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AD6190ARSRL Datasheet PDF : 8 Pages
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AD6190
PRODUCT DESCRIPTION
The AD6190 is a complete RF/IF transceiver for operation in
the 902 MHz–928 MHz Industrial, Scientific and Medical
(“ISM”) frequency band. Together with a suitable spread-
spectrum controller, the AD6190 can be used to design
RF
a spread-spectrum system compliant with FCC “Part 15”
IN
LO
90؇
AD6190
IF
OUT
(47CFR15.247) regulations. The AD6190 is a fully compatible
companion chip to the Zilog Z87L00 “ZPhone” frequency-
hopping spread-spectrum controller.
90؇
The AD6190 includes a receive path of LNA, image-reject
mixer, IF amplifier and limiter amplifier with RSSI. The trans-
mit path accepts a 10.7 MHz IF input signal, and uses image-
Figure 9. Image-Reject Mixer
reject upconversion to the 902 MHz–928 MHz band. Frequency The RF signal, containing both the desired signal at (FLO + FIF)
control is achieved using an on-chip VCO and dual-modulus
prescaler connected to an inexpensive low frequency PLL for
channel selection and frequency hopping.
Additionally, an on-chip voltage regulator stabilizes the VCO to
prevent LO pushing due to power supply variations.
E APPLYING THE AD6190
Receive Signal Path
The AD6190 Low Noise Amplifier (LNA) and image-reject
T mixer together provide downconverter with a total gain of 24 dB
and a typical Noise Figure (NF) of 4.2 dB.
The LNA input port exhibits an impedance of 320-j61 at
E 915 MHz. In order to provide an optimum match to a 50 Ω
source, the network shown in Figure 8 should be used.
L 50⍀
82pF
2.2pF
15nH
RF IN
O AD6190
S Figure 8. LNA Input Matching Circuit
The frequency plan of the AD6190 provides the lowest possible
B RF implementation cost. A single conversion design is used with
a 10.7 MHz IF to take advantage of the very low cost filters
available. However, since the 902 MHz–928 MHz band is wider
than twice the IF, it is possible that undesired in-band signals
O will be mixed down to the IF. These images could cause inter-
and another possible signal at the image frequency of (FLO – FIF) is
applied to two mixers in parallel. These mixers are driven by
local oscillator signals in quadrature. The mixer outputs at the
two mixer IF ports contain both the desired signal and the
image signal. However, the outputs of the two mixers are in
quadrature (shifted 90 degrees relative to each other). The
outputs of the two mixers are then shifted another 90 degrees
relative to each other in a phase-shift network. The two mixer
outputs thus contain the desired signal and the image signal
exactly 180 degrees out of phase. By adding (or subtracting) the
two signals, the undesired image signals cancel, the desired
signal components add, and image-rejection occurs. Local oscil-
lator leakage is suppressed by the use of doubly-balanced mixers.
The quality of the image rejection is a function of the phase and
amplitude matching of the quadrature branches of the LO and
IF phase-shift networks. In the AD6190, image-rejection is
typically 33 dB.
The mixer output that drives the input side of the first
10.7 MHz filter should also be connected through a parallel
RLC network of 6.8 pF, 1 kΩ, and 7 pF to the power supply to
match the 330 Ω filter impedance.
The 10.7 MHz IF signal is then filtered and amplified by a
24 dB fixed gain. The output of this stage is further filtered, and
applied to a 6-stage limiting amplifier. The limiter output signal
is typically 450 mV p-p into a 30 kΩ, 30 pF load, with a dc
offset level of approximately 1.76 V dc.
All 10.7 MHz IF filters are assumed to be standard 330 Ω imped-
ance ceramic types. The AD6190 RX IF signal chain and TX IF
input includes internal matching resistors for this impedance.
When used with the Zilog Z87L00 Spread-Spectrum Controller
IC, the 10.7 MHz IF signal contains the received data encoded in
FSK modulation with approximately a ±33 kHz deviation. The
ference to the desired signal. It is thus necessary to provide
Z87L00 performs the FSK demodulation in the digital domain.
tunable filtering before the receive mixer, or some other ap-
The RSSI (Received Signal Strength Indicator) signal represents
proach to eliminate interference from image signals.
the strength of the received signal, linear in dB, and scales with
In the AD6190, a technique known as “image-reject” (or SSB)
mixing is used. This technique suppresses image interference by
using a pair of mixers with quadrature local oscillators. See
Figure 9.
supply voltage. With a 3.3 V supply (through a 10 Ω resistor on
the VCCIF pin), an RF signal level of –100 dBm at the LNA
input will produce an RSSI voltage of approximately 900 mV.
The RSSI voltage will increase with increasing RF input level,
at approximately 22 mV/dB to approximately 2.4 V at
–30 dBm input. The RSSI output voltage remains above 2.4 V
for input levels up to +15 dBm.
–6–
REV. 0
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