogeneous blocks to desired sites and a coordinate transformation technique to facilitate CLB cell spreading; 3) a heterogeneous force modulation algorithm to stabilize placement movement and a hierarchical contraction technique to remedy an insufficiency of the multilevel placement framework; and 4) a two-level clock-aware packing and legalization scheme to generate an optimized, clocking-violation-free placement. We evaluate our results based on the ISPD 2017 Clock-Aware Placement Contest benchmark suite. Compared with the state-of-the-art placers, the experimental results show that our algorithm achieves the best-routed wirelength. [ABSTRACT FROM AUTHOR]

Published

2020

2. Quantum walks for crossed cubes.

Author

Lin, Tein-Sheng, Chang, Ting-Hsu, Chien, Chia-Hung, Wang, Shiou-An, and Kuo, Sy-Yen

Abstract

This paper proposes a quantum switching on crossed cube, the diameter of the crossed cube is almost half of that of the hypercube, to execute quantum walks. Quantum walks can be implemented in the hypercube and general graphs. Hypercube is a regular graph. According to quantum walk algorithm, the system can preserve unitary property of quantum walks. In the regular graph, to develop quantum walks algorithm is focused on quantum search algorithm. The proposed circuit is to use quantum state, transferring from source node to destination for find the searching object. The small diameter is the best criterion to simulate the behavior of the proposed mechanism. This work selects crossed cube as the research topics with the following two major clauses. One is the small diameter and the other is the exchanged crossed state. The crossed cube has the half diameter of the hypercube. This cube owns the exchanged crossed state that can be used to present the behavior of the entangled particles. Quantum switching is reversible circuit and parallel computation circuit. By using parallel computation circuit, the system can achieve the better performance in time complexity and space complexity. Based on quantum switching, the system can trace the behavior of quantum walks from input sequence to output sequence, and obtains the benefit in time complexity and space complexity for quantum search algorithm. [ABSTRACT FROM PUBLISHER]

Published

2013

3. Quantum switching and quantum walks.

Author

Chang, Ting-Hsu, Lin, Tein-Sheng, Chien, Chia-Hung, Lu, Chin-Yung, and Kuo, Sy-Yen

Abstract

Quantum walks can be implemented in the hypercube and general graphs, where hypercube is a regular graph. According to quantum walk algorithm, unitary property of quantum walks can be preserved. In the regular graph, to develop quantum walks algorithm is focused on quantum search algorithm. Quantum switching is the reversible and parallel computation circuits, where parallel computation circuit can achieve the better performance in time complexity and space complexity. Especially, this switching can trace the behavior of quantum walks from input sequence to output sequence, looking as quantum search algorithm. Furthermore, application of unicasting and multicasting can be implemented in this circuit. [ABSTRACT FROM PUBLISHER]

Published

2013

4. Throughput improvement of multi-hop wireless mesh networks with cooperative opportunistic routing.

Author

Liang, Yu-Shan, Chung, Wei-Ho, Zhang, Hongke, and Kuo, Sy-Yen

Abstract

This paper proposes cooperative opportunistic routing (COR), a throughput improvement scheme for the cooperative opportunistic routing in multi-hop wireless mesh networks (WMNs). We investigate the two major issues in opportunistic routing, the selection and the prioritization metric for the candidate set. The COR is presented to select and prioritize the candidate node with minimum expected cost. This candidate selection with low expected cost on each transmission constructs a throughput efficient routing path. The COR's robust packet handling strategy is also proposed to avoid duplicated transmission without forwarding list. With more efficient candidate set and packet handling, the average throughput improves by 76% and the end-to-end delay is reduced by 15% in our simulation results. [ABSTRACT FROM PUBLISHER]

Published

2012

5. Reversible quantum circuits and quantum transmission integrity.

Author

Lin, Tien-Sheng, Chien, Chia-Hung, Chang, Ting-Hsu, Yuan, Shih-Yi, and Kuo, Sy-Yen

Abstract

This paper proposes a novel work to design reversible quantum circuits. The function of this circuit is to investigate quantum transmission integrity in the quantum communication networks. This work is to verify quantum transmission sequence of a quantum frame by using reversible quantum model. This model designs control module to derive the correlation between two quantum strings: quantum input sequence and quantum output sequence. If a quantum frame reserves the correlation, then we can obtain quantum transmission sequence. So, quantum transmission integrity of a quantum frame can be verified. [ABSTRACT FROM PUBLISHER]

Published

2011

6. Quantum authentication protocol using entanglement swapping.

Author

Chien, Chia-Hung, Lin, Tien-Sheng, Chang, Ting-Hsu, Yuan, Shih-Yi, and Kuo, Sy-Yen

Abstract

In this paper, we use the technique of entanglement swapping to exchange quantum message among sharing parties. For Bell measurements, quantum teleportation can provide long-distance quantum transmission when sharing parties are disconnected. The proposed mutual authentication protocol has the capability to securely identify each other under an unsafe routing path. Eavesdropping and malicious nodes may exist in the routing path. For quantum authentication protocol, it is called location-release problem. The proposed approach can solve this problem. Furthermore, source can transfer quantum message to destination in a secure way. [ABSTRACT FROM PUBLISHER]

Published

2011

7. Obstacle-Avoiding Rectilinear Steiner Tree Construction: A Steiner-Point-Based Algorithm.

Author

Liu, Chih-Hung, Kuo, Sy-Yen, Lee, D. T., Lin, Chun-Syun, Weng, Jung-Hung, and Yuan, Shih-Yi

Subjects

*TREE graphs, *PERFORMANCE evaluation, *COMPUTATIONAL complexity, *HEURISTIC algorithms, *VECTOR spaces, *VERY large scale circuit integration

Abstract

For the obstacle-avoiding rectilinear Steiner minimal tree (OARSMT) problem, we present a Steiner-point-based algorithm that achieves the best practical performance among existing heuristics. We first propose a new concept of Steiner point locations, creating a linear-space routing graph with satisfactory Steiner point candidates to resolve the bottleneck of most existing heuristics. Then, we propose a Steiner-point-based framework to yield a solution, which is close to the key to the handling of the OARSMT problem. Experimental results show that this algorithm achieves excellent solution quality and speed performance at the same time. We also extend the Steiner-point-based framework to the obstacle-avoiding preferred direction Steiner tree problem with a good performance. [ABSTRACT FROM PUBLISHER]

Published

2012