Analog equalizers and SerDes receiver analog front end for 32 Gb/s wireline communication
Options for area-efficient and power-efficient equalization with maximum timing integrity become increasingly crucial for wireline receivers entering data rate more than 10 Gb/s. Different techniques for equalization at the receiver end have already been proposed in the past. Many of these soluti...
Saved in:
| Main Author: | |
|---|---|
| Other Authors: | |
| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2019
|
| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/78832 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Options for area-efficient and power-efficient equalization with maximum timing
integrity become increasingly crucial for wireline receivers entering data
rate more than 10 Gb/s. Different techniques for equalization at the receiver
end have already been proposed in the past. Many of these solutions, though
are highly suitable for data rate > 25 Gb/s, are not power- and area-efficient
to be used in compact wireline system-on-chip (SoC) owing to the use of bulky
inductors which are necessary to meet the desired bandwidth. The widely
used equalizers also tend to ignore the low frequency loss in the channel, while
addressing the traditional high frequency loss in the channel. However, over
long measurement intervals, the low frequency loss manifests as increased datadependent
jitter (DDJ) and worsens the timing integrity of the equalized signal.
In this thesis, three different power-efficient inductorless analog equalizer
designs that improve the timing integrity of the equalized signal are proposed.
The first design which operates at 13 Gb/s proposes an inductorless analog
equalizer design with low, intermediate and high frequency equalization. The
equalizer design uses conventional linear equalizer architecture together with
active feedback topology which extends the bandwidth for the inductorless
design. The proposed linear equalizer improves the jitter of a conventional
CTLE from 0.41 unit interval (UI) to 0.12 UI for a 231-1 input PRBS in the
presence of channel loss of 15 dB, with a power efficiency of 1.07 mW/Gb/s.
The first equalizer design implements dedicated circuit logic for low frequency
equalization and hence does not offer a power-efficient solution at data
rate higher than 25 Gb/s. To address this challenge, a second equalizer design
is proposed. The proposed equalizer design targets an inductorless and powerefficient
solution for a data rate of 32 Gb/s. The proposed analog equalizer
utilizes a triple-gate control which entails that a low frequency equalization is
simultaneously achieved at minimum area overhead. At a peaking of 21 dB at
Nyquist, the proposed design measures a peak-to-peak jitter of 0.17 UI at the
equalizer output for a 231-1 PRBS input pattern. Under a 1.2 V supply, the
power efficiency is measured as 0.53 mW/Gb/s.
The adaptation logic of the tuning controls in the second equalizer, especially
for the low frequency loss poses technical challenges in channel-aware
designs. This conduces that a linear equalizer as proposed in the second design
be combined with a nonlinear equalizer for better flexibility to adapt the
equalizer to minimize the timing jitter. This is especially significant when the
transmitted clock has to be recovered to retime the received data. Thus, the
third design proposes an inductorless 32 Gb/s wireline receiver analog front
end (AFE) with a linear equalizer and a novel half-rate distributed decision
feedback equalizing (DFE) scheme. The proposed distributed DFE scheme addresses
the problem of edge ISI, thus ensuring better timing jitter at the clock
edges. This in turn helps in accurate sampling of the data edges while maintaining
the vertical height at the centre of the sampled data. Measurement
results show that the proposed design has a power efficiency of 3.53 mW/Gb/s
at 1.2 V and exhibits a Bit Error Rate (BER) < 10-12 at a data rate of 32
Gb/s. |
|---|