TY - GEN
T1 - I/O clustering in design cost and performance optimization for flip-chip design
AU - Chen, Hung Ming
AU - Liu, I. Min
AU - Wong, Martin D.F.
AU - Shao, Muzhou
AU - Huang, Li Da
PY - 2004
Y1 - 2004
N2 - I/O placement has always been a concern in modern IC design. Due to flip-chip technology, I/O can be placed throughout the whole chip without long wires from the periphery of the chip. However, because of I/O placement constraints in design cost and performance, I/O buffer planning becomes a pressing problem. During the early stages of circuits and packaging co-design, I/O layout should be evaluated to optimize design cost and to avoid product failures. In this paper, our objective is to better an existing/initial standard cell placement by I/O clustering, considering design cost reduction and signal integrity preservation. We formulate it as a minimum cost flow problem minimizing αW + βD, where W is the I/O wirelength of the placement and D is the total voltage drop in the power network. The experimental results on some MCNC benchmarks show that our method achieves better timing performance and averagely over 30% design cost reduction when compared with the conventional design rule of thumb popularly used by circuit designers.
AB - I/O placement has always been a concern in modern IC design. Due to flip-chip technology, I/O can be placed throughout the whole chip without long wires from the periphery of the chip. However, because of I/O placement constraints in design cost and performance, I/O buffer planning becomes a pressing problem. During the early stages of circuits and packaging co-design, I/O layout should be evaluated to optimize design cost and to avoid product failures. In this paper, our objective is to better an existing/initial standard cell placement by I/O clustering, considering design cost reduction and signal integrity preservation. We formulate it as a minimum cost flow problem minimizing αW + βD, where W is the I/O wirelength of the placement and D is the total voltage drop in the power network. The experimental results on some MCNC benchmarks show that our method achieves better timing performance and averagely over 30% design cost reduction when compared with the conventional design rule of thumb popularly used by circuit designers.
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U2 - 10.1109/ICCD.2004.1347978
DO - 10.1109/ICCD.2004.1347978
M3 - Conference contribution
AN - SCOPUS:17644363769
SN - 0769522319
T3 - Proceedings - IEEE International Conference on Computer Design: VLSI in Computers and Processors
SP - 562
EP - 567
BT - Proceedings - IEEE International Conference on Computer Design
T2 - Proceedings - IEEE International Conference on Computer Design: VLSI in Computers and Processors, ICCD 2004
Y2 - 11 October 2004 through 13 October 2004
ER -