1 / 28

Part 1

A/D Converters for SDR applications by : H. Mala M. Sajadieh A. Bakhtafrouz Isfahan University of Technology. Part 1. ADC systems for SDR applications By : Ahmad Bakhtafrouz. ADC Systems for SDR Digital Front-End. Performance Requirements. SNR and Sampling. Sigma-Delta ADCs.

valentinar
Download Presentation

Part 1

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. A/D Converters for SDRapplicationsby : H. MalaM. SajadiehA. BakhtafrouzIsfahan University of Technology

  2. Part 1 ADC systems for SDR applications By : Ahmad Bakhtafrouz

  3. ADC Systems for SDR Digital Front-End • Performance Requirements • SNR and Sampling • Sigma-Delta ADCs • Time-Interleaved ADC Systems • High-Resolution ADC toward SDR Receivers • Introduction • Configurations of Superconductor-Based SDR Receivers • Development of ADCs • Commercial Capture Cards

  4. ADC Systems for SDR Digital Front-End Performance Requirements :

  5. ADC Systems for SDR Digital Front-End • An ADC operates directly at RF stage of a wideband receiver will need to • have a bandwidth of up to 5 GHz with sampling rate of at least twice the • signal bandwidth , which means up to 40 M sample/sec in the case of the • 802.11x wireless LAN system. • Because of the frequency bandwidth encountered by a wideband receiver • of the SDR, it is expected that ADC with at least 14-bit resolution will be • needed to detect weak desired channel in presence of strong neighboring • channels. • Dynamic range and bandwidth of ADCs is still needs major improvement • Using parallel ADCs of lower specifications are of great interest with active • research being conducted.

  6. ADC Systems for SDR Digital Front-End SNR and Sampling : • SNR directly affects the Bit Error Rate (BER) of the communication channel. • Maximum theoretical SNR of an ADC due to quantization noise (Nyquist rate) : • SNR = 6.02n + 1.76 dB • Every additional bit will add 6 dB of improvement . • One attractive technique to improve the SNR is oversampling. • In the oversampling technique, the sampling frequency is purposely increased beyond the Nyquist rate to spread the noise power over a wider frequency band. • SNR = 6.02n + 1.76 + 10log(fs/2fb) dB • Every factor-of-4 increment in the sampling frequency , the SNR is improved by 6dB which is equivalent to one additional bit.

  7. ADC Systems for SDR Digital Front-End Sigma-Delta ADC : • The Sigma-Delta ADC, provides additional noise shaping characteristics that is • more effective in improving the SNR. • Due to its internal operation, Sigma-Delta ADC act as a LPF to the signal but a • HPF to the quantization noise . • The actual noise shaping performance of the Sigma-Delta ADC depends on the • order of the modulator used inside the ADC. • SNR improvement of an Lth order Sigma-Delta • ADCs due to oversampling : • SNR = 6.02n + 1.76 + (20L+10)log(fs/2fb) dB • A 1st order Sigma-Delta ADC will provide 18dB • improvement which is equivalent to an additional • 3-bit resolution .

  8. ADC Systems for SDR Digital Front-End Time-Interleaved ADC Systems : • One technique that can be used to obtain the benefit of over sampling without • using ADC with exception sampling rate is to parallel multiple ADCs. • It is shown that mismatch of Gain ,Offset and clock skew between the ADCs will • degrade the SFDR and linearity of the overall system . • the offset mismatch between the • ADCs causes spectrums to appear • at multiples of the ADC sampling • frequency , while the gain mismatch • and clock skew cause spurious • spectrum to appear around the • multiples of the ADC sampling • frequency.

  9. ADC Systems for SDR Digital Front-End

  10. High-Resolution ADC toward SDR Receivers Introduction : • There is an increasing interest in radio receiver systems based on superconducting • technologies . • Analog BPFs utilizing high-temperature super-conductors have sharp skirt • characteristic and low insertion loss . • Superconducting single-flux-quantum (SFQ) logic circuits can operate at several • tens of GHz and have higher integration level than other ultra high-speed • semiconductor circuits . • A simple 1st order sigma-delta ADC is still insufficient to the SDR applications in • its performances even if a high-speed SFQ circuit is used.

  11. High-Resolution ADC toward SDR Receivers Configurations of superconductor-Based SDR receivers : • Bandpass ADC • Bandwidth 100MHz • SNR 100dB(16 bit) • Current sensitivity 100nA • Bandpass ADC • Bandwidth 20MHz • SNR 85dB(14 bit) • Current sensitivity 100nA

  12. High-Resolution ADC toward SDR Receivers Configurations of superconductor-Based SDR receivers : • Lowpass ADC • Bandwidth 20MHz • SNR 75-85dB (12-14 bit) • Current sensitivity lower • Several kinds of the SFQ ADCs have current sensitivity less than 100nA . Thus an • SFQ-ADC is the most promising candidate for the SDR receivers. • Lowpass ADC for the digital-IF receiver is a base for the other superconductor-based • SDR receivers. • A simple lowpass ADC based on the SFQ circuits is difficult to have both the broad • bandwidth and the high SNR required for the digital-IF receiver. • Quantizer-sampler-separated (QSS) ADC overcome this problem.

  13. High-Resolution ADC toward SDR Receivers Development of ADCs : QSS ADC : • the quantizer junction outputs an SFQ pulse train whose voltage is identical to • the total voltage VL+VR . • VR is an offset voltage so that the ADC may handle negative values of VL. • The first derivative of the analog signal is converted to the pulse period of the • PDM signal at the quantizer, and the period is measured at the sampler. • The junction Jq and DFF serve as a quantizer and a sampler .

  14. High-Resolution ADC toward SDR Receivers Development of ADCs : QSS ADC : • The SNR and sensitivity of the QSS ADC are improved by the interleave technique • in which the increased number of DFFs (samplers) are used to measure the time • difference between the adjacent pulses in the PDM signal more precisely. • In addition, a bandpass ADC is easily obtained by replacing the integrator with • a resonator. • Numerical analysis shows that the QSS ADC has higher sensitivity than the • sigma-delta ADC.

  15. High-Resolution ADC toward SDR Receivers Development of ADCs : Complementary Delta ADC : • The QSS ADC have a strict operating condition that the DC offset should keep • a constant value and it is difficult in the actual opration. • The output of the left modulator is multiplied by -1 and then added to the output • of the right modulator. • The ADC becomes insensitive to the common-mode signals containing the dc offset • and the noise mixed with that. • With 2nd order decimation filter and 8 sets of samplers, the SNR reaches 82dB • (13 bits) for a frequency band of 0.1-20 MHz.

  16. High-Resolution ADC toward SDR Receivers Development of ADCs : Complementary Delta ADC : • 3 sinusoidal signals around 20 MHz to the port of the DC offset Complementary ADC QSS ADC

  17. High-Resolution ADC toward SDR Receivers Development of ADCs : • SNR can be improved by increasing the number of the samplers. • In this calculation, we assume that the oversampling frequency is 20GHz and the • band of interest is ranging from 0.1-20 MHz. • The SNR is increased by about 6dB in every twice of the number of the samplers.

  18. Commercial Capture Cards High-Frequency Internal ADCs

  19. Commercial Capture Cards Card NVL-45 Price: $750  • two independent ADC channels the sampling rate of which is up to 60 MHz (each channel) • , resolution of the channels is12 bit (each channel) • sampling rate doubling  in single-channel (ping-pong) mode • input voltage ranges: +/-1 V, +/-2 V (program switching) • onboard memory: 4 Mb • 8-channels analog signals multiplexers (on the input of every ADC) • digital I/O ports (8 input and 8 output lines)  • PC connection through PCI bus, high speed of data exchange with the bus, plug-and-play • "oscilloscope" program is included in a set • drivers for Windows95/98/ME/NT/2000/XP, Linux 2.216 - 22 Red Hat 7.0 (Guinness) and • samples of VC programming 

  20. Commercial Capture Cards Card AD-PCI 12 Price: $1190 • two independent ADC channels resolution of which is12 bit, sampling rate of the channels • is 100 MHz • bandwidth: 100 MHz • one DAC channel (8 bit) • sampling rate: 100 MHz • PCI bus transmission speed: 100 MHz • drivers for Windows 95/98/ME/NT/2000/XP • sample of programming ("oscilloscope" program) with initial text in DELPHI

  21. Commercial Capture Cards Analog/digital conversion card for PCI - n10M6PCI Price: $994 • sampling rate: upto100 MHz (single-channel mode) • mode of sampling rate task-setting - fixed frequency of a quartz generator • bandwidth: (-3dB)- 50 MHz • ADC resolution: 8 bit • speed of conversion: 20 ns • onboard memory • two single-ended inputs for analog signals • analog inputs and external trigger inputs can be either single-ended or differential  

  22. Commercial Capture Cards Low-Frequency Internal ADCs

  23. Commercial Capture Cards Сard NVL03 Price: $198 • ADC: resolution 10 bit, 16 channels • voltage ranges +/-5V; +/-2,5V; +/-1,25V; +/-1V • conversion time: 30 ms • 16 double-ended channels of digital input and output • 3 ways of starting the ADC • the list of functions and testing programs "oscilloscope" are included in a set.

  24. Commercial Capture Cards ADC card PC-1202 Price $589  • PCI bus • 12-bit 110KHz A/D converter • PC-1002H/-1002L, 32 single-ended/16 differential inputs • sampling rates of single channel or multiple • channels is 110 K samples/sec • three different external trigger: post-trigger, pre-trigger, middle trigger • 16 digital input /16 digital output channels • 1002L : programmable low gain:1, 2, 4, 8. • 1002H: programmable high gain:1, 10, 100, 1000. • internal /external triggering.

  25. Commercial Capture Cards ADC card PC-1602 Price: $1286 • PCI bus • 16-bit 200KHz A/D converter  • 32 single-ended or 16 differential inputs 8K word FIFO buffer • the sampling rates of single channel or multiple  channels is: 200 k samples/sec • three different external trigger: post-trigger, pre-trigger, middle trigger • 16 digital input /16 digital output channels • PCI-1602 provides programmable low gain: 0.5, 1, 2, 4, 8 • internal/external triggering • two12-bit independent programmable DAC • high-speed data transfer rate (2.7 M Words)

  26. Commercial Capture Cards Card ADC 1,5PCI-14 Price: $586 • ADC: resolution: 14 bit, conversion time: 2,5 ms • 32 single-ended channels or 16 differential channels • input resistance is more than 100 М Ohm • switchable input voltage ranges of the ADC: ± 10V, ± 5V, ± 2,5V, ± 1V, ± 0,5V, ± 0,25V, ± • 0,1V, ± 0,05V (for each channel) • buffer memory of FIFO type, 2048 Words • high stable quartz generator 50 MHz and a programmable frequency devisor (from 5 upto • 31) • provides a wide grid of sampling rates • 16 digital lines: 8 - input and 8 - output

  27. References : 1) ADC Systems for SDR Digital Front-End N. vun, A. B. Premkumar, Senior members, IEEE 2) High-Resolution Analog-to-Digital Converters toward Software-Defined-Radio Receivers Akira FUJIMAKI, Yoshinori NISHIDO, and Akito SEKIYA, Members 3) Catalogs of Capture Cards from signal company

More Related