AN-851 Datasheet, PDF(1/8 Page) Analog Devices – A WiMax Double Downconversion IF Sampling Receiver Design

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AN-851 Datasheet, PDF (1/8 Pages) Analog Devices – A WiMax Double Downconversion IF Sampling Receiver Design

AN-851

APPLICATION NOTE

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A WiMax Double Downconversion IF Sampling Receiver Design

by Eric Newman and Cecile Masse

INTRODUCTION

This application note describes an intermediate frequency (IF)

sampling receiver intended for use in the wireless communica-

tion services (WCS) band from 2.3 GHz to 2.36 GHz and the

unlicensed ISM band from 2.4 GHz to 2.48 GHz. The receiver

is designed for broadband Orthogonal Frequency Division

Multiplexing (OFDM) systems, as described according to IEEE

802.16 standards documentation. The design approach and

implementation procedures are presented to allow designers to

easily modify the receiver chain to address other bands such as

Wireless Broadband (WiBro) and other cellular standards such

as TDS-CDMA. The presented design is capable of addressing

channel bandwidths as wide as 10 MHz using the depicted

surface acoustic wave (SAW) filter; however, larger bandwidths

can be addressed using wider bandwidth channel-select filters

and increased sampling rates.

BACKGROUND

OFDM is the modulation scheme used in the next emerging

WiMax standard. OFDM utilizes multiple subcarriers of various IQ

modulations to achieve a high aggregate data rate that has inherent

immunity to multipath propagation. The baseband information is

spread among subcarriers so that little information is lost if

multiple propagation paths result in destructive interference and

heavily attenuate a portion of the transmitted spectrum. The

variability in the subcarrier modulation schemes allows for an

adaptive signaling approach that propagates lower data rates at the

greatest distances, while the highest data rates can be utilized when

the received signal-to-noise ratio (SNR) is high.

The variety of subcarrier modulation schemes and coding

results in different SNR requirements at the receiver. The

reference sensitivity of a WiMax receiver is defined in the IEEE

Std. 802.16-2004 to be â91 dBm for a 1.5 MHz channel using Â½

coding rate QPSK, and â65 dBm for a 20 MHz channel using Â¾

coding rate 64-QAM. This results in a receiver NF requirement

of 7 dB with 5 dB of implementation margin.

The 802.16 standard defines a maximum input power level of

â30 dBm for successful detection, with a maximum tolerated

power level of 0 dBm. While the base station or subscriber

station is not expected to decode a 0 dBm input level success-

fully, the equipment must be able to withstand the large 0 dBm

input without damage.

The 802.16 standard describes an adjacent channel rejection

requirement for the receiver. The following adjacent and

nonadjacent channel interferer to desired channel power ratios

must be achieved while maintaining a 10â6 bit error rate (BER)

while the desired signal is no more than 3 dB above the

specified reference sensitivity.

Table 1. Adjacent and Nonadjacent Channel Rejection

Requirements as Described in the 802.16-2004 Standard

Adjacent Channel

Modulation/Coding Rejection (dB)

Nonadjacent

Channel

Rejection (dB)

16-QAM-Â¾

â11

â30

64-QAM-Â¾

â4

â23

ARCHITECTURE

Figure 1 depicts a classic double downconversion IF sampling

receiver. IF sampling architectures are quite appropriate when

dealing with large signal bandwidths as employed in WiMax, or

even multicarrier systems. By using multiple down conversions,

it is possible to employ several channel select filters that help to

improve the selectivity of the receiver and improve immunity to

blocking signals that would otherwise degrade receiver sensitiv-

ity. The double downconversion also allows the use of a high

enough first IF where the image frequency band falls out of the

passband of the front-end, band-select RF filter.

The receiver architecture described in this application note is

based on a 14-bit ADC. A 12-bit ADC could be used to address

the 802.16 receiver requirements, although it is recommended

to use a 14-bit ADC for single-down conversion or for multicar-

rier architectures in order to compensate for the less efficient

selectivity and avoid the saturation of the ADC in presence of

high interferer levels. In order to design a receiver capable of

successfully addressing the multiple data rate options available,

it is necessary to select IF center frequencies carefully and

ensure that appropriate SAW filter selections are available.

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