AD6640PCB AD [Analog Devices], AD6640PCB Datasheet - Page 18

AD6640PCB

Manufacturer Part Number

AD6640PCB

Description

12-Bit, 65 MSPS IF Sampling A/D Converter

Manufacturer

AD [Analog Devices]

Datasheet

1.AD6640PCB.pdf (24 pages)

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DIGITAL WIDEBAND RECEIVERS

Introduction

Several key technologies are now being introduced that may

forever alter the vision of radio. Figure 43 shows the typical

dual conversion superheterodyne receiver. The signal picked up

by the antenna is mixed down to an intermediate frequency (IF)

using a mixer with a variable local oscillator (LO); the variable

LO is used to “tune-in” the desired signal. This first IF is

mixed down to a second IF using another mixer stage and a

fixed LO. Demodulation takes place at the second or third IF

using either analog or digital techniques.

If demodulation takes place in the analog domain then tradi-

tional discriminators, envelop detectors, phase locked loops or

other synchronous detectors are generally employed to strip the

modulation from the selected carrier.

However, as general purpose DSP chips such as the ADSP-2181

become more popular, they will be used in many baseband-

sampled applications like the one shown in Figure 43. As

shown in the figure, prior to ADC conversion, the signal must

be mixed down, filtered, and the I and Q components separated.

These functions are realizable through DSP techniques, how-

ever several key technology breakthroughs are required: high

dynamic range ADCs such as the AD6640, new DSPs (highly

programmable with onboard memory, fast), digital tuners and

filters such as the AD6620, wide band mixers and amplifiers.

Figure 44 shows such a wideband system. This design shows

that the front end variable local oscillator has been replaced with

a fixed oscillator and the back end has been replaced with a

wide dynamic range ADC, digital tuner and DSP. This tech-

nique offers many benefits.

First, many passive discrete components have been eliminated

that formed the tuning and filtering functions. These passive

components often require “tweaking” and special handling

during assembly and final system alignment. Digital compo-

nents require no such adjustments; tuner and filter characteristics

are always exactly the same. Moreover, the tuning and filtering

characteristics can be changed through software. Since software

AD6640

SHARC is a registered trademark of Analog Devices, Inc.

e.g. 900MHz

Figure 43. Narrowband Digital Receiver Architecture

e.g. 900MHz

Figure 44. Wideband Digital Receiver Architecture

LNA

SHARED

LNA

WIDEBAND

MIXER

FIXED

VARIABLE

ONE RECEIVER PER CHANNEL

NARROWBAND

(416 CHANNELS)

FILTER

WIDEBAND

12.5MHz

FILTER

FIXED

NARROWBAND

WIDEBAND

SHARED

ADC

FILTER

CHANNEL SELECTION

DIGITAL TUNER/FILTER

"n" CHANNELS

TO DSP

ADCs

DSP

–18–

is used for demodulation, different routines may be used to

demodulate different standards such as AM, FM, GMSK or any

other desired standard. In addition, as new standards arise or

new software revisions are generated, they may be field installed

with standard software update channels. A radio that performs

demodulation in software as opposed to hardware is often

referred to as a soft radio because it may be changed or modified

simply through code revision.

System Description

In the wideband digital radio (Figure 44), the first down conver-

sion functions in much the same way as a block converter does.

An entire band is shifted in frequency to the desired interme-

diate frequency. In the case of cellular base station receivers,

5 MHz to 30 MHz of bandwidth are down-converted simulta-

neously to an IF frequency suitable for digitizing with a wide-

band analog-to-digital converter. Once digitized the broadband

digital data stream contains all of the in-band signals. The

remainder of the radio is constructed digitally using special

purpose and general purpose programmable DSP to perform

filtering, demodulation and signal conditioning not unlike the

analog counter parts.

In the narrowband receiver (Figure 43), the signal to be received

must be tuned. This is accomplished by using a variable local

oscillator at the first mix down stage. The first IF then uses a

narrow band filter to reject out of band signals and condition

the selected carrier for signal demodulation.

In the digital wideband receiver (Figure 44), the variable local

oscillator has been replaced with a fixed oscillator, so tuning

must be accomplished in another manner. Tuning is performed

digitally using a digital down conversion and filter chip fre-

quently called a channelizer. The term channelizer is used

because the purpose of these chips is to select one channel out

of many within the broadband spectrum present in the digital

data stream of the ADC.

Figure 45 shows the block diagram of a typical channelizer, such

as the AD6620. Channelizers consist of a complex NCO (Nu-

merically Controlled Oscillator), dual multiplier (mixer), and

matched digital filters. These are the same functions that would

be required in an analog receiver, however implemented in

digital form. The digital output from the channelizer is the

desired carrier, frequently in I & Q format; all other signals have

been filtered and removed based on the filtering characteristics

desired. Since the channelizer output consists of one selected

RF channel, one tuner chip is required for each frequency re-

ceived, although only one wideband RF receiver is needed for

the entire band. Data from the channelizer may then be pro-

cessed using a digital signal processor such as the ADSP-2181

or the SHARC

then be processed through software to demodulate the informa-

tion from the carrier.

DATA

Figure 45. AD6620 Digital Channelizer

COS

processor, the ADSP-21062. This data may

SIN

DIGITAL

TUNER

DECIMATION

FILTER

LOW-PASS

FILTER

REV. 0

AD6640PCB AD [Analog Devices], AD6640PCB Datasheet - Page 18

AD6640PCB

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