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Analog Multi-Tone Signaling for High-Speed Backplane Electrical Links

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Analog Multi-Tone Signaling for High-Speed Backplane Electrical Links ... Cannot afford high-resolution ADC. 20G, 8bit ADC ~ 450mW/GHz (ISSCC-03) ... – PowerPoint PPT presentation

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Title: Analog Multi-Tone Signaling for High-Speed Backplane Electrical Links


1
Analog Multi-Tone Signaling for High-Speed
Backplane Electrical Links
  • Amirkhany1, A. Abbasfar2, V. Stojanovic3, and M.
    Horowitz1,2
  • 1Stanford University
  • 2Rambus Inc
  • 3Massachusetts Institute of Technology

2
High-Speed Link
  • Multi Gb/sec chip-to-chip communication over PCB
    traces.
  • Routers, XAUI, PCI express

Channel
3
State of the Art Links
  • 2.5-12.5Gb/Sec, 20-40mW/Gbps
  • Baseband 2PAM or 4PAM
  • 4-5 tap discrete linear transmit equalizer
  • 5-20 tap (predictive or partial response) DFE
  • Designed for BER of 10-15
  • No error detection/correction coding

4
Potential of Multi-Tone
S21 (dB)
  • Better power allocation over channels with a
    notch
  • Parallelized data stream in frequency leading to
    implementation advantages

f (GHz)
5
Design Considerations
  • Power efficiency is the main constraint
  • Cannot afford high-resolution ADC
  • 20G, 8bit ADC 450mW/GHz (ISSCC-03)!
  • Limits signal processing
  • 1GSample/Sec, 128-point FFT 175mW/GHz
    (JSSC-05)!
  • Rules out DMT techniques
  • A customized MT architecture is required
  • Few sub-channels can create close to optimum
    transmit spectrum

6
Analog Multi-Tone (AMT)
  • A bank of parallel links on different carrier
    frequencies
  • Sub-channels not independent
  • Inter-channel interference (ICI) exists

7
Practical Architecture
  • N-times over-sampled equalizers per sub-channel
  • Receive filters are integrators
  • MIMO DFE in the receiver
  • Power Number of taps x operating rate
  • Tx/DFE power equal to a BB Tx/DFE covering same BW

8
Analysis Framework (Convex - SOCP)
  • Find Tx equalizer and Rx DFE taps that
  • Minimize transmit peak voltage (power)
  • Meet BER constraint per sub-channel
  • dmin Minimum distance at Rx (linear)
  • offsetk Receiver sampler dead-band (fixed)
  • snoise Sigma residual interf. and thermal
    (norm-2)

SOCP
9
ZFE with BER Constrained Power Allocation
  • Step 1 Independent sub-channel tap optimization
    (ZFE)
  • Minimize interference power from one transmitter
    to all receivers (find WTx,k and WFB,mk)
  • Independent of sub-channel transmitter power

10
ZFE with BER Constrained Power Allocation
  • Step 2 Joint power allocation (BER constrained)
  • Co-optimize g coefficients to meet BER constraint
    for all sub-channels
  • Model interference as peak distortion
  • BER constraint per sub-channel is linear in gk
  • SOCP reduces to an LP in vector g
  • A,B fixed since taps are fixed
  • Solution is g B-1b

11
Closed Form Jitter Modeling
Tx Jitter
Rx Jitter
Variance at kth Rx output
12
Performance on a Channel with Notch
13
Performance on a Smooth Channel

  • Comparable hardware complexity
  • AMT can achieve higher rates
  • Needs better Rx precision at lower rates
  • Possible since AMT samplers operate at half BB
    (4PAM) rate

14
Conclusion
  • High-speed links must be power efficient
  • DMT-type approaches not practical
  • The AMT architecture is power-efficient
  • Comparable complexity with BB
  • AMT has clear advantage over channels with a
    notch
  • Comparable performance over smooth channels
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