Z87200 Datasheet, PDF(3/54 Page) Zilog, Inc. – Spread-Spectrum Transceiver

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Z87200 Datasheet, PDF (3/54 Pages) Zilog, Inc. – Spread-Spectrum Transceiver

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Zilog

Z87200

Spread-Spectrum Transceiver

Z87200 I.F. Interface

To improve performance in the presence of high noise and

The Z87200 receiver circuitry employs an NCO and com-

plex multiplier referenced to RXIFCLK to perform frequen-

cy downconversion, where the input I.F. sampling rate and

the clock rate of RXIFCLK must be identical. In âcomplex

inputâ or Quadrature Sampling Mode, external dual ana-

log-to-digital converters (ADCs) sample quadrature I.F.

signals so that the Z87200 can perform true full single

sideband downconversion directly from I.F. to baseband.

At PN chip rates less than one-eighth the value of RXIF-

CLK, downconversion may also be effected using a single

ADC in âreal inputâ or Direct I.F. Sampling Mode.

interference levels, the Z87200 receiverâs symbol timing

recovery circuit incorporates a âflywheel circuitâ to maxi-

mize the probability of correct symbol timing. This circuit

will insert a symbol clock pulse if the correlation peak ob-

tained by the PN Matched Filter fails to exceed the pro-

grammed detect threshold at the expected time during a

given symbol. During each burst, a missed detect counter

tallies each such event to monitor performance and allow

a burst to be aborted in the presence of abnormally high in-

terference. A timing gate circuit further minimizes the prob-

ability of false correlation peak detection and consequent

false symbol clock generation due to noise or interference.

The input I.F. frequency is not limited by the capabilities of

the Z87200. The highest frequency to which the NCO can

be programmed is 50% of the I.F. sampling rate (the fre-

quency of RXIFCLK); moreover, the signal bandwidth,

NCO frequency, and I.F. sampling rate are all interrelated,

as discussed in Higher I.F. frequencies, however, can be

supported by using one of the aliases of the NCO frequen-

cy generated by the sampling process. For example, a

spread signal presented to the Z87200âs receiver ADCs at

an I.F. frequency of fI.F., where fRXIFCLK < fI.F. < 2 x fRXIF-

CLK, can generally, as allowed by the signalâs bandwidth,

be supported by programming the Z87200âs NCO to a fre-

quency of (fI.F.- fRXIFCLK), as discussed in Appendix A of

this product specification. The maximum I.F. frequency is

then limited by the track-and-hold capabilities of the

ADC(s) selected. Signals at I.F. frequencies up to about

100 MHz can be processed by currently available 8-bit

ADCs, but the implementation cost as well as the perfor-

mance can typically be improved by using an I.F. frequen-

cy of 30 MHz or lower. Downconversion to baseband is

then accomplished digitally by the Z87200, with a pro-

grammable loop filter provided to establish a frequency

tracking loop.

Burst and Continuous Data Modes

The Z87200 is designed to operate in either burst or con-

tinuous mode: in burst mode, built-in symbol counters al-

low bursts of up to 65,533 symbols to be automatically

transmitted or received; in continuous mode, the data is

simply treated as a burst of infinite length. The Z87200âs

use of a digital PN Matched Filter for code detection and

despreading permits signal and symbol timing acquisition

in just one symbol. The fast acquisition properties of this

design are exploited by preceding each data burst with a

single Acquisition/Preamble symbol, allowing different PN

codes (at the same PN chip rate) to independently spread

the Acquisition/Preamble and data symbols. In this way, a

long PN code with high processing gain can be used for

the Acquisition/Preamble symbol to maximize the proba-

bility of burst detection, and a shorter PN code can be used

thereafter to permit a higher data rate.

To minimize power consumption, individual sections of the

device can be turned off when not in use. For example, the

receiver circuitry can be turned off during transmission

and, conversely, the transmitter circuitry can be turned off

during reception when the Z87200 is operating in a half-

duplex/time division duplex (TDD) system. If the NCO is

not being used as the BPSK/QPSK modulator (that is, if an

external modulator is being used), the NCO can also be

turned off during transmission to conserve still more pow-

er.

Conclusion

The fast acquisition characteristics of the Z87200 make it

ideal for use in applications where bursts are transmitted

relatively infrequently. In such cases, the device can be

controlled so that it is in full âsleepâ mode with all receiver,

transmitter, and NCO functions turned off over the majority

of the burst cycle, thereby significantly reducing the aggre-

gate power consumption. Since the multiply operations of

the PN Matched Filter consume a major part of the overall

power required during receiver operation, two independent

power-saving techniques are also built into the PN

Matched Filter to reduce consumption during operation by

a significant factor for both short and long PN spreading

codes.

The above features make the Z87200 an extremely

versatile and useful device for spread-spectrum data

communications. Operating at its highest rates, the

Z87200 is suitable for use in wireless Local Area Network

implementations, while its programmability allows it to be

used in a variety of data acquisition, telemetry, and

transaction system applications.

DS96WRL0400

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