ADC Front-End Design Considerations for Telecommunication Satellite Applications - PowerPoint PPT Presentation

About This Presentation
Title:

ADC Front-End Design Considerations for Telecommunication Satellite Applications

Description:

ADC Front-End Design Considerations for Telecommunication Satellite Applications presented by Dr. Rajan Bedi rajan.bedi_at_astrium.eads.net UK EXPORT CONTROL TECHNOLOGY ... – PowerPoint PPT presentation

Number of Views:72
Avg rating:3.0/5.0
Slides: 29
Provided by: microelect5
Category:

less

Transcript and Presenter's Notes

Title: ADC Front-End Design Considerations for Telecommunication Satellite Applications


1
  • ADC Front-End Design Considerations for
    Telecommunication Satellite Applications
  • presented by
  • Dr. Rajan Bedi
  • rajan.bedi_at_astrium.eads.net
  • UK EXPORT CONTROL TECHNOLOGY RATING
  • 3A001.a.1.a, 3A001.a.2.a, 3C001.a, 3C001.b,
    3E001, 4E001.a, 4A003.a, 5E001.b.1
  • Rated By P. Cornfield with reference to UK
    Export Control Lists (version INTR_B05.doc 30
    July
  • 2006) which contains the following caveat The
    control texts reproduced in this guide are for
  • information purposes only and have no force in
    law. Please note that where legal advice is
  • required, exporters should make their own
    arrangements.
  • Export licence Not required for EU countries.
    Community General Export authorisation EU001
  • is valid for export to Australia, Canada,
    Japan, New Zealand, Norway, Switzerland USA.

2
Agenda
  • Introduction
  • Balun and ADC Modelling
  • Simulation Results
  • Conclusion Future Work

3
Differential ADCs
  • Digital wideband telecommunication payloads use
    high-frequency differential ADCs.
  • System noise accumulates in signals as they
    travel across a PCB or through long cables.
  • Differential signals are highly immune to system
    noise due to the common-mode rejection of a
    differential ADC.
  • System noise such as that induced from switching
    supplies, ground currents and EMI are reduced due
    to the common-mode rejection of a differential
    ADC.
  • Differential signals cancel even-order harmonics
    providing better distortion performance than
    single-ended signals.
  • A differential input doubles the ADCs useful
    dynamic range.

4
Single-Ended to Differential Conversion
  • Prior to digitization, we need to convert the
    single-ended, down-converted baseband output to a
    differential signal.
  • The conversion from single-ended to differential,
    transmission line effects and package parasitics,
    adversely affect the integrity of the analogue
    input to the ADC.
  • These combined effects impact the maximum dynamic
    performance that can be achieved from the ADC.

5
Single-Ended to Differential Conversion
  • There are a number of conversion options
  • Single-ended to differential amplifier
  • RF Transformer
  • There were no wideband space-grade differential
    amplifiers that had the required bandwidth and
    dynamic range.

6
Balun Transformer
  • A balun transformer is to be used to convert the
    single-ended, down-converted baseband output to a
    differential signal.
  • The balun also provides the necessary impedance
    matching between the single-ended input and the
    differential input resistance of the ADC.
  • A centre-tapped secondary winding provides the
    freedom to set the common-mode level arbitrarily.
  • The voltage gain provided by a step-up balun
    transformer introduces no non-linear,
    amplification noise.

7
Simplified Ideal Balun Specification
The balun converts the 50 ohm single-ended
baseband input into a differential signal driving
the100 ohm differential ADC input
resistance. Impedance Ratio Z Secondary
Impedance / Primary Impedance 2 Turns Ratio N
Secondary Turns / Primary Turns vZ v2 1.414
8
Balun Imperfections
  • Balun transformers are not perfect.
  • Intrinsic parasitics affect the amplitude and
    phase balance of the differential output which
    could potentially result in increased even-order
    distortion in the ADC output spectrum.
  • Baluns have a finite bandwidth and not always a
    flat amplitude response over the frequency range
    of interest.
  • Baluns introduce an in-circuit insertion loss as
    well as a return loss.

9
Balun Imperfections
  • Winding Resistance both the primary and
    secondary windings have resistance (copper loss)
    which reduces the expected load voltage.
  • Magnetic Flux Leakage both the primary and
    secondary windings have leakage inductance caused
    by incomplete mutual coupling between the
    windings.
  • Intra-Winding Capacitance there is always some
    stray capacitance between adjacent turns of each
    winding effective capacitance in parallel with
    each winding of the balun.

10
Balun Imperfections
  • Inter-Winding Capacitance - there is stray
    capacitance between windings.
  • Core Losses
  • Eddy current loss which increases with frequency
  • Hystersis loss which increases with flux density
  • Magnetising inductance core loss
  • Low-frequency behaviour of a balun transformer is
    influenced by the inductance of the primary
    winding.
  • High-frequency behaviour of a balun transformer
    is influenced by the windings capacitances and
    series inductances.

11
Model of a Lossy Non-Ideal Balun
  • Primary and secondary leakage inductance IL
    and -RL at high freqs.
  • Primary and secondary resistive winding loss
    IL at high freqs.
  • Interwinding and Intrawinding capacitances IL
    at high freqs.
  • Core losses IL and -RL at low freqs.

12
Simulation Environment
  • A simulation environment has been developed to
    model the analogue front end which includes
  • A VHDL-AMS behavioural model of a differential
    ADC which accounts for offset and gain error, DNL
    and INL.
  • A SPICE model of a lossy balun transformer model
    which includes real balun parasitics.
  • Transmission line interconnect effects between
    these components.

13
Simulation Environment
  • The simulation environment is allowing us to
    investigate how the balun parasitics affect the
    output from the ADC.
  • Sinusoidal and NPR analysis within this
    simulation environment.

14
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • Single tone testing, Fin 47.5 MHz at 1 dBFS
  • SFDR 52.5 dBc, SINAD 43.2 dB, SNR 43.9 dB
    ENOB 7 bits

15
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
There is only 2.5 dB variation in SFDR as a
function of phase imbalance due to a slight
increase in H2.
16
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • SINAD decreases by 2.5 dB as a function of phase
    imbalance

17
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • SNR decreases by 2.5 dB as a function of phase
    imbalance

18
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • ENOB decreases by 0.41 bits as a function of
    phase imbalance

19
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
There is 3.7 dB variation in SFDR as a function
of amplitude imbalance.
20
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
Negligible variation in SINAD as a function of
amplitude imbalance.
21
ADC Simulation Results8-bit ADC model DNL
0.5 lsb, INL 1 lsb
Minor variation in SNR as a function of amplitude
imbalance.
22
ADC Simulation Results10-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • Single tone testing, Fin 45.625 MHz at 1
    dBFS
  • SFDR 67.3 dBc, SINAD 54.9 dB, SNR 55.5 dB
    ENOB 8.92 bits

23
ADC Simulation Results10-bit ADC model DNL
0.5 lsb, INL 1 lsb
There is only 1.7 dB variation in SFDR as a
function of phase imbalance, not due to H2.
24
ADC Simulation Results10-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • SINAD decreases by only 0.8 dB as a function of
    phase imbalance

25
ADC Simulation Results10-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • SNR decreases by only 1.2 dB as a function of
    phase imbalance

26
ADC Simulation Results10-bit ADC model DNL
0.5 lsb, INL 1 lsb
  • ENOB decreases by only 0.19 bits as a function
    of phase imbalance

27
Conclusion
  • A simulation environment has been developed that
    allows the analogue front-end of a digital
    payload to be modelled.
  • Simulation results suggest that actual device
    amplitude and phase imbalances from standard
    product COTS baluns have limited impact on the
    dynamic performance of an ADC.
  • Parameters such as 3dB bandwidth and flatness
    over the frequency range of interest maybe more
    important from a Systems/Payload perspective.

28
Future Work
  • We are about to characterise a selection of COTS
    baluns using a VNA to measure the amplitude and
    phase imbalance ..
  • These will then be used to convert a single-ended
    signal to a differential ADC input to correlate
    the measured data from actual hardware with
    simulation results.
Write a Comment
User Comments (0)
About PowerShow.com