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Interconnect and Packaging Lecture 2: Scalability. Chung-Kuan Cheng UC San Diego. Outlines. Trends of Interconnect and Packaging Scalability References. I. Trends of High Performance Interconnect and Packaging. I. Trends of High Performance Interconnect and Packaging. I. Trends.
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Interconnect and PackagingLecture 2: Scalability Chung-Kuan Cheng UC San Diego
Outlines • Trends of Interconnect and Packaging • Scalability References
I. Trends • On-Chip Interconnect • Delay (5-40 times of Speed of Light 5ps/mm) • Power Density (> ½) • Clock Skew: Variations (5GHz) • Off-Chip Interconnect and Packaging • Number of pins (limited growth) • Wire density (scalability) • Speed and distance of interconnect
I. Trends • On-chip Global Interconnect trend • Concerns: Speed, Power, Cost, Reliability
I. Trend • Scalability • Latency, Bandwidth • Attenuation, Phase Velocity • Distortion • Intersymbol Interference, Jitter, Cross Talks • Clock Distribution • Skew, Jitter, Power Consumption • IO Interface • Density • Impedance Matching • Cross Talks, Return loops
II. Scalability: Interconnect Models • Voltage drops through serial resistance and inductance • Current reduces through shunt capacitance • Resistance increases due to skin effect • Shunt conductance is caused by loss tangent
II. Scalability: Interconnect Models • Telegrapher’s equation: • Propagation Constant: • Wave Propagation: • Characteristic Impedance
II. Scalability of Physical Dimensions b t w • R= ρ/A = ρ/(wt) • Z= ¼ (µ/ε)1/2 ln (b+w)/(t+w) • C= vZ • L= Z/v ρ: resistivity of the conductor µ: magnetic permeability ε: dielectric permittivity v: speed of light in the medium
II. Scalability of Physical Dimensions • Resistance: Increases quadratically with scaling, e.g. ρ=2µΩ-cm R=0.0002 Ω/µm at A=10µmx10µm R=0.02 Ω/µm at A=1µmx1µm R=2 Ω/µm at A=0.1µmx0.1µm • Characteristic Impedance: No change • Capacitance per unit length: No change • Inductance per unit length: No change
II. Scalability of Frequency Ranges • RC Region • LC Region • Skin Effect • Loss Tangent
II. Scalability of Frequency Ranges 1. RC Region e.g. on-chip wires R=2ohm/um (A=0.01um2) L=0.3pH/um, C=0.2fF/um R/L=6.7x1012
II. Scalability of Frequency Ranges: RC Region ltr l Elmore delay model with buffers inserted in intervals ltr: length from transmitter to receiver l: interval between buffers rn: nmos resistance cn: nmos gate capacitance cg=(1+g)cn, g is pn ratio. rw: wire resistance/unit length cw: wire capacitance/unit length f: cd/cg
II. Scalability of Frequency Ranges: RC Region Elmore delay model with buffers inserted in intervals Optimal interval Optimal buffer size Optimal delay
II. Scalability of Frequency Ranges Example: w= 85nm, t= 145nm rn= 10Kohm,cn=0.25fF,cg=2.34xcn=0.585fF rw=2ohm/um, cw=0.2fF/um Optimal interval Optimal buffer size Optimal delay
II. Scalability of Frequency Ranges: RC Region *no scattering, p=2.2uohm-cm
II. Scalability of Frequency Ranges: RC Region • Device delay, rncn, decreases with scaling • Wire delay, rwcw, increases with scaling • Interval, l, between buffers decreases with scaling • In order to increase the interval, we add the stages of each buffer.
II. Scalability of Frequency Ranges 2. LC Region
II. Scalability 3. Skin Effect Skin Depth:
II. Scalability 3. Skin Effect Skin Depth: e.g. 0.7um @ f=10GHz, ρ=2uΩ-cm For 100umx25um RDC=0.000008Ω/um= 8Ω/m R= 0.000114Ω/um=114Ω/m
II. Scalability 4. Loss Tangent
References • E. Lee, et al., “CMOS High-Speed I/Os – Present and Future,” ICCD 2003. • http://www.itrs.net/ • Ling Zhang, Low Power High Performance Interconnect Design and Optimization, Thesis, UCSD, 2008. • G.A. Sai-Halasz G.A. "Performance Trends in High-End Processors,“ IEEE Proceedings, pp. 20-36, Jan. 1995. • M.T. Bohr, “Interconnect scaling-the real limiter to high performance ULSI” Electron Devices Meeting, 1995., International10-13 Dec. 1995 pp.241 – 244.