AD9547/PCBZ Analog Devices Inc, AD9547/PCBZ Datasheet - Page 37
AD9547/PCBZ
Manufacturer Part Number
AD9547/PCBZ
Description
Clock Generator/Synchronizer Evaluation Board
Manufacturer
Analog Devices Inc
Datasheet
1.AD9547BCPZ-REEL7.pdf
(104 pages)
Specifications of AD9547/PCBZ
Silicon Manufacturer
Analog Devices
Application Sub Type
Network Clock Generator/Synchronizer
Kit Application Type
Clock & Timing
Silicon Core Number
AD9547
Main Purpose
Timing, Clock Generator
Embedded
No
Utilized Ic / Part
AD9547
Primary Attributes
2 Differential or 4 Single Ended Inputs
Secondary Attributes
CMOS, LVPECL & LVDS Compatible
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Recovery from Holdover
When in holdover, if a valid reference becomes available, the
device exits holdover operation. The loop state machine restores
the DPLL to closed-loop operation, locks to the selected reference,
and sequences the recovery of all the loop parameters based on
the profile settings for the active reference.
Note that if the user holdover bit (Register 0x0A01, Bit 6) is set,
the device does not automatically exit holdover when a valid
reference is available. However, automatic recovery can occur
after clearing the user holdover bit.
SYSTEM CLOCK INPUTS
Functional Description
The system clock circuit provides a low jitter, stable, high fre-
quency clock for use by the rest of the chip. The user has the
option of directly driving the SYSCLKx inputs with a high
frequency clock source at the desired system clock rate.
Alternatively, the SYSCLKx input can be configured to operate
in conjunction with the internal SYSCLK PLL. The SYSCLK
PLL can synthesize the system clock by means of a crystal
resonator connected across the SYSCLKx input pins or by
means of direct application of a low frequency clock source.
The SYSCLKx inputs are internally biased to a dc level of ~1 V.
Take care to ensure that any external connections do not disturb
the dc bias because such a disturbance can significantly degrade
performance. Generally, the SYSCLKx inputs should be ac-coupled
to the signal source (except when using a crystal resonator).
Low Loop Bandwidth Applications Using a TCXO/OCXO
For many applications, the use of a crystal oscillator is a cost-
effective and simple choice. The stability is good enough to
support loop bandwidths down to 50 Hz, and the holdover
performance is good enough for all except the most demanding
applications.
In cases where Stratum 2 or Stratum 3 holdover performance is
needed, or in cases where the loop bandwidth must be <50 Hz,
the user must use either a TCXO or OCXO. The user should
choose a TCXO/OCXO with a high output frequency and
CMOS output to achieve the best performance.
Rev. B | Page 37 of 104
When interfacing the TCXO/OCXO, a voltage divider on the
output should be used to reduce the voltage swing to 1 V p-p,
and that signal should be ac-coupled to the SYSCLKP pin.
The SYSCLKN pin can be bypassed to ground with a 0.01 μF
capacitor.
Choosing the System Clock Oscillator Frequency
The best performance of the AD9548 is achieved when the
system clock is not an integer multiple of the DDS output
frequency.
As an example, using a 19.44 MHz oscillator for the system
clock in a 156.25 MHz Ethernet application yields better
performance than a 25 MHz oscillator.
Another good system clock choice for many communications
applications is a 49.152 MHz crystal used in IEEE 1394 (FireWire)
because nearly all output frequencies are not integer related to
this frequency and the crystal is readily available.
System Clock Details
A block diagram of the system clock appears in Figure 43. The
signal at the SYSCLKx input pins becomes the internally
buffered DAC sampling clock (f
•
•
•
Note that both the LF and XTAL paths require the use of the
SYSCLK PLL (see the SYSCLK PLL Multiplier section).
The main purpose of the HF path is to allow the direct use of
a high frequency (500 MHz to 1 GHz) external clock source for
clocking the AD9547. This path is optimized for high frequency
and low noise floor. Note that the HF input also provides a path
to SYSCLK PLL (see the SYSCLK PLL Multiplier section), which
includes an input divider (M) programmable for divide-by −1,
−2, −4, or −8. The purpose of the divider is to limit the frequency
at the input to the PLL to less than 150 MHz, which is the maxi-
mum PFD rate.
High frequency direct (HF)
Low frequency synthesized (LF)
Crystal resonator synthesized (XTAL)
S
) via one of three paths.
AD9547
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