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EE141 © Digital Integrated Circuits 2nd Wires 1 Digital Integrated Circuits A Design Perspective The Wire Jan M. Rabaey Anantha Chandrakasan Borivoje Nikolic July 30, 2002
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EE141 © Digital Integrated Circuits 2nd Wires 2 The Wire schematics physical
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EE141 © Digital Integrated Circuits 2nd Wires 3 Interconnect Impact on Chip
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EE141 © Digital Integrated Circuits 2nd Wires 4 Wire Models All-inclusive model Capacitance-only
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EE141 © Digital Integrated Circuits 2nd Wires 5 Impact of Interconnect Parasitics Interconnect parasitics reduce reliability affect performance and power consumption Classes of parasitics Capacitive Resistive Inductive
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EE141 © Digital Integrated Circuits 2nd Wires 6 Nature of Interconnect Global Interconnect S Local = S Technology S Global = S Die Source: Intel
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EE141 © Digital Integrated Circuits 2nd Wires 7 INTERCONNECT
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EE141 © Digital Integrated Circuits 2nd Wires 8 Capacitance of Wire Interconnect
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EE141 © Digital Integrated Circuits 2nd Wires 9 Capacitance: The Parallel Plate Model
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EE141 © Digital Integrated Circuits 2nd Wires 10 Permittivity
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EE141 © Digital Integrated Circuits 2nd Wires 11 Fringing Capacitance
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EE141 © Digital Integrated Circuits 2nd Wires 12 Fringing versus Parallel Plate
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EE141 © Digital Integrated Circuits 2nd Wires 13 Interwire Capacitance
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EE141 © Digital Integrated Circuits 2nd Wires 14 Interwire Capacitance (Process Data)
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EE141 © Digital Integrated Circuits 2nd Wires 15 DB and SB Capacitance
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EE141 © Digital Integrated Circuits 2nd Wires 16 Gate Capacitance
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EE141 © Digital Integrated Circuits 2nd Wires 17 INTERCONNECT
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EE141 © Digital Integrated Circuits 2nd Wires 18 Wire Resistance
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EE141 © Digital Integrated Circuits 2nd Wires 19 Interconnect Resistance
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EE141 © Digital Integrated Circuits 2nd Wires 20 Dealing with Resistance Selective Technology Scaling Use Better Interconnect Materials reduce average wire-length e.g. copper, silicides More Interconnect Layers reduce average wire-length
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EE141 © Digital Integrated Circuits 2nd Wires 21 Sheet Resistance
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EE141 © Digital Integrated Circuits 2nd Wires 22 Sheet Resistance (Process Data)
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EE141 © Digital Integrated Circuits 2nd Wires 23 Example: Intel 0.25 micron Process 5 metal layers Ti/Al - Cu/Ti/TiN Polysilicon dielectric
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EE141 © Digital Integrated Circuits 2nd Wires 24 InterconnectModeling
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EE141 © Digital Integrated Circuits 2nd Wires 25 The Lumped Model
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EE141 © Digital Integrated Circuits 2nd Wires 26 The Lumped RC-Model The Elmore Delay
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EE141 © Digital Integrated Circuits 2nd Wires 27 The Ellmore Delay RC Chain
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EE141 © Digital Integrated Circuits 2nd Wires 28 Wire Model Assume: Wire modeled by N equal-length segments For large values of N:
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EE141 © Digital Integrated Circuits 2nd Wires 29 The Distributed RC-line
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EE141 © Digital Integrated Circuits 2nd Wires 30 Step-response of RC wire as a function of time and space
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EE141 © Digital Integrated Circuits 2nd Wires 31 RC-Models
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EE141 © Digital Integrated Circuits 2nd Wires 32 Driving an RC-line
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EE141 © Digital Integrated Circuits 2nd Wires 33 Design Rules of Thumb rc delays should only be considered when t pRC >> t pgate of the driving gate Lcrit >> t pgate /0.38rc rc delays should only be considered when the rise (fall) time at the line input is smaller than RC, the rise (fall) time of the line t rise < RC when not met, the change in the signal is slower than the propagation delay of the wire © MJIrwin, PSU, 2000
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