Design of TCAM Architecture for Low Power and High Performance Applications

Yıl 2019, Cilt: 32 Sayı: 1, 164 - 173, 01.03.2019

Satti V V Satyanarayana Sriadibhatla Srıdevı

Öz

Content
Addressable Memory (CAM) is a special
memory used in search engines for numerous applications, especially in network
routers for packet forwarding. The CAM
operation begins with pre-charging followed by evaluating the match-lines (MLs)
for searching the data in the stored memory. CAM stores unique words in their
array of cells such that only one word is
matched for a given search word. ML associated with matched word retains
its state and the remaining MLs drain their charge. Ternary content addressable
memory (TCAM) is a fast lookup hardware device used for high-speed packet
forwarding. However, significant power
consumption and high cost limits its versatility and popularity. In this paper,
a design has been made for TCAM
architecture with pre-charge controller. The pre-charge controller helps in
predicting the mismatched MLs during pre-charge phase. This prediction happens
at an early stage and helps in terminating the pre-charging of the line. This assures the design of TCAM which consumes low
power and also improves the performance. The proposed early predict 8 × 8 TCAM architecture simulations were
performed in 45nm technology node using Cadence Virtuoso. The proposed TCAM
design exhibits 16.6% reduction in power, 24.7% decrement in delay and 37.1%
minimization in energy metric than basic TCAM NOR. 

Anahtar Kelimeler

Delay, Early-predict, Match-line, Search-line, Pre-charge, Energy metric, Power

Kaynakça

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