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Friday, 5 July 2013

VLSI

VLSI Design

Module Aims

         Introduction to VLSI Technology
        Process Design
         Trends
         Chip Fabrication
         Real Circuit Parameters
        Circuit Design
         Electrical Characteristics
         Configuration Building Blocks
         Switching Circuitry
         Translation onto Silicon
         CAD
        Practical Experience in Layout Design
Learning Outcomes

         Understand the principles of the design and implementation of standard MOS integrated circuits and be able to assess their performance taking into account the effects of real circuit parameters

Laboratory
         Micro wind layout and simulation package
         Dedicated to training in sub-micron CMOS VLSI design
         Layout editor, electrical circuit extractor and on-line analogue simulator
             Reading List
Why VLSI?
         Integration improves the design
        Lower parasitic = higher speed
        Lower power consumption
        Physically smaller
         Integration reduces manufacturing cost - (almost) no manual assembly
Module 1
Introduction to VLSI Technology
         Introduction
         Typical Applications
         Moore’s Law
         The cost of fabrication
         Technology Background
         What is a chip
         Switches
         Doping
         IC Technology
         Basic MOS Transistor
         Fabrication Technology
         CMOS Technology
         BiCMOS

VLSI Applications
         VLSI is an implementation technology for electronic circuitry - analogue or digital
         It is concerned with forming a pattern of interconnected switches and gates on the surface of a crystal of semiconductor
         Microprocessors
        personal computers
        microcontrollers
         Memory - DRAM / SRAM
         Special Purpose Processors - ASICS (CD players, DSP applications)
         Optical Switches
         Has made highly sophisticated control systems mass-producible and therefore cheap

Moore’s Law
         Gordon Moore: co-founder of Intel
         Predicted that the number of transistors per chip would grow exponentially (double every 18 months)
         Exponential improvement in technology is a natural trend:
        e.g. Steam Engines - Dynamo - Automobile

The Cost of Fabrication
         Current cost $2 - 3 billion
         Typical fab line occupies 1 city block, employees a few hundred employees
         Most profitable period is first 18 months to 2 years
         For large volume IC’s packaging and testing is largest cost
         For low volume IC’s, design costs may swamp manufacturing costs
Technology Background
What is a Silicon Chip?
         A pattern of interconnected switches and gates on the surface of a crystal of semiconductor (typically Si)
         These switches and gates are made of
        areas of n-type silicon
        areas of p-type silicon
        areas of insulator
        lines of conductor (interconnects) joining areas together
         Aluminium, Copper, Titanium, Molybdenum, polysilicon, tungsten
          The geometry of these areas is known as the layout of the chip
         Connections from the chip to the outside world are made around the edge of the chip to facilitate connections to other devices
Switches
         Digital equipment is largely composed of switches
         Switches can be built from many technologies
        relays (from which the earliest computers were built)
        thermionic valves
        transistors
         The perfect digital switch would have the following:
        switch instantly
        use no power
        have an infinite resistance when off and zero resistance when on
         Real switches are not like this!
Semiconductors and Doping
         Adding trace amounts of certain materials to semiconductors alters the crystal structure and can change their electrical properties
        in particular it can change the number of free electrons or holes
         N-Type
        semiconductor has free electrons
        dopant is (typically) phosphorus, arsenic, antimony
         P-Type
        semiconductor has free holes
        dopant is (typically) boron, indium, gallium
Dopants are usually implanted into the semiconductor using Implant Technology, followed by thermal process to diffuse the dopants
IC Technology
         Speed / Power performance of available technologies
         The microelectronics evolution
         SIA Roadmap
         Semiconductor Manufacturers 2001 Ranking
Metal-oxide-semiconductor (MOS) and related VLSI technology
         nMOS
         pMOS
         CMOS
         BiCMOS
         GaAs
Basic MOS Transistors
         Minimum line width
         Transistor cross section
         Charge inversion channel
         Source connected to substrate
         Enhancement vs. Depletion mode devices
         pMOS are 2.5 time slower than nMOS due to electron and hole nobilities
Fabrication Technology
         Silicon of extremely high purity
        chemically purified then grown into large crystals
         Wafers
        crystals are sliced into wafers
        wafer diameter is currently 150mm, 200mm, 300mm
        wafer thickness <1mm
        surface is polished to optical smoothness
         Wafer is then ready for processing
         Each wafer will yield many chips
        chip die size varies from about 5mmx5mm to 15mmx15mm
        A whole wafer is processed at a time
         Different parts of each die will be made P-type or N-type (small amount of other atoms intentionally introduced - doping -implant)
         Interconnections are made with metal
         Insulation used is typically SiO2. SiN is also used. New materials being investigated (low-k dielectrics)
         nMOS Fabrication
         CMOS Fabrication
        p-well process
        n-well process
         All the devices on the wafer are made at the same time
         After the circuitry has been placed on the chip
        the chip is over glassed (with a passivation layer) to protect it
        only those areas which connect to the outside world will be left uncovered (the pads)
         The wafer finally passes to a test station
        test probes send test signal patterns to the chip and monitor the output of the chip
         The yield of a process is the percentage of die which pass this testing
         The wafer is then scribed and separated up into the individual chips. These are then packaged
         Chips are ‘binned’ according to their performance
CMOS Technology
         First proposed in the 1960s. Was not seriously considered until the severe limitations in power density and dissipation occurred in NMOS circuits
         Now the dominant technology in IC manufacturing
         Employs both pMOS and nMOS transistors to form logic elements
         The advantage of CMOS is that its logic elements draw significant current only during the transition from one state to another and very little current between transitions - hence power is conserved.
         In the case of an inverter, in either logic state one of the transistors is off. Since the transistors are in series, (~ no) current flows.
         See twin-well cross sections
BiCMOS
         A known deficiency of MOS technology is its limited load driving capabilities (due to limited current sourcing and sinking abilities of pMOS and nMOS transistors.
         Bipolar transistors have
        higher gain
        better noise characteristics
        better high frequency characteristics
          BiCMOS gates can be an efficient way of speeding up VLSI circuits
         See table for comparison between CMOS and BiCMOS
         CMOS fabrication process can be extended for BiCMOS
         Example Applications
        CMOS - Logic
        BiCMOS         - I/O and driver circuits
        ECL    - critical high speed parts of the system
Conclusion

         Design for yield is design for low cost and quality
         Traditional techniques are not sufficient
         Multiple aspects

         redundancy

         defect robustness

         variation robustness
         DfY doesn't come for free

         timing issues

         wiring congestion increase

         noise issues
There is a lot to be gained but also a lot to do!