AD9862BST Analog Devices Inc, AD9862BST Datasheet - Page 24
AD9862BST
Manufacturer Part Number
AD9862BST
Description
IC FRONT-END MIXED-SGNL 128-LQFP
Manufacturer
Analog Devices Inc
Datasheet
1.AD9860-EBZ.pdf
(32 pages)
Specifications of AD9862BST
Rohs Status
RoHS non-compliant
Rf Type
LMDS, MMDS
Features
12-bit ADC(s), 14-bit DAC(s)
Package / Case
128-LQFP
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AD9860/AD9862
The output will be latched using some configuration of CLKOUT1
or CLKOUT2 edges as defined in the Clock Overview section of
the data sheet. The Rx path available options include bypassing
the input buffer, RxPGA control and using the decimation filter.
The input buffer description above explains the conditions under
which the buffer should be bypassed.
If the input signal, or the undersampled alias signal for the
IF sampling case, falls below 40% of the ADC Nyquist rate, the
decimation filter can be enabled to suppress out-of-band noise
and spurious signals by 40 dB or more. With the decimation
filter enabled the SNR of the Rx path improves by about 2.3 dB.
Dual Channel Complex ADC Signal
The Dual Channel Complex ADC Signal mode is used to receive
baseband I and Q signals or a single sideband signal at some IF.
In this mode, a complex input signal is generated from an external
quadrature demodulator. The in-phase channel (I channel) is
connected to VIN+A and VIN–A, and the Quadrature Data
(Q channel) is connected to the VIN+B and VIN–B differential
pins. The Rx path available options include bypassing the input
buffer, RxPGA control, the decimation filter, and using the digital
Hilbert filter. Shared Reference mode is also discussed below.
The RxPGA provides 0 dB to 20 dB gain control for both chan-
nels. The input buffer description above explains the conditions
under which the buffer should be bypassed.
If the input signal, or the undersampled alias signal for the IF sam-
pling case, falls below 40% of the ADC Nyquist rate, the decimation
filter can be enabled to suppress out-of-band noise and spurious
signals by 40 dB or more. With the decimation filter enabled,
the SNR of the Rx path improves by about 2.3 dB.
A digital Hilbert filter can be enabled to provide a receive image
rejection architecture on-chip. The digital Hilbert filter combines
the I data and a phase shifted version of the Q data to produce a
single combined Rx signal. The filter can provide 50 dB image
suppression in the pass band (less than 0.1 dB ripple). The pass
band of the filter is from 25% to 75% of Nyquist rate of the data
entering the Hilbert filter. Note, the Hilbert filter’s maximum
input data rate is 32 MSPS, at ADC rates above 32 MSPS. The
decimation filter is required to reduce the data rate. With the
decimation filter also enabled, the pass band of the Hilbert filter
will be 12.5% to 37.5% of the ADC Nyquist rate (still 25% to 75%
of the Nyquist rate of the data entering the Hilbert filter).
An optional Shared Reference mode allows the user to connect the
differential references from the dual ADC together externally for
superior gain matching performance. To enable the Shared Ref-
erence mode, the Shared Ref register (d4, b1) should be set high.
TIMING GENERATION BLOCK
The AD9860/AD9862 Timing Generation block uses a single
external clock reference to derive all internal clocks to operate
the transmit and receive channels. The input clock reference
can consist of either an external single ended clock applied to
the OSC1 pin, with the OSC2 pin left floating or an external
crystal connected between the clock input pins (OSC1 and OSC2).
By default, the AD9860/AD9862 can accept either an external
reference clock or a crystal to generate the input clock. The
internal oscillator, if not used, should be disabled by setting the
Input Control Clock register. The OSC1 input impedance is a
relatively high resistive impedance (typically, about 500 kW).
–24–
An internal Delay Lock Loop (DLL) based clock multiplier pro-
vides a low noise, 2 or 4 multiplication of the input clock over
an output frequency range of 32 MHz to 128 MHz. The DLL
Fast register should be used to optimize the DLL performance.
For DLL output frequencies between 32 MHz and 64 MHz, this
bit should be set low. For output frequencies between 64 MHz
to 128 MHz, the Fast bit should be set high (for a 64 MHz out-
put frequency, the register can be set either high or low). The DLL
can be bypassed by setting a 1 multiplication factor in the DLL
Multiplier register. The DLL can be powered down when it is
bypassed for power savings by setting the DLL PwrDwn register.
For applications where an external crystal is desired, the AD9860/
AD9862 internal oscillator circuit and the DLL clock multiplier
enable a low frequency, lower cost quartz crystal to be used to
generate the input reference clock. The quartz crystal would be
connected between the OSC1 and OSC2 pins with parallel
resonant load capacitors as specified by the crystal manufacturer.
An internal Duty Cycle Stabilizer (DCS) can be enabled on the
AD9860 by setting the Clk Duty register. This provides a stable
50% duty cycle to the ADC for high speed clock rates between
40 MSPS to 64 MSPS when proper duty cycle is more critical.
System Clock Distribution Circuitry
There are many variables involved in the timing distribution.
External variables include CLKIN, CLKOUT1, CLKOUT2,
Rx Data Rate, Tx Data Rate. Internal variables include ADC
conversion rate, DAC update rate, interpolation rate, decimation
rate, Rx data multiplexing and Tx data demultiplexing. Many of
these parameters are interrelated and based on CLKIN. Optimal
power versus performance and ease of integration options can
be chosen to suit a particular application.
One of two possible timing operation modes can be selected. The
typical timing mode is called Normal Operation mode; a block
diagram is shown in Figure 8. The other mode is called Alterna-
tive Operation mode, and a block diagram is shown in Figure 12.
CLKIN
Figure 8. Normal Operation Timing Block Diagram
ADC DIV2:
REG D24 B5
1 , 1/2
CLKSEL
1 , 1/2
DIV
DIV
CLOCK PATH
DATA PATH
ADC
DLL MULTIPLIER:
REG D24 B3, 4
1 , 2 , 4
INV1: REG D25 B1
NO DECIMATION,
NO INVERSION,
INVERT
DLL
DECIMATE:
REG D6 B0
DAC
INV
CLKOUT1
INTERPOLATION:
REG D19 B0, 1
1 , 1/2 , 1/4
CLKOUT2
DIV FACTOR:
REG 25 B6, 7
NO INTERP
2
MUX OUT:
REG D5 B0
Rx RETIME:
REG D5 B3
2, 4
DIV
LATCH
DATA
MUX
AND
2 DATA PATHS: REG D19 B4
Q/I ORDER:
Tx RETIME:
NO INVERSION,
INVERT
INV2:
REG D25 B5
DEMUX
LATCH
DATA
AND
INV
Rx DATA
[0:23]
REG D18 B5
REG D18 B6
CLKOUT2
REV. 0
Tx DATA
[0:13]
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