AD6620S/PCB Analog Devices Inc, AD6620S/PCB Datasheet - Page 27
AD6620S/PCB
Manufacturer Part Number
AD6620S/PCB
Description
BOARD EVAL DUAL RCVR W/AD6620AS
Manufacturer
Analog Devices Inc
Datasheet
1.AD6620SPCB.pdf
(44 pages)
Specifications of AD6620S/PCB
Rohs Status
RoHS non-compliant
Module/board Type
Evaluation Board
For Use With/related Products
AD6620
Filter Phase Synchronization
Like the NCO, the AD6620 filter stages have phase synchroni-
zation circuitry enabling multiple AD6620s to be used in appli-
cations such as diversity antennas and phased array systems.
For any f
output of the CIC2 stage. Similarly, at the output of the CIC5
stage, there are M
at the output of the CIC stages there is already M
possible phases of the filtered data. Additional phase uncertainty
is introduced by decimation done in the RCF. At the output of
the AD6620 there are a total of M
output phases of the data.
In diversity systems using multiple AD6620s, it is necessary to
ensure that the output of each AD6620 in the system is in phase.
A variety of system issues (e.g., not bringing the AD6620s on
line at the same time, excessive digital noise) could cause the
AD6620s to start out-of-phase or to drift out-of-phase as the
system runs. To achieve output phase coherence in such systems
the SYNC_CIC and SYNC_RCF pins are provided.
The function of these pins is controlled by the SYNC_M/S bit
in the Mode Control Register at address 300 hex of internal
address space. When the SYNC_M/S bit is high, SYNC_CIC
and SYNC_RCF provide synchronization pulses on the rising
edge of CLK. When the SYNC_M/S bit is low, SYNC_CIC and
SYNC_RCF accept external synchronization pulses sampled on
the rising edge of clock. This pulse edge synchronizes the CIC2,
CIC5 and RCF filter stages of all AD6620 in the chain.
Below is an example of the output SYNC pulse waveforms.
The SYNC_NCO pulse is not shown and is described in the
preceding NCO Synchronization section. Each SYNC_RCF
output pulse is concurrent with a SYNC_CIC pulse. The
SYNC_RCF output pulse can be connected to the SYNC_CIC,
and SYNC_RCF inputs of another AD6620 to achieve full
decimation synchronization.
In the example above, M
by the SYNC_CIC pulses that occur every 3 CLK cycles
(M
that are one third as frequent as the SYNC_CIC pulses. In this
example full rate input timing is employed such that the input
data rate equals the clock rate.
SYNC CIC
SYNC RCF
CIC2
CLK
× M
SAMP
CIC5
, there are M
). M
CIC5
RCF
possible phases of f
= 3, resulting in SYNC_RCF pulses
CIC2
CIC2
= 3, and M
possible phases of f
CIC2
× M
CIC5
SAMP5
CIC5
= 1 as evidenced
. This means that
× M
CIC2
SAMP2
RCF
× M
possible
at the
CIC5
If the AD6620s to be synchronized have identical decimation,
then latency through the filter stages will be matched and output
data rates for the Sync master’s filter stages will match the cor-
responding filter stages of the slave.
The three SYNC inputs to the control block originate from the
same three bidirectional pads from which the three SYNC out-
puts are driven. When the AD6620 is a SYNC MASTER, the
internal circuitry that generates the SYNC pulse outputs is
enabled to the pads. When the AD6620 is a SYNC SLAVE, the
internally produced SYNC pulses are three-stated, and the pads
are driven from an external input. The capacitance on these pins
must be closely monitored since the master responds to the
same SYNC pulse as the slave (its own pulse). There is no input
requirement to the relative phases of these SYNC pulses. In the
absence of SYNC pulses each state machine will free run so the
latter decimation filters can be reliably synchronized by the
SYNC pulses of an earlier stage. However, when sync pulses are
provided externally, setup-and-hold times must be met for each
respective input.
CONTROL REGISTERS AND ON-CHIP RAM
The AD6620 provides a choice of two control ports. It has an
8-bit generic microprocessor port that is used for configuring
the device at boot up and dynamically reconfiguring the AD6620
in the system. It also has a synchronous serial port that can also
dynamically reconfigure the AD6620 for the desired system
operation. All control registers are available from both the serial
port and the microprocessor port. These control methods are
nonexclusive and the two ports can be used simultaneously. If
simultaneous access occurs, the serial port is given precedence
over the microprocessor port unless a micro cycle is already
under way. The microprocessor port deasserts the RDY signal
and waits until the serial access is completed for Mode 0. The
microprocessor port does not assert DTACK for Mode 1 until
the serial access is completed.
SYNC M/S
MASTER
MASTER
SLAVE
SLAVE
SYNC CIC
SYNC RCF
AD6620
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