fin12a Fairchild Semiconductor, fin12a Datasheet - Page 4
fin12a
Manufacturer Part Number
fin12a
Description
Fin12a Mserdes Low Voltage 12-bit Bi-directional Serializer/deserializer With Multiple Frequency Ranges Preliminary
Manufacturer
Fairchild Semiconductor
Datasheet
1.FIN12A.pdf
(21 pages)
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Power-Down Mode
Mode 0 is used for powering down and resetting the
device. When both of the mode signals are driven to a
LOW state the PLL and references will be disabled, differ-
ential input buffers will be shut off, differential output buffers
will be placed into a HIGH Impedance state, LVCMOS out-
puts will be placed into a HIGH Impedance state, and LVC-
MOS inputs will be driven to a valid level internally.
Additionally all internal circuitry will be reset. The loss of
CKREF state is also enabled to insure that the PLL will only
power-up if there is a valid CKREF signal.
In a typical application mode signals of the device will not
change other than between the desired frequency range
and the power-down mode. This allows for system level
power-down functionality to be implemented via a single
wire for a SerDes pair. The S1 and S2 selection signals
that have their operating mode driven to a “logic 0” should
be hardwired to GND. The S1 and S2 signals that have
their operating mode driven to a “logic 1” should be con-
nected to a system level power-down signal.
Serializer Operation Mode
The serializer configurations are described in the following
sections. The basic serialization circuitry works essentially
identical in these modes but the actual data and clock
streams will differ dependent on if CKREF is the same as
the STROBE signal or not. When it is stated that CKREF
STROBE this means that the CKREF and STROBE signals
have an identical frequency of operation but may or may
not be phase aligned. When it is stated that CKREF does
not equal STROBE then each signal is distinct and CKREF
must be running at a frequency high enough to avoid any
loss of data condition. CKREF must never be a lower fre-
quency than STROBE.
Serializer Operation: (Figure 1)
The PLL must receive a stable CKREF signal in order to
achieve lock prior to any valid data being sent. The CKREF
signal can be used as the data STROBE signal provided
that data can be ignored during the PLL lock phase.
Once the PLL is stable and locked the device can begin to
capture and serialize data. Data will be captured on the ris-
Modes 1, 2, or 3
DIRI equals 1
CKREF equals STROBE
4
ing edge of the STROBE signal and then serialized. The
serialized data stream is synchronized and sent source
synchronously with a bit clock with an embedded word
boundary. When operating in this mode the internal deseri-
alizer circuitry is disabled including the DS input buffer. The
CKSI serial inputs remain active to allow the pass through
of the CKSI signal to the CKP output. For more on this
mode please see the section on Passing a Word Clock. If
this mode is not needed then the CKSI inputs can either be
driven to valid levels or left to float. For lowest power oper-
ation let the CKSI inputs float.
Serializer Operation: (Figure 2)
If the same signal is not used for CKREF and STROBE,
then the CKREF signal must be run at a higher frequency
than the STROBE rate in order to serialize the data cor-
rectly. The actual serial transfer rate will remain at 14 times
the CKREF frequency. A data value of zero will be sent
when no valid data is present in the serial bit stream. The
operation of the serializer will otherwise remain the same.
The exact frequency that the reference clock needs to run
at will be dependent upon the stability of the CKREF and
STROBE signal. If the source of the CKREF signal imple-
ments spread spectrum technology then the minimum fre-
quency of this spread spectrum clock should be used in
calculating the ratio of STROBE frequency to the CKREF
frequency. Similarly if the STROBE signal has significant
cycle-to-cycle variation then the maximum cycle-to-cycle
time needs to be factored into the selection of the CKREF
frequency.
Serializer Operation: (Figure 3)
A third method of serialization can be done by providing a
free running bit clock on the CKSI signal. This mode is
enabled by grounding the CKREF signal and driving the
DIRI signal HIGH.
At power-up the device is configured to accept a serializa-
tion clock from CKSI. If a CKREF is received then this
device will enable the CKREF serialization mode. The
device will remain in this mode even if CKREF is stopped.
To re-enable this mode the device must be powered down
and then powered back up with “logic 0” on CKREF.
DIRI equals 1
CKREF does not equal STOBE
DIRI equals 1
No CKREF
Preliminary
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