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7 October 2008 1
CAD Algorithms
Physical Design Automation
of VLSI Systems
Mohammad Tehranipoor
ECE Department
7 October 2008 2
Physical Design Automation
� Objectives:
� Obtain general understanding about IC design process
� Study design automation
� Study algorithms
� Used in designing the layout of a chip
� Prepare students for exposure to hard CAD problems
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7 October 2008 3
VLSI Design Cycle
� Large number of components:� The physical design is not practical without the help of computers.
� Optimize requirements for higher performance� Performance relates to speed, power and size.
� Time to market competition:� Makes the use of computer necessary
� Cost:� Using computer makes it cheaper by reducing time-to-market.
System
Specifications Chip
Manual
Automation
7 October 2008 4
VSLI Design Cycle (Cont.)
� VLSI design cycle can be divided into the following steps:
� System Specification:
� Goals and constraints of the system
� Functionality (what will a system do)
� Performance figures like speed and power
� Technology constraints like size and space (physical dimensions)
� Fabrication technology and design techniques
� Architectural/Functional Design:
� RISC, CISC, # of ALUs, floating point units, number and structure of
pipelines, etc.
� Functional behavior and functional units to match specification
� Functional subunits and relationship among them
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7 October 2008 5
VSLI Design Cycle (Cont.)� Logic Design:
� Implementation of functional subunits using logic representation
� Boolean expressions, finite state machines or schematics.
� Use of standard building blocks like RAM, ROM, PLA, etc.
� Logic design should match functional description.
� Register Transfer Level (RTL) description of subunits.
� RTL is expressed in VHDL or Verilog.
� Circuit Design
� Logic networks or descriptions are converted into electronic circuits.
� Circuit elements are designed to meet specifications.
� Transistors are sized for current capacity and delay requirements.
� Circuit simulation is used to verify the correctness and timing of each
component.
7 October 2008 6
VSLI Design Cycle (Cont.)
� Physical Design: That’s the focus of our course.
� The circuit representation is converted into a geometric representation.
� Geometric representation of a circuit is called layout.
� The exact details of the layout depends on design rules.
� Design rules are guidelines based on the limitations of the fabrication
process.
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7 October 2008 7
VSLI Design Cycle (Cont.)
CAD Tools:
� Layout synthesis tools are fast but do have area and performance penalties.
� Manual layout is very slow but does have better area and performance.
� Most of the layout of a high performance custom design may be done
using manual design.
� Synopsys, Cadence, Mentor Graphics, Magma, and more
� Note that the objective of VLSI CAD tools are to minimize
the time for each iteration and the total number of iterations,
thus reducing time-to-market.
7 October 2008 8
VSLI Design Cycle (Cont.)
� Fabrication:
� After layout and verification, the design is ready for
fabrication (called tapeout).
� Layout data is converted into photo-lithographic
masks.
� Testing and Debugging:
� After fabrication, each die is tested.
� The wafer is diced into individual chips.
� Each chip is packaged and tested.
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7 October 2008 9
VLSI Design Cycle
System Specifications
Functional Design
Logic Design
Circuit Design
X=(AB*CD)+ …
7 October 2008 10
VLSI Design Cycle
Physical Design
Fabrication
Packaging
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7 October 2008 11
New Trends in VLSI Design Cycles
� Increasing Interconnect Delay:
� Interconnect is not scaling at the same rate as the devices.
� Almost 60% of path delay may be due to interconnect.
� Increasing Interconnect Area:
� Almost 30-40% of the area is covered by interconnects in modern designs.R
ela
tive D
ela
y
Technology Node (nm) ITRS2005
Interconnect vs. Gate Delay
7 October 2008 12
New Trends in VLSI Design Cycles
� Increasing number of Metal Layers:
� To meet the increasing need of interconnect, number of metals is increasing.
� Up to 12 metal layer in the next few years
Many Metal Layers� In nanometer technology designs:
� More silicon area consumed by wires –Miles of Cu wires
� Increasing wire lengths and interconnect defects, i.e. more bridging faults
� Increasing number of vias – Metal layers
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7 October 2008 13
New Trends in VLSI Design Cycles
� Increasing Planning Requirements:
� Physical design considerations have to enter into design at much earlier
phase.
� Synthesis:
� The design time can be reduced if layout can be directly generated from a
higher level description.
� Behavioral Model � Physical Layout
� New tools can support it.
7 October 2008 14
Physical Design Process
� Physical Design converts circuit description into a geometric
description.
� This description is used to manufacture a chip.
� The input to a physical design cycle is a circuit diagram/netlist
and the output is the layout of the circuit.
� Required Stages:
� Partitioning
� Floorplanning
� Placement
� Routing
� Compaction
� Extraction and Verification (post-layout verification)
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7 October 2008 15
New Trends in Physical Design Process
� Chip Level Signal Planning
� Routing of major signals and buses must be planned from early design
stages, so that the interconnect distances can be minimized.
� Interconnects length directly impact circuit delay and layout area
� OTC Routing
� Over-the-cell (OTC) routing allows routing over blocks and active
areas.
� Reduces the layout area
7 October 2008 16
Major Challenges
� Crosstalk
CcCs
Cs
Cc
0.35 µm 90 nm
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7 October 2008 17
Cont.
� Power Supply Noise and Temperature
7 October 2008 18
Cont.
� Power Supply Noise
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7 October 2008 19
Cont.
� Temperature
7 October 2008 20
Steps of Iterative Design Process
� Synthesis:
� Synthesis derives or improves a representation at any step.
� Behavioral synthesis, logic synthesis and layout synthesis are all
examples at various steps.
� Analysis:
� Analysis ensures that the design representation matches the requirements
at various steps.
� Requirements like area, power dissipation and speed.
� Verification:
� Establishes the correctness of design at any given step.
� Simulation at any step should match specifications.
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7 October 2008 21
Design Process is Iterative
Behavioral
Structural
Synthesis
PNR
Simulation-Based Verification
Simulation-Based Verification
Simulation-Based Verification
Simulation/Emulation-Based
Verification
7 October 2008 22
Design Styles
Preferred style for mass production, Highly optimized layout, Time can be justified
JC
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7 October 2008 23
Selection of Design Style
� Selection of design styles depends on many factors:
� Type of chip
� High performance, Area, …
� Volume
� Mass production, Medium production volume, …
� Cost
� Company’s budget, Cost of the chip
� Time-to-market
� Last two are dominant.
7 October 2008 24
Full Custom Design Style
� Circuit partitioned into sub-blocks.
� Blocks can be of any size/shape
� Hierarchical design
� Placement on any location is allowed
� Allows very compact designs
� Difficult automation
� High performance
� The process of automating a full-
custom design style has a much higher
complexity than other restricted styles.
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7 October 2008 25
Standard Cell Design Style
� Design process is somewhat simpler than full-custom design style
� Rectangular cells of same height
� Library based design
� Cells arranged in rows
� Easier automation
� Inherently nonhierarchical
� Lower performance
� Well suited for moderate size designs and medium production volume.
� Logic synthesis uses standard cell design style.
7 October 2008 26
Standard Cell
� Channel is the space between two rows.
� Feedthrough is the empty cells in a row.
� Feedthroughs are assigned for the interconnections of non-adjacent
cells.
� Standard cell design style takes more area than full custom.
� Along with semiconductor manufacturing advances, standard cell
methodology was responsible for allowing designers to scale ASICs
from comparatively simple single-function ICs (of several thousand
gates), to complex multi-million gate devices (SoC).
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7 October 2008 27
Standard Cell
� 2-input NAND or NOR function is sufficient to form any arbitrary
Boolean function set
� In modern ASIC design, standard cell methodology is practiced with a
sizeable library of cells
� The library contains multiple implementations of the same logic function,
differing in area and speed
� This variety enhances the efficiency of automated synthesis, place and
route tools
� It gives the designer greater freedom to perform implementation tradeoffs
� Area vs Speed vs Power Consumption
� A complete group of standard cell descriptions is commonly called a
technology library.
� The technology library is developed and distributed by the foundry
operator.
7 October 2008 28
Gate Array Design Style
� A simplification of Standard Cell Design Style
� Gate array design is a manufacturing method in which the diffused layers, i.e.
transistors and other active devices, are predefined and wafers containing such
devices are held in stock prior to metallization, in other words, unconnected
� A regular lattice shaped structure
� Pre-fabricated logic
� Both vertical and Horizontal channels
� Only wiring masks need to be defined
� Rapid fabrication
� Low performance
� Easy automation
� Non-hierarchical structure
� Logic synthesis can use gate array.
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7 October 2008 29
Gate Array
� Photo-lithographic masks are required only for the metal layers� Production cycles are much shorter as metallization is a comparatively
quick process
� Advantages/Disadvantages:
� The steps involved for creating any prefabricated wafer are the same
� Only the last few steps in the fabrication process will be used.
� Cheaper and easier to produce than full-custom and standard cell.
� It offers more area and less time.
� Difficulties in routing the interconnect require migration onto a larger array device with consequent increase in the price
� Pure, logic-only gate array design is rarely implemented by circuit designers today
� FPGA is preferred.
7 October 2008 30
Gate Array
� Today gate arrays are evolving into
Structured ASICs
� Structured ASICs consist of a large IP
core like a CPU, DSP unit, peripherals,
standard interfaces, integrated memories
SRAM, and a block of reconfigurable
uncommited logic.
� This shift is largely because ASIC
devices are capable of integrating large
blocks of system functionality and
"system on a chip" requires far more
than just logic blocks.
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7 October 2008 31
FPGA Design Style
� Extremely rapid prototyping
� Re-programmable
� Lowest performance
� Easy automation
� Cells and interconnects are pre-fabricated.
� The user simply programs the interconnects.
� Contains programmable logic blocks and interconnects� Logic blocks can be programmed to
perform the function of basic logic gatessuch as AND, and XOR, or more complex combinational functions such as decoders or mathematical functions.
� FPGAs contain FFs
7 October 2008 32
LUT Programming
Source: Fundamentals of Digital Logic , McGraw Hill 2000
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7 October 2008 33
LUT Programming
3-input LUT
7 October 2008 34
LUT Programming Sequential
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7 October 2008 35
Comparison of Design Styles
Mass
Production
Volume
Medium
Production
Volume
Medium
Production
Volume
Low
Production
Volume
Production
Volume:
Complexity: High Low
7 October 2008 36
Physical Design Automation
� Physical design implies “physical realization” of
integrated circuit layout.
� Input to physical design cycle is a circuit design
� Circuit netlist (gate level representation)
� RTL description of the circuit
� Output from this stage is a layout of the circuit
� The task from input to output is accomplished in several design stages,
each addressing specific goals.
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7 October 2008 37
Physical Design Cycle
7 October 2008 38
Physical Design Cycle
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7 October 2008 39
Physical Design Cycle
7 October 2008 40
VLSI Design Automation
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