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AD6652
APPLICATIONS
Rev. 0 | Page 73 of 76
AD6652 RECEIVER APPLICATIONS
One CDMA2000 IF Carrier with No External Analog
Filtering
Code Division Multiple Access depends upon a unique code
sequence that modulates the IF carrier along with the payload
data. This permits multiple signals to be transmitted on the
same carrier frequency and successfully separated at the
receiver. This technique spreads the spectrum of the initial
digital bit stream over a much wider bandwidth. The wideband
nature and stringent adjacent channel-filtering requirements of
CDMA2000 allow the AD6652 to process only one CDMA2000
channel. To do this requires the processing power of all four
channels operating at maximum speed.
Two CDMA2000 IF Carriers with External Analog Saw
Filtering
If two CDMA2000 carriers are to be processed by the AD6652,
prefiltering of the analog signal(s) going to the AD6652 is
required. Surface acoustic wave (SAW) filters are commonly
used to reduce the digital signal processing required of the
AD6652 filters. This combination permits adequate reduction
of the adjacent channel interference as specified for that
medium and permits two CDMA2000 carriers to be processed
using only two DDC channels per carrier.
Two UMTS or WCDMA IF Carriers with No External
Analog Saw Filtering
er requirements of wideband CDMA
TS, the AD665
sing p
f exte
al analog filters.
aseband I and Q Processor
his application calls for baseband I and Q analog signals to be
outed individually to the two AD6652 ADC inputs. The 12-bit
DCs digitize the signals and send the data to all four receive
rocessing channels for decimation and filtering. Therefore,
ach channel is processing the same 12 bits of I data and 12 bits
f Q data simultaneously. The user can shut down unused
hannels as desired.
c
MA carrier
nels for each carrie
rocessing baseband I and Q data requires that each active
channel’s NCO and quadrature mixer be bypassed by program-
ming of the NCO control registers.
DESIGN GUIDELINES
When designing the AD6652 into a system, it is recommended
that, before starting design and layout, the designer become
familiar with these guidelines, which discuss the special circuit
connections and layout requirements required for certain pins.
1.
The following power-up sequence is recommended for the
AD6652. First, ensure that RESET
AVDD (3.0 V) and VDD (2.5 V), allowing them both to
settle to nominal values before applying VDDIO (3.3 V).
Once VDDIO (3.3 V) has settled to nominal value, bring
RESET logic high. Last, apply a logic low RESET pulse for
30 ns to reset the AD6652 into a known state ready for
programming.
Due to less stringent filt
and UM
using the proces
without the use o
B
T
r
A
p
e
o
2 can receive two WCD
ower of two chan
rn
s
r
P
is held logic low. Apply
2.
RESET pin: The RESET pin must be held logic low during
power-up sequencing to ensure that the internal logic starts
in a known state. Certain registers, noted in the datasheet,
are cleared after hardware reset. Failure to ensure hardware
reset during power-up might result in invalid output until a
valid reset is applied.
3.
The number format used in this part is twos complement.
All input ports and output ports use twos complement data
format. The formats for individual internal registers are
given in the memory map description of these registers.
4.
To enhance microport programming, the DTACK (RDY)
should be pulled high (to VDDIO)
pin
pull-up resister. The recomm
resistor is between 1 kΩ a
ended val
nd 5 kΩ.
ull-up
5.
CS
microport. It is recommended that the designer not tie this
pin low at all times. This pin should ideally be pulled high
using a pull-up resistor, and the user can pull it low
whenever microport control is required.
externally using a
ue for the p
pin is used as chip select for programming with the
6.
The output parallel port has one clock cycle overhead for
every output sample. So, if data from two AGCs with the
same data rate are output on one output port in 16-bit
interleaved I/Q mode along with the AGC word, then four
clock cycles are required for one sample from each
channel/AGC: one blank clock cycle, and one clock cycle
each for I data, Q data, and gain data.