Z87200 Datasheet, PDF(50/54 Page) Zilog, Inc. – Spread-Spectrum Transceiver

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Z87200 Datasheet, PDF (50/54 Pages) Zilog, Inc. – Spread-Spectrum Transceiver

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Z87200

Spread-Spectrum Transceiver

Zilog

THEORY OF OPERATION (Continued)

In general, when a DDS is used to generate an unmodu-

lated signal, the stepped sine wave generated by the DDS

has spectral components at integer multiples of the DDS

sampling clock. In other words, the Z87200âs BPSK/QPSK

modulator, when programmed to generate a signal at I.F.

frequency fOUT, will produce spectral components at Â±fOUT

as well as at (nRXIFCLK Â± fOUT), where n is a positive or

negative integer. Because of these aliases, one generally

cannot program the NCO to provide an output frequency

fOUT greater than the Nyquist frequency fRXIFCLK/2. When

the I.F. frequency fOUT is modulated, however, degrada-

tions to the output signal due to aliasing can result even

when fOUT is less than fRXIFCLK/2.

In particular, the Z87200âs PN modulation results in a

transmit signal that has a power spectral density charac-

terizable as a sinc function (sin(x)/x) centered about the

I.F. frequency fOUT. Nulls of the sinc function occur at inte-

ger multiples of the PN chip rate, and the null-to-null signal

bandwidth of the Z87200âs transmit signal about fOUT is

twice the transmit chip rate. The presence of modulation

sidelobes and their interaction with aliases due to sam-

pling, however, will result in distortion of the mainlobe of

the baseband component centered at fOUT unless atten-

tion is paid to the interaction of the chip rate, the I.F. fre-

quency fOUT, and the sampling rate fRXIFCLK.

In the example of Figure 18, the spectrum drawn in bold

represents a signal where fOUT has been programmed to

be (0.4 x fRXIFCLK) and has been PN-modulated at a chip

rate of (0.1 x fRXIFCLK). The first alias of the negative fre-

quency version of this signal appears centered about (0.6

x fRXIFCLK) and is shown as the lighter curve. As can be

seen, energy of the second and third modulation sidelobes

of the first alias is present within the mainlobe of the base-

band component, resulting in distortion. One would typical-

ly filter the digital-to-analog converted output of the

Z87200âs BPSK/QPSK modulator to remove the energy

outside the modulation mainlobe, but such filtering will not

affect any aliasing distortion within the mainlobe as de-

scribed here. Note that the nulls of the modulated signal

aliases in this example coincide here only due to the

choice of values for the I.F. frequency, sampling rate, and

PN chip rate; in general, the nulls will not coincide. Note

also that the filtering effect of sampling has been neglected

in this discussion â in general, the aliases will be sup-

pressed by a second sinc function, sin(fâ)/(fâ), where fâ =

Ïf/fRXIFCLK, but this effect is not very significant for the

baseband component and first alias.

Figure 16. Spectrum of DDS modulated at 0.1 x fRXIFCLK

when carrier frequency is set to 0.4 x fRXIFCLK

4-50

DS96WRL0400

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