DocumentCode
1028557
Title
A burst-mode word-serial address-event link-II: receiver design
Author
Boahen, Kwabena A.
Author_Institution
Dept. of Bioeng., Univ. of Pennsylvania, Philadelphia, PA, USA
Volume
51
Issue
7
fYear
2004
fDate
7/1/2004 12:00:00 AM
Firstpage
1281
Lastpage
1291
Abstract
We present a receiver for a scalable multiple-access inter-chip link that communicates binary activity between two-dimensional arrays fabricated in deep submicron CMOS. Recipients are identified by row and column addresses but these addresses are not communicated simultaneously. The row address is followed sequentially by a column address for each active cell in that row; this cuts pad count in half without sacrificing communication capacity. Column addresses are decoded as they are received but cells are not written individually. An entire burst is written to a row in parallel; this increases communication capacity with integration density. Rows are written one by one but bursts are not processed one at a time. The next burst is decoded while the last one is being written; this increases capacity further. We synthesized an asynchronous implementation by performing a series of program decompositions, starting from a high-level description. Links using this design have been implemented successfully in three generations of submicron CMOS technology.
Keywords
CMOS logic circuits; asynchronous circuits; logic design; multi-access systems; pipeline arithmetic; quantisation (signal); receivers; 2D arrays; active cell; asynchronous implementation; asynchronous logic synthesis; binary activity; burst-mode word-serial address-event link; column address; communication capacity; event-driven communication; high-level description; integration density; neuromorphic systems; pipelining; pixel-level quantization; program decompositions; receiver design; row address; scalable multiple-access interchip link; serial-to-parallel conversion; submicron CMOS; CMOS logic circuits; CMOS technology; Decoding; Logic arrays; Multiplexing; Neuromorphics; Pipeline processing; Quantization; Sensor arrays; Silicon; Asynchronous logic synthesis; event-driven communication; neuromorphic systems; pipelining; pixel-level quantization; serial-to-parallel conversion;
fLanguage
English
Journal_Title
Circuits and Systems I: Regular Papers, IEEE Transactions on
Publisher
ieee
ISSN
1549-8328
Type
jour
DOI
10.1109/TCSI.2004.830702
Filename
1310499
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