a low-power precomputation-based parallel cam chi-sheng lin, jui-chang, bin-da liu ieee2003

A Low-Power Precomputation-Based Parallel CAM

Chi-Sheng Lin, Jui-Chang, Bin-Da Liu

IEEE2003

Outline

Intro CAM Design concept of PB-CAM Circuit Design of PB-CAM Improved PB-CAM Experimental Results ConclusionConclusion

Intro

Parallel CAM function is used widelylookup tables, databases, associative computing, data compression, etc.

It need large power to achieve parallel CAM

CAM

Design concept of PB-CAM

To reduce the comparison between input and the stored data.

Add parameter extractor, parameter memory.

Design concept of PB-CAM

Design concept of PB-CAM

With an m words by n bits CAM size

PB-CAM:1th comparison: m*upon[log(n+2)]2th comparison: (m*n)/(n+1)Total=1th+2th

CAM:Total=M*(upon[log(n+2)+1])

Design concept of PB-CAM

Circuit Design of PB-CAM

Traditional dynamic CAM:1) The dynamic circuit needs an extra precharge time for

each data searching operation.

2) The dynamic circuit has some problems, such as charge sharing and noise problems.

3) A clock signal is necessary to handle the circuit operation.

4) The noise margin of dynamic circuit is less than .

Traditional dynamic CAM

Circuit Design of PB-CAM

static pseudo-nMOS circuita) In the data searching operation, if the valid bit i

s invalid(v=1) , then the PM1 is turned off and the NM1 is turned on.

b) Otherwise, PM1 is turned on, and NM1 is turned off.

pseudo-nMOS circuit

Circuit Design of PB-CAM

Another problem of pseudo-nMOS circuit. power dissipation

With an m-words CAM size input data only matches one stored data per dat

a searching operation. m-1 data mismatching between stored data and

input data per data searching operation.

Circuit Design of PB-CAM

Circuit Design of PB-CAM

parameter comparison circuit is used to control the pull-up PM1.

Therefore, the number of PB-CAM word circuits that consume static power is reduced to ((m/n-1)-1) .

Circuit Design of PB-CAM

Traditional CAM cell is constructed by typical nine-transistor

six-transistor SRAM cell to store a data bit, an XOR-type comparison circuit containing two nMOS transistors, and an nMOS pull-down device to drive the word match line

Circuit Design of PB-CAM

Circuit Design of PB-CAM

Proposed PB-CAM cell

five-transistor D-latch device to store a data bit and a NAND-type comparison circuit containing two nMOS transistors to drive the word match line.

To achieve low-voltage operation, the feedback inverter (INV2) is a weak-driving design to allow the input data(BL) to be stored in the D-latch device easily.

Circuit Design of PB-CAM

Circuit Design of PB-CAM

Advantage:

1. Searching time is better

2. Simplifies HW design

3. reduces operating voltage Disadvantage

1. Access performance is poorer

Improved PB-CAM

Because of the parameter extraction function

lot difference between probability of parameters.

Table of 14 bits ones-count parameter extractor

Block XOR approach

Block XOR approach

Table of 14 bits Block XOR PB-CAM

Experimental Results

Experimental Results

Experimental Results

ConclusionConclusion

Based on the precomputation methodology, the circuit reduces most of the comparison operations and transistors to achieve low-power, low-cost, and low-voltage features.