Title: Evolutionary Heuristics for Multiobjective
1Evolutionary Heuristics for Multiobjective VLSI
Netlist Bi-Partitioning
- by
- Dr. Sadiq M. Sait
- Dr. Aiman El-Maleh
- Mr. Raslan Al Abaji
- Computer Engineering Department
2Outline .
- Introduction
- Problem Formulation
- Cost Functions
- Proposed Approaches
- Experimental results
- Conclusion
3VLSI Technology Trend
7.5M333MHz0.25um
Design Characteristics
3.3M200MHz0.6um
1.2M50MHz0.8um
0.13M12MHz1.5um
0.06M2MHz6um
Cycle-basedsimulation,FormalVerification
Top-DownDesign,Emulation
HDLs, Synthesis
CAESystems, Siliconcompilation
Key CAD Capabilities
SPICE Simulation
The Challenges to sustain such an exponential
growth to achieve gigascale integration have
shifted in a large degree, from the process of
manufacturing technologies to the design
technology.
4The VLSI Chip in 2006
Technology 0.1 um Transistors 200 M Logic
gates 40 M Size 520 mm2 Clock 2 - 3.5 GHz Chip
I/Os 4,000 Wiring levels 7 - 8 Voltage 0.9 -
1.2 Power 160 Watts Supply current 160 Amps
Performance Power consumption Noise
immunity Area Cost Time-to-market Tradeoffs!!!
5VLSI Design Cycle
- VLSI design process is carried out at a number of
levels.
- System Specification
- Functional Design
- Logic Design
- Circuit Design
- Physical Design
- Design Verification
- Fabrication
- Packaging Testing and Debugging
6Physical Design
The physical design cycle consists of
- Partitioning
- Floorplanning and Placement
- Routing
- Compaction
Physical Design converts a circuit description
into a geometric description. This description is
used to manufacture a chip.
7Why we need Partitioning ?
- Decomposition of a complex system into smaller
subsystems. - Each subsystem can be designed independently
speeding up the design process (divide-and
conquer-approach). - Decompose a complex IC into a number of
functional blocks, each of them designed by one
or a team of engineers. - Decomposition scheme has to minimize the
interconnections between subsystems.
8Levels of Partitioning
System
System Level Partitioning
PCBs
Board Level Partitioning
Chips
Chip Level Partitioning
Subcircuits / Blocks
9Motivation
- Need for Power optimization
- Portable devices.
- Power consumption is a hindrance in further
integration. - Increasing clock frequency.
- Need for delay optimization
- In current sub micron design wire delay tend to
dominate gate delay. Larger die size imply long
on-chip global routes, which affect performance. - Optimizing delay due to off-chip capacitance.
10Objective
- Design a class of iterative algorithms for VLSI
multi objective partitioning. - Explore partitioning from a wider angle and
consider circuit delay , power dissipation and
interconnect in the same time, under balance
constraint.
11Problem formulation
- Objectives
- Power cost is optimized AND
- Delay cost is optimized AND
- Cutset cost is optimized
- Constraint
- Balanced partitions to a certain tolerance
degree. (10)
12Cutset
- Based on hypergraph model H (V, E)
- Cost 1 c(e) 1 if e spans more than 1 block
- Cutset sum of hyperedge costs
- Efficient gain computation and update
13Delay Model
- path ? SE1 ? C1?C4?C5?SE2.
- Delay? CDSE1 CDC1 CDC4 CDC5 CDSE2
- CDC1 BDC1 LFC1 ( Coffchip CINPC2 CINPC3
CINPC4)
14Delay
Delay(Pi)
Delay(Pi)
Pi is any path Between 2 cells or nodes P
set of all paths of the circuit.
15Power
The average dynamic power consumed by CMOS logic
gate in a synchronous circuit is given by
Ni is the number of output gate transition per
cycle( switching Probability)
Is the Load Capacitance
16Power
Load Capacitances driven by a cell before
Partitioning
additional Load due to off chip capacitance.(
cut net)
Total Power dissipation of a Circuit
17Power
Can be assumed identical for all nets
Set of Visible gates Driving a load outside the
partition.
18Balance
The Balance as constraint is expressed as
follows
However balance as a constraint is not appealing
because it may prohibits lots of good moves.
Objective Cells(block1) Cells( block2)
19Fuzzy logic for cost function
- Imprecise values of the objectives
- best represented by linguistic terms that are
basis of fuzzy algebra - Conflicting objectives
- Operators for aggregating function
20Use of fuzzy logic for Multi-objective cost
function
- The cost to membership mapping.
- Linguistic fuzzy rule for combining the
membership values in an aggregating function. - Translation of the linguistic rule in form of
appropriate fuzzy operators.
21Some fuzzy operators
- And-like operators
- Min operator ? min (?1, ?2)
- And-like OWA
- ? ? min (?1, ?2) ½ (1- ?) (?1 ?2)
- Or-like operators
- Max operator ? max (?1, ?2)
- Or-like OWA
- ? ? max (?1, ?2) ½ (1- ?) (?1 ?2)
- Where ? is a constant in range 0,1
22Membership functions
Where Oi and Ci are lower bound and actual cost
of objective i ? i(x) is the membership of
solution x in set good i gi is the relative
acceptance limit for each objective.
23Fuzzy linguistic rule
- A good partitioning can be described by the
following fuzzy rule - IF solution has
- small cutset AND
- low power AND
- short delay AND
- good Balance.
- THEN it is a good solution
24Fuzzy cost function
The above rule is translated to AND-like OWA
Represent the total Fuzzy fitness of the
solution, our aim is to Maximize this fitness.
Respectively (Cutset, Power, Delay , Balance )
Fitness.
25GA for multiobjective Partitioning
Algorithm (Genetic_Algorithm) Construct_Population
(Np) For j 1 to Np Evaluate_Fitness
(Populationj) End For For i 1 to Ng
For j 1 to No (x,y) ?
Choose_parents offspringj ? Crossover(x,y)
EndFor Population ? Select ( Population,
offspring, Np ) For k 1 to Np Apply
Mutation (Populationk) EndFor EndFor
26Solution representation
27GA implementation
- Different population sizes
- Parent selection Roulette wheel
- The probability of selecting a chromosome for
crossover is - Np is the population size
28GA implementation
- Simple single point
- crossover
- Selection before mutation
- Roulette wheel (rlt)
- Elitism random (ernd)
29Tabu Search
- Algorithm Tabu_Search
- Â Start with an initial feasible solution S ? ?
- Initialize tabu list and aspiration level
- For fixed number of iterations Do
- Generate neighbor solutions V ? N(S)
- Find best S ? V
- If move S to S is not in T Then
- Accept move and update best solution
- Update T and AL
- Else If Cost(S) lt AL Then
- Accept move and update best solution
- Update T and AL
- End If
- End For
30TS implementation
- Neighbor solution
- Change the block of a randomly selected cells.
- The Tabu list size depends on the circuit size.
31TS implementation
- Tabu list
- Store index of one of the swapped cell.
- Various sizes for tabu list.
- Aspiration Level
- The best neighbor is better than the global best.
32Experimental Results
ISCAS 85-89 Benchmark Circuits
33GA Vs Tabu Multi-objective
34Circuit S13207 GA
35Circuit S13207 TS
36Circuit S13207 GA Vs TS time
37Conclusion
- The present work successfully addressed the
important issue of reducing power and delay
consumption in VLSI circuits. - The present work successfully formulate and
provide solutions to the problem of
multiobjective VLSI partitioning - TS partitioning algorithm outperformed GA in
terms of quality of solution and execution time
38 Thank you.