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Ethernet 1000BASE-X PCS/PMA or SGMII v9.1
UG155 March 24, 2008
Chapter 12:
Constraining the Core
R
Virtex-5 Devices
Figure 6-6, page 75
illustrates the TBI input logic provided by the example design for the
Virtex-5 family. IODELAY elements are instantiated on the TBI data input path as
illustrated: the number of tap delays is currently set to zero. This can be modified in the
UCF file, if desired, to de-skew the bus for PCB routing. A fixed tap delay is applied to
delay the
pma_rx_clk0
clock so that it correctly samples the TBI data at the IOB IDDR
register, thereby meeting TBI setup and hold timing.
The tap delays are applied using the following UCF syntax.
#-----------------------------------------------------------
# To Adjust TBI Rx Input Setup/Hold Timing
#-----------------------------------------------------------
INST "core_wrapper/delay_pma_rx_clk" IDELAY_VALUE = "63";
INST "core_wrapper/tbi_rx_data_bus[9].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[8].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[7].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[6].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[5].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[4].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[3].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[2].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[1].delay_tbi_rx_data" IDELAY_VALUE
= "0";
INST "core_wrapper/tbi_rx_data_bus[0].delay_tbi_rx_data" IDELAY_VALUE
= "0";
The value of
IDELAY_VALUE
for the
pma_rx_clk0
clock is preconfigured in the example
designs to meet the setup and hold constraints for the example TBI pinout in the particular
device. The setup/hold timing which is achieved after place-and-route is reported in the
datasheet section of the TRCE report (created by the implement script). See
“Understanding Timing Reports for Setup/Hold Timing.”
Constraints When Implementing an External GMII
The constraints defined in this section are implemented in the UCF for the example
designs delivered with the core. Sections from this UCF have been copied into the
following examples, and should be studied in conjunction with the HDL source code for
the example design. See also the section,
“Implementing External GMII,” page 61
.
Clock Period Constraints
When implementing an external GMII, the Transmitter Elastic Buffer delivered with the
example design (or similar logic) must be used. The input transmitter GMII signals are
then synchronous to their own clock domain (
gmii_tx_clk
is used in the example
design). This clock must be constrained for a clock frequency of 125 MHz. The following
UCF syntax shows the necessary constraints being applied to the example design.
Содержание LogiCORE IP Ethernet 1000BASE-X PCS/PMA or SGMII v9.1
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