Arria V GZ Device Family Pin Connection Guidelines

®
Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
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These pin connection guidelines should only be used as a recommendation, not as a specification. The use of the pin connection guidelines for any particular design should be verified for
device operation, with the datasheet and Altera.
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PCG-01016-1.4
Copyright © 2015 Altera Corp.
Page 1 of 23
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Connection Guidelines
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
CLK[0:23]p
I/O, Clock Input
Dedicated high speed clock input pins that can also be
used for data inputs/outputs. Differential input OCT Rd,
single ended input OCT Rt, and single ended output OCT
Rs are supported on these pins.
You can tie unused pins to GND or leave them unconnected. If
unconnected, use the Quartus II software programmable options to
internally bias these pins. You can reserve them as inputs tristate with
weak pull-up resistor enabled, or as outputs driving GND.
CLK[0:23]n
I/O, Clock Input
Dedicated high speed clock input pins that can also be
used for data inputs/outputs. Differential input OCT Rd,
single ended input OCT Rt, and single ended output OCT
Rs are supported on these pins.
You can tie unused pins to GND or leave them unconnected. If
unconnected, use the Quartus II software programmable options to
internally bias these pins. You can reserve them as inputs tristate with
weak pull-up resistor enabled, or as outputs driving GND.
FPLL_[B,T][L,C,R]_FB/CLKOUTp
I/O, Clock
Dual purpose I/O pins that can be used as two single-ended
outputs or one differential external feedback input pin.
You can tie unused pins to GND or leave them unconnected. If
unconnected, use the Quartus II software programmable options to
internally bias these pins. You can reserve them as inputs tristate with
weak pull-up resistor enabled, or as outputs driving GND.
FPLL_[B,T][L,C,R]_FB/CLKOUTn
I/O, Clock
FPLL_[B,T][L,C,R]_CLKOUTp
I/O, Clock
FPLL_[B,T][L,C,R]_CLKOUTn
I/O, Clock
Arria V GZ Pin Name
Clock and PLL Pins
You can tie unused pins to GND or leave them unconnected. If
unconnected, use the Quartus II software programmable options to
internally bias these pins. You can reserve them as inputs tristate with
weak pull-up resistor enabled, or as outputs driving GND.
I/O pins that can be used as two single-ended clock output
pins or one differential clock output pair.
You can tie these pins to GND or leave them unconnected. If
unconnected, use Quartus II software programmable options to internally
bias these pins. You can reserve them as inputs tristate with weak pull up
resistor enabled, or as outputs driving GND.
You can tie these pins to GND or leave them unconnected. If
unconnected, use Quartus II software programmable options to internally
bias these pins. You can reserve them as inputs tristate with weak pull up
resistor enabled, or as outputs driving GND.
Dedicated Configuration/JTAG Pins
nIO_PULLUP
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Input
Dedicated input that chooses whether the internal pull-ups
on the user I/O pins and dual-purpose I/O pins
(DATA[0:31], CLKUSR, INIT_DONE, DEV_OE,
DEV_CLRn) are on or off before and during configuration. A
logic high turns off the weak pull-up, while a logic low turns
them on.
The nIO_PULLUP pin must be tied to GND.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
TEMPDIODEp
Input
Pin used in conjunction with the temperature sensing diode
(bias-high input) inside the FPGA.
If the temperature sensing diode is not used with an external temperture
sensing device, then connect this pin to GND. When connecting the
TEMPDIODE pins to an external temperture sense device, refer to the
"Power Management in Arria V Devices" chapter in the Arria V Handbook.
TEMPDIODEn
Input
Pin used in conjunction with the temperature sensing diode
(bias-low input) inside the FPGA.
If the temperature sensing diode is not used with an external temperture
sensing device, then connect this pin to GND. When connecting the
TEMPDIODE pins to an external temperture sense device, refer to the
"Power Management in Arria V Devices" chapter in the Arria V Handbook.
MSEL[0:4]
Input
Configuration input pins that set the FPGA device
configuration scheme.
These pins are internally connected through a 25-kΩ resistor to GND. Do
not leave these pins floating. When these pins are unused connect them
to GND. Depending on the configuration scheme used you should tie
these pins to VCCPGM or GND. Refer to the "Configuration, Design
Security, and Remote System Upgrades in Arria V Devices" chapter in the
Arria V Handbook for the configuration scheme options. If only JTAG
configuration is used, connect these pins to GND.
nCE
Input
Dedicated active-low chip enable. When nCE is low, the
device is enabled. When nCE is high, the device is
disabled.
In multi-device configuration, nCE of the first device is tied low while its
nCEO pin drives the nCE of the next device in the chain. In single device
configuration and JTAG programming, you should connect nCE to GND.
nCONFIG
Input
Dedicated configuration control input. Pulling this pin low
during user-mode will cause the FPGA to lose its
configuration data, enter a reset state, and tri-state all I/O
pins. Returning this pin to a logic high level will initiate
reconfiguration.
You should connect nCONFIG directly to the configuration controller when
the FPGA uses a passive configuration scheme, or through a 10-kΩ
resistor tied to VCCPGM when using an active serial configuration
scheme. If this pin is not used, it requires a connection directly or through
a 10-kΩ resistor to VCCPGM.
CONF_DONE
Bidirectional
(open-drain)
This is a dedicated configuration done pin. As a status
output, the CONF_DONE pin drives low before and during
configuration. After all configuration data is received without
error and the initialization cycle starts, CONF_DONE is
released. As a status input, CONF_DONE goes high after
all data is received. Then the device initializes and enters
user mode. It is not available as a user I/O pin.
If internal pull-up resistors on the configuration controller or enhanced
configuration device are used, you should not use external 10-kΩ pull-up
resistors on this pin. Otherwise you should use an external 10-kΩ pull-up
resistor to VCCPGM. When you use passive configuration schemes, this
pin should also be monitored by the configuration controller.
Output that drives low when device configuration is
complete. If this pin is not enabled for use as a
configuration pin, it can be used as a user I/O pin.
During multi-device configuration, this pin feeds the nCE pin of a
subsequent device. Connect this pin to an external 10-kΩ pull-up resistor
to VCCPGM. During single device configuration, you may leave this pin
floating.
nCEO
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I/O, Output
(open-drain)
The CONF_DONE error checking is not supported in the active serial
multi-device configuration mode.
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Arria V GZ Device Family Pin Connection Guidelines
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Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
nSTATUS
Bidirectional
(open-drain)
This is a dedicated configuration status pin. The FPGA
drives nSTATUS low immediately after power-up and
releases it after POR time. As a status output, the
nSTATUS is pulled low if an error occurs during
configuration. As a status input, the device enters an error
state when nSTATUS is driven low by an external source
during configuration or initialization. It is not available as a
user I/O pin.
The OE and nCE pins of the enhanced configuration devices have
optional internal programmable pull-up resistors. If internal pull-up
resistors on the enhanced configuration device are used, you should not
use external 10-kΩ pull-up on these pins. Otherwise, an external 10-KΩ
pull-up resistors to VCCPGM should be used. When using Passive
configuration schemes this pin should also be monitored by the
configuration controller.
TCK
Input
Dedicated JTAG test clock input pin.
Connect this pin to a 1-kΩ pull-down resistor to GND. This pin has an
internal 25-kΩ pull-down.
TMS
Input
Dedicated JTAG test mode select input pin.
Connect this pin to a 1-kΩ - 10-kΩ pull-up resistor to VCCPD. If the JTAG
connections are not used, connect TMS to VCCPD using a 1-kΩ resistor.
This pin has an internal 25-kΩ pull-up.
TDI
Input
Dedicated JTAG test data input pin.
Connect this pin to a 1-kΩ - 10-kΩ pull-up resistor to VCCPD. If the JTAG
connections are not used, connect TDI to VCCPD using a 1-kΩ resistor.
This pin has an internal 25-kΩ pull-up.
TDO
Output
Dedicated JTAG test data output pin.
You can disable the JTAG circuitry by leaving TDO unconnected. In cases
where TDO uses VCCPD = 2.5 V to drive a 3.3 VJTAG interface, there
may be leakage current in the TDI input buffer of the interfacing devices.
You may use an external pull-up resistor tied to 3.3 V on their TDI pin to
eliminate the leakage current if needed.
TRST
Input
Dedicated active low JTAG test reset input pin. TRST is
used to asynchronously reset the JTAG boundary-scan
circuit.
Utilization of TRST is optional. When you use this pin ensure that TMS is
held high or TCK is static when TRST is changed from low to high. If not
using TRST, tie this pin to a 1-kΩ pull-up resistor to VCCPD. If the JTAG
connections are not used, tie this pin to GND. This pin has an internal 25kΩ pull-up.
Dedicated output control signal from the FPGA to the serial
configuration device in AS mode that enables the
configuration device.
When not programming the device in AS mode nCSO is not used. Also,
when this pin is not used as an output then it is recommended to leave the
pin unconnected.
Optional/Dual-Purpose Configuration Pins
nCSO
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Output
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Arria V GZ Device Family Pin Connection Guidelines
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Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
DCLK
Input (PS,
FPP) Output
(AS)
Dedicated configuration clock pin. In PS and FPP
configuration, DCLK is used to clock configuration data
from an external source into the FPGA. In AS mode, DCLK
is an output from the FPGA that provides timing for the
configuration interface.
Do not leave this pin floating. Drive this pin either high or low.
CRC_ERROR
I/O, Output
(open-drain)
Active high signal that indicates that the error detection
circuit has detected errors in the configuration SRAM bits.
This pin is optional and is used when the CRC error
detection circuit is enabled.
When using as optionally open-drain output dedicated CRC_ERROR pin,
connect this pin to an external 10-kΩ pull-up resistor to VCCPGM. When
not using as the dedicated CRC_ERROR optionally open-drain output,
and when this pin is not used as an I/O pin, then connect this pin as
defined in the Quartus II software.
DEV_CLRn
I/O, Input
Optional pin that allows designers to override all clears on
all device registers. When this pin is driven low, all registers
are cleared; when this pin is driven high (VCCPGM), all
registers behave as programmed.
When the dedicated input DEV_CLRn is not used and this pin is not used
as an I/O then it is recommended to tie this pin to ground.
DEV_OE
I/O, Input
Optional pin that allows designers to override all tri-states
on the device. When this pin is driven low, all I/O pins are
tri-stated; when this pin is driven high (VCCPGM), all I/O
pins behave as defined in the design.
When the dedicated input DEV_OE is not used and this pin is not used as
an I/O then it is recommended to tie this pin to ground.
DATA0
I/O, Input
Dual-purpose configuration data input pin. The DATA0 pin
can be used for PS or FPP configuration or as an I/O pin
after configuration is complete.
When the dedicated input for DATA[0] is not used and this pin is not used
as an I/O then it is recommended to leave this pin unconnected.
DATA[1:31]
I/O, Input
Dual-purpose configuration input data pins. Use DATA [1:7]
pins for FPP x8, DATA [1:15] pins for FPP x16, and DATA
[1:31] pins for FPP x32 configuration or as regular I/O pins.
These pins can also be used as user I/O pins after
configuration.
When the dedicated inputs for DATA[1:31] are not used and these pins
are not used as an I/O then it is recommended to leave these pins
unconnected.
INIT_DONE
I/O, Output
(open-drain)
This is a dual-purpose pin and can be used as an I/O pin
when not enabled as INIT_DONE. When enabled, a
transition from low to high at the pin indicates when the
device has entered user mode. If the INIT_DONE output is
enabled, the INIT_DONE pin cannot be used as a user I/O
pin after configuration.
When using as optionally open-drain output dedicated INIT_DONE pin,
connect this pin to an external 10-kΩ pull-up resistor to VCCPGM. When
using in an AS or PS multi-device configuration mode ensure that the
INIT_DONE pin is enabled in the Quartus II designs. When not using as
the dedicated INIT_DONE optionally open-drain output, and when this pin
is not used as an I/O pin, then connect this pin as defined in the Quartus II
software.
In the active serial multi-device configuration mode, do not tie the
INIT_DONE pin together with other devices. Tie the INIT_DONE pin
independently to a pull-up resistor.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
CLKUSR
I/O, Input
Optional user-supplied clock input. Synchronizes the
initialization of one or more devices. If this pin is not
enabled for use as a user-supplied configuration clock, it
can be used as a user I/O pin.
If the CLKUSR pin is not used as a configuration clock input and the pin is
not used as an I/O then it is recommended to connect this pin to ground.
nPERSTL0
I/O, Input
Dedicated Fundamental Reset pin is only available when
used in conjunction with PCIe HIP. When low the
transcievers are in reset. When high the transceivers are
out of reset. When this pin is not used as the fundamental
reset, this pin may be used as a user I/O.
Connect this pin as defined in the Quartus II software. You may drive this
pin by 3.3V regardless of the VCCIO voltage level of the bank without a
level translator as long as:
• the input signal meets the LVTTL VIH/VIL specification, and
• as long as it meets the overshoot specifications for 100%
operation as listed in the Arria V device datasheet.
Only one nPERST pin is used per PCIe HIP.
nPERSTL0 = Bottom Left PCIe HIP.
AS_DATA0 / ASDO
Bidirectional
Dedicated AS configuration pin. When using an EPCS
device (x1 mode) this is the ASDO pin and used to send
address and control signals between the FPGA and the
EPCS/EPCQ.
When not programming the device in AS mode ASDO is not used. Also,
when this pin is not used it is recommended to leave the pin unconnected.
AS_DATA[1:3]
Bidirectional
Dedicated AS configuration data pins. Configuration data is
transported on these pins when connected to the EPCQ
devices.
When this pin is not used it is recommended to leave the pin unconnected.
PR_REQUEST
I/O, Input
Partial Reconfiguration Request pin. Drive this pin high to
start partial reconfiguration. Drive this pin low to end
reconfiguration.
This pin can only be used in Partial Reconfiguration using
external host mode in FPP x16 configuration scheme.
When the dedicated input PR_REQUEST is not used and this pin is not
used as an I/O, then it is recommended to tie this pin to GND.
PR_READY
I/O, Output or
Output
(open-drain)
The partial reconfiguration ready pin is driven low until the
device is ready to begin partial reconfiguration. When the
device is ready to start reconfiguration, this signal is
released and is pulled high by an external pull-up resistor.
When using as optionally open-drain output dedicated PR_READY pin,
connect this pin to an external 10-kΩ pull-up resistor to VCCPGM. When
not using as the dedicated PR_READY optionally open-drain output, and
when this pin is not used as an I/O pin, then connect this pin as defined in
the Quartus II software.
PR_ERROR
I/O, Output or
Output
(open-drain)
The partial reconfiguration error pin is driven low during
partial reconfiguration unless the device detects an error. If
an error is detected, this signal is released and pulled high
by an external pull-up resistor.
When using as optionally open-drain output dedicated PR_ERROR pin,
connect this pin to an external 10-kΩ pull-up resistor to VCCPGM. When
not using as the dedicated PR_ERROR optionally open-drain output, and
when this pin is not used as an I/O pin, then connect this pin as defined in
the Quartus II software.
Partial Reconfiguration Pins
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Arria V GZ Device Family Pin Connection Guidelines
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Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
PR_DONE
I/O, Output or
Output(opendrain)
The partial reconfiguration done pin is driven low until the
partial reconfiguration is complete. When the
reconfiguration is complete, this signal is released and is
pulled high by an external pull-up resistor.
When using as optionally open-drain output dedicated PR_DONE pin,
connect this pin to an external 10-kΩ pull-up resistor to VCCPGM. When
not using as the dedicated PR_DONE optionally open-drain output, and
when this pin is not used as an I/O pin, then connect this pin as defined in
the Quartus II software.
CvP_CONFDONE
I/O, Output
(open-drain)
Configuration Via Protocol Done pin is driven low during
configuration. When configuration via PCIe is complete, this
signal is released and is pulled high by an external pull-up
resistor. Status of this pin is only valid if CONF_DONE is
high.
When using as optionally open-drain output dedicated CvP_CONFDONE
pin, connect this pin to an external 10-kΩ pull-up resistor to VCCPGM.
When not using as the dedicated CvP_CONFDONE optionally open-drain
output, and when this pin is not used as an I/O pin, then connect this pin
as defined in the Quartus II software.
DIFFIO_RX_[T,B][#:#]p,
DIFFIO_RX_[T,B][#:#]n
I/O, RX
channel
These are true LVDS receiver channels on row and column
I/O banks. Pins with a "p" suffix carry the positive signal for
the differential channel. Pins with an "n" suffix carry the
negative signal for the differential channel. If not used for
differential signaling, these pins are available as user I/O
pins. OCT Rd is supported on all DIFFIO_RX pins when
VCCPD is 2.5V.
Connect unused pins as defined in Quartus II software.
DIFFIO_TX_[T,B][#:#]p,
DIFFIO_TX_[T,B][#:#]n
I/O, TX
channel
These are true LVDS transmitter channels on side I/O
banks. Pins with a "p" suffix carry the positive signal for the
differential channel. Pins with an "n" suffix carry the
negative signal for the differential channel. If not used for
differential signaling, these pins are available as user I/O
pins.
Connect unused pins as defined in Quartus II software.
DIFFOUT_[T,B][##]p,
DIFFOUT_[T,B][##]n
I/O, TX
channel
These are emulated LVDS output channels. All user I/Os,
including I/Os with true LVDS input buffers, can be
configured as emulated LVDS output buffers. Pins with a
"p" suffix carry the positive signal for the differential
channel. Pins with an "n" suffix carry the negative signal for
the differential channel. If not used for differential signaling,
these pins are available as user I/O pins.
Connect unused pins as defined in Quartus II software.
Differential I/O Pins
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Arria V GZ Device Family Pin Connection Guidelines
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Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
I/O,DQS
Optional data strobe signal for use in external memory
interfacing. These pins drive to dedicated DQS phase shift
circuitry. The shifted DQS signal can also drive to internal
logic.
Connect unused pins as defined in Quartus II software. See Note 11.
I/O,DQSn
Optional complementary data strobe signal for use in
external memory interfacing. These pins drive to dedicated
DQS phase shift circuitry.
Connect unused pins as defined in Quartus II software. See Note 11.
I/O,DQ
Optional data signal for use in external memory interfacing.
The order of the DQ bits within a designated DQ bus is not
important; however, use caution when making pin
assignments if you plan on migrating to a different memory
interface that has a different DQ bus width. Analyze the
available DQ pins across all pertinent DQS columns in the
pin list.
Connect unused pins as defined in Quartus II software. See Note 11.
DQS
Optional data strobe signal for use in QDRII SRAM. These
are the pins for echo clocks.
Connect unused pins as defined in Quartus II software. See Note 12.
DQS
Optional complementary data strobe signal for use in QDRII
SRAM. These are the pins for echo clocks.
Connect unused pins as defined in Quartus II software. See Note 12.
RREF_[T,B][L,R]
Input
Reference resistor for transceiver, specific to the left (L)
side or right (R) side of the device.
If any PLL, REFCLK pin, or transceiver channel on one side (left or right)
of the device is used, you must connect each RREF pin on that side of the
device to its own individual 1.8kΩ +/- 1% resistor to GND. Otherwise, you
may connect each RREF pin on that side of the device directly to GND. In
the PCB layout, the trace from this pin to the resistor needs to be routed
so that it avoids any aggressor signals.
RZQ_[#]
I/O, Input
Reference pins for I/O banks. The RZQ pins share the
same VCCIO with the I/O bank where they are located. The
external precision resistor must be connected to the
designated pin within the bank. If not required, this pin is a
regular I/O pin.
When the device does not use this dedicated input for the external
precision resistor or as an I/O it is recommended that you connect the pin
to GND. When using OCT tie these pins to GND through either a 240W or
100W resistor, depending on the desired OCT impedence. Refer to the
Arria V handbook for the OCT impedence options for the desired OCT
scheme.
Arria V GZ Pin Name
External Memory Interface Pins
DQS[1:66]T,
DQS[1:70]B
DQSn[1:66]T,
DQSn[1:70]B
DQ[1:66]T,
DQ[1:70]B
CQ[1:27]T,
CQ[1:29]B
CQn[1:27]T,
CQn[1:29]B
Reference Pins
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Arria V GZ Device Family Pin Connection Guidelines
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Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
DNU
Do Not Use
Do Not Use (DNU).
Do not connect to power, ground or any other signal. You must leave
these pins floating.
NC
No Connect
Do not drive signals into these pins.
When designing for device migration you may connect these pins to
power, ground, or a signal trace depending on the pin assignment of the
devices selected for migration. However, if device migration is not a
concern leave these pins floating.
Supply Pins (See Notes 4 through 7)
VCC
Power
VCC supplies power to the core and periphery.
VCC is 0.85V. Connect all VCC pins to a low noise switching regulator.
When VCCHIP and VCCHSSI are used, tie these pins to the same plane
as VCC. For data rates less than 6.5 Gbps and with a proper isolation
filter, you may source VCCR_GXB and VCCT_GXB from the same
regulator as VCC when the power rails require the same voltage level. Use
the Arria V Early Power Estimator to determine the current requirements
for VCC and other power supplies. Decoupling for these pins depends on
the design decoupling requirements of the specific board. See Notes 2, 3,
4, and 6.
VCCD_FPLL
Power
PLL digital power.
Connect all VCCD_FPLL pins to a 1.5V linear or low noise switching
power supply. You may tie these pins to the same regulator as VCCPT,
VCCBAT, and VCCH_GXB. Decoupling for these pins depends on the
design decoupling requirements of the specific board. See Notes 2, 3, and
4.
VCCPT
Power
Power supply for the programmable power technology.
Connect all VCCPT pins to a 1.5V linear or low noise switching power
supply. You may tie these pins to the same regulator as VCCD_FPLL,
VCCBAT and VCCH_GXB. Decoupling for these pins depends on the
design decoupling requirements of the specific board. See Notes 2, 3, 4
and 7.
VCCA_FPLL
Power
PLL analog power.
Connect these pins to a 2.5V low noise switching power supply through a
proper isolation filter. You may share this power rail with VCC_AUX. With
a proper isolation filter you may source these pins from the same regulator
as VCCIO, VCCPD and VCCPGM when each of these power supplies
require 2.5V. Decoupling for these pins depends on the design decoupling
requirements of the specific board. See Notes 2, 3, 4, and 7.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
VCC_AUX
Power
Auxiliary supply for the programmable power technology.
Connect all VCC_AUX pins to a 2.5V low noise switching power supply
through a proper isolation filter. You may share this power rail with
VCCA_FPLL. With a proper isolation filter you may source these pins from
the same regulator as VCCIO, VCCPD and VCCPGM when each of these
power supplies require 2.5V. Decoupling for these pins depends on the
design decoupling requirements of the specific board. See Notes 2, 3, 4,
and 7.
VCCIO[3,4,7,8][A,B,C,D]
Power
These are I/O supply voltage pins for banks 1 through 8.
Each bank can support a different voltage level. supported
VCCIO standards include LVDS, LVCMOS( 3.0V),
HSTL(12, 15, 18), SSTL(12, 125, 135, 15, 18, 2), LVTTL
(3.0V), HSUL(12), LVPECL(2.5V),1.2V, 1.5V, 1.8V, 2.5V
I/O standards.
Connect these pins to 1.2V, 1.25V, 1.35V, 1.5V, 1.8V, 2.5V or 3.0V
supplies, depending on the I/O standard connected to the specified bank.
When these pins require the same voltage level as VCCPD and/or
VCCPGM, you may tie them to the same regulator as VCCPD and/or
VCCPGM, but only if each of these supplies requires the same voltage
level. Decoupling for these pins depends on the design decoupling
requirements of the specific board. See Notes 2, 3, 4, and 8.
VCCPGM
Power
Configuration pins power supply.
Connect these pins to either 1.8V, 2.5V or 3.0V power supply. When these
pins require the same voltage level as VCCPD and/or VCCIO, you may tie
them to the same regulator as VCCPD and/or VCCIO, but only if each of
these supplies requires the same voltage level. Decoupling for these pins
depends on the design decoupling requirements of the specific board. See
Notes 2, 3, and 4.
VCCPD3[AB][CD]
Power
Dedicated power pins. This supply is used to power the I/O
pre-drivers. This can be connected to 2.5V or 3.0V. For
1.2V, 1.25V, 1.35V, 1.5V, 1.8V or 2.5V I/O standards
connect VCCPD to 2.5V and for 3.0V I/O standard connect
VCCPD to 3.0V.
The VCCPD pins require 2.5V or 3.0V. When these pins have the same
voltage requirements as VCCPGM and VCCIO, you may tie them to the
same regulator. The voltage on VCCPD is dependent on the VCCIO
voltage.
VCCPD[4,7,8]
When VCCIO is 3.0V, VCCPD must be 3.0V.
When VCCIO is 2.5V or less, VCCPD must be 2.5V.
Decoupling for these pins depends on the design decoupling requirements
of the specific board. See Notes 2, 3, 4, and 8.
For details about VCCPD pin sharing for VCCIO groups, refer to the I/O
Design Guidelines section in the I/O Features in Arria V Devices chapter.
VCCBAT
PCG-01016-1.4
Copyright © 2015 Altera Corp.
Power
Battery back-up power supply for design security volatile
key register.
Connect this pin to a non-volatile battery power source in the range of
1.2V - 3.0V when using design security volatile key. In this case, do not
connect this pin to a volatile power source on the board. 3.0V is the typical
battery power selected for this supply. When not using the volatile key, tie
this to a 1.5V, 2.5V or 3.0V supply. Arria V devices will not exit POR if
VCCBAT is not powered up.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
GND
Ground
Device ground pins.
You must connect all GND pins to the board ground plane.
VREF[3,4,7,8][A,B,C,D]N0
Power
Input reference voltage for each I/O bank. If a bank uses a
voltage-referenced I/O standard, then these pins are used
as the voltage-reference pins for the bank.
If VREF pins are not used, you should connect them to either the VCCIO
in the bank in which the pin resides or GND. Decoupling depends on the
design decoupling requirements of the specific board. See Note 2 and 8.
Transceiver Pins (See Notes 4 through 10)
VCCHIP_L
Power
PCIe Hard IP digital power supply, specific to the left (L)
side the device.
VCCHIP is 0.85V. When VCCHIP is used, tie it to the same plane as VCC.
When you do not use the device's HIP, you may connect VCCHIP pins to
GND. For data rates less than 6.5Gbps and with a proper isolation filter,
you may source VCCR_GXB and VCCT_GXB from the same regulator as
VCC, VCCHIP, and VCCHSSI. Decoupling for these pins depends on the
design decoupling requirements of the specific board. See Notes 2, 3, 4,
and 5.
VCCHSSI_[L,R]
Power
PCS power supply, specific to the left (L) side or right (R)
side of the device.
VCCHSSI is 0.85V. When VCCHSSI is used, tie it to the same plane as
VCC. When you do not use any of the transceivers on one side of the
device, you may tie VCCHSSI on that side of the device to GND. For data
rates less than 6.5Gbps and with a proper isolation filter, you may source
VCCR_GXB and VCCT_GXB from the same regulator as VCC, VCCHIP,
and VCCHSSI. Decoupling for these pins depends on the design
decoupling requirements of the specific board. See Notes 2, 3, 4, and 5.
PCG-01016-1.4
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
VCCR_GXB[L,R][0:2]
Power
Analog power, receiver, specific to the left (L) side or right
(R) side of the device.
Connect VCCR_GXB pins to a linear or low noise switching regulator. Set
VCCR_GXB and VCCT_GXB to either 1.0V, or to match the VCC of the
device.
Set VCCR_GXB and VCCT_GXB to 1.0V when:
• ATX PLL is used, the CMU data rate is > 6.5Gbps, or
• DFE/AEQ/EyeQ are used, or
• Provisions are made to use any of the above capabilities in the future
If the above features are not used, and when there is no future provision
to use them, you can set VCCR_GXB and VCCT_GXB to the same level
as VCC or to 1.0V.
Ensure that the choice you make for VCCR_GXB and VCCT_GXB tracks
the choice made for VCCA_GXB as follows:
• VCCR_GXB/VCCT_GXB = VCC and VCCA_GXB = 2.5V, or
• VCCR_GXB/VCCT_GXB = 1.0V and VCCA_GXB = 3.0V
For data rates less than 6.5Gbps and ATX PLL, DFE, AEQ, or EyeQ is not
used, you may tie these pins to the same regulator as VCC, VCCHIP and
VCCHSSI with a proper isolation filter.
For data rates greater than 10.3Gbps and DFE is used, you must connect
VCCR_GXB and VCCT_GXB to 1.05V +/-20mV.
For data rates less than 12.5Gbps these pins may share the same power
rail as VCCT_GXB.
However, for better performance you should isolate VCCR_GXB and
VCCT_GXB by at least 60dB for a 1MHz to 100MHz bandwidth.
Decoupling for these pins depends on the design decoupling requirements
of the specific board design. See Notes 2, 3, 4, 5, 7, and 10.
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PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
VCCT_GXB[L,R][0:2]
Power
Analog power, transmitter, specific to the left (L) side or
right (R) side of the device.
Connect VCCT_GXB pins to a linear or low noise switching regulator. Set
VCCR_GXB and VCCT_GXB to either 1.0V, or to match the VCC of the
device.
Set VCCR_GXB and VCCT_GXB to 1.0V when:
• ATX PLL is used, the CMU data rate is > 6.5Gbps, or
• DFE/AEQ/EyeQ are used, or
• Provisions are made to use any of these capabilities in the future
If the above features are not used, and when there is no future provision to
use them, you can set VCCR_GXB and VCCT_GXB to the same level as
VCC, or to 1.0V.
Ensure that the choice you make for VCCR_GXB and VCCT_GXB tracks
the choice made for VCCA_GXB as follows:
• VCCR_GXB/VCCT_GXB = VCC and VCCA_GXB = 2.5V, or
• VCCR_GXB/VCCT_GXB = 1.0V and VCCA_GXB = 3.0V
For data rates less than 6.5Gbps and ATX PLL, DFE, AEQ, or EyeQ is not
used, you may tie these pins to the same regulator as VCC, VCCHIP and
VCCHSSI with a proper isolation filter.
For data rates >10.3Gbps and DFE is used, you must connect
VCCT_GXB and VCCR_GXB to 1.05V +/-20mV.
For data rates less than 12.5Gbps these pins may share the same power
rail as VCCR_GXB.
However, for better performance you should isolate VCCR_GXB and
VCCT_GXB by at least 60dB for a 1MHz to 100MHz bandwidth.
Decoupling for these pins depends on the design decoupling requirements
of the specific board design. See Notes 2, 3, 4, 5, 7, and 10.
VCCH_GXB[L,R][0:2]
PCG-01016-1.4
Copyright © 2015 Altera Corp.
Power
Analog power, block level TX buffers.
Connect VCCH_GXB to a 1.5V linear or low noise switching regulator. You
may source these pins from the same regulator as VCCPT, VCCD_FPLL
and VCCBAT. Decoupling for these pins depends on the design
decoupling requirements of the specific board design. See Notes 2, 3, 4,
5, 7, and 10.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
VCCA_GXB[L,R][0:2]
Power
Analog power, TX driver, RX receiver, CDR, specific to the
left (L) side or right (R) side of the device.
Use a linear or low noise switching regulator to supply power to this power
plane. Set VCCA_GXB to either 2.5V or 3.0V.
Set VCCA_GXB to 3.0V when:
• ATX PLL is used, the CMU data rate is > 6.5Gbps, or
• DFE/AEQ/EyeQ are used, or
• Provisions are made to use any of these capabilities in the future
If the above features are not used, and when there is no future provision to
use them, you can set VCCA_GXB to 2.5V or 3.0V
Ensure that the choice you make for VCCA_GXB must track the choice
you make for VCCR_GXB and VCCT_GXB as follows:
• VCCR_GXB/VCCT_GXB = VCC and VCCA_GXB = 2.5V, or
• VCCR_GXB/VCCT_GXB = 1.0V and VCCA_GXB = 3.0V
This power rail may be shared with VCCA_FPLL and VCC_AUX. With a
proper isolation filter you may source these pins from the same regulator
as VCCIO, VCCPD and VCCPGM when each of these power supplies
require 2.5V.
Decoupling depends on the design decoupling requirements of the specific
board design. See Notes 2, 3, 5, 7, and 10.
GXB_RX_[L,R][0:17]p,
Input
High speed positive differential receiver channels. Specific
to the left (L) side or right (R) side of the device.
These pins may be AC-coupled or DC-coupled when used. Connect all
unused GXB_RXp/GXB_REFCLKp pins directly to GND or VCCR_GXB or
VCCT_GXB. See Note 9.
Input
High speed negative differential receiver channels. Specific
to the left (L) side or right (R) side of the device.
These pins may be AC-coupled or DC-coupled when used. Connect all
unused GXB_RXn/GXB_REFCLKn pins directly to GND. See Note 9.
GXB_TX_[L,R][0:17]p
Output
High speed positive differential transmitter channels.
Specific to the left (L) side or right (R) side of the device.
Leave all unused GXB_TXp pins floating.
GXB_TX_[L,R][0:17]n
Output
High speed negative differential transmitter channels.
Specific to the left (L) side or right (R) side of the device.
Leave all unused GXB_TXn pins floating.
REFCLK_ [0:5] [L,R]p
Input
High speed differential reference clock positive receiver
channels, specific to the left (L) side or right (R) side of the
device.
In the PCI Express configuration, DC-coupling is allowed on the REFCLK
if the selected REFCLK I/O standard is HCSL.
GXB_REFCLK[L,R][0:17]p
GXB_RX_[L,R][0:17]n,
GXB_REFCLK[L,R][0:17]n
These pins must be AC-coupled if the selected REFCLK I/O standard is
not HCSL. See Note 9 for non-HCSL I/O standard.
Connect all unused pins directly to GND.
PCG-01016-1.4
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Arria V GZ Pin Name
Pin Type (1st
and 2nd
Function)
Pin Description
Connection Guidelines
REFCLK_ [0:5] [L,R]n
Input
High speed differential reference clock complement,
complementary receiver channel, specific to the left (L) side
or right (R) side of the device.
In the PCI Express configuration, DC-coupling is allowed on the REFCLK
if the selected REFCLK I/O standard is HCSL.
These pins must be AC-coupled if the selected REFCLK I/O standard is
not HCSL. See Note 9 for non-HCSL I/O standard.
Connect all unused pins directly to GND.
PCG-01016-1.4
Copyright © 2015 Altera Corp.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Notes to Arria V GZ Pin Connection Guidelines
Altera provides these guidelines only as recommendations. It is the responsibility of the designer to apply simulation results to the design to verify proper
device functionality.
1.
2.
These pin connection guidelines are created based on the Arria V GZ device family.
Capacitance values for the power supply should be selected after consideration of the amount of power they need to supply over the frequency of operation of the particular circuit
being decoupled. A target impedance for the power plane should be calculated based on current draw and voltage droop requirements of the device/supply. The power plane should
then be decoupled using the appropriate number of capacitors. On-board capacitors do not decouple higher than 100 MHz because “Equivalent Series Inductance” of the mounting of
the packages. Proper board design techniques such as interplane capacitance with low inductance should be considered for higher frequency decoupling.
3. Use the Arria V Early Power Estimator to determine the current requirements for VCC and other power supplies.
4. These supplies may share power planes across multiple Arria V devices.
5. Examples 1 - 3 and Figures 1 - 3 illustrate power supply sharing guidelines that are data rate dependent.
•
Example 1 and Figure 1, ""Power Regs <= 6.5Gbps"", show recommendations for designs using the Arria V GZ transceivers that will not exceed 6.5Gbps option 1.
•
Example 2 and Figure 2, ""Power Regs <= 6.5Gbps"", show recommendations for designs using the Arria V GZ transceivers that will not exceed 6.5Gbps option 2.
•
Example 3 and Figure 3, ""Power Regs > 6.5Gbps <= 12.5Gbps"", show recommendations for designs using the Arria V GZ transceivers that are between 6.5Gbps and
12.5Gbps.
6. Power pins should not share breakout vias from the BGA. Each ball on the BGA needs to have its own dedicated breakout via. VCC must not share breakout vias.
7. Low Noise Switching Regulator - defined as a switching regulator circuit encapsulated in a thin surface mount package containing the switch controller, power FETs, inductor, and
other support components. The switching frequency is usually between 800kHz and 1MHz and has fast transient response. The switching frequency range is not an Altera
requirement. However, Altera does require the Line Regulation and Load Regulation meet the following specifications:
•
Line Regulation < 0.4%
•
Load Regulation < 1.2%
You have the option to use a linear regulator depending on your design and your system’s power and thermal budget considerations.
8. The number of modular I/O banks on Arria V GZ devices depends on the device density. For the indexes available for a specific device, please refer to the I/O Bank section
in the Arria V device handbook.
9. For AC-coupled links, the AC-coupling capacitor can be placed anywhere along the channel. PCI Express protocol requires the AC-coupling capacitor to be placed on the transmitter
side of the interface that permits adapters to be plugged and unplugged.
10. All transceiver power pins on the same side of the device must be connected either to the required supply or to GND. When ALL transceiver channels on the same side are unused,
you have the option to connect all of the transceiver power pins on the same side of the device to GND or to the required supply.
11. For DQS, DQSn, and DQ groups, group 31B to group 42B, group 3T and 4T, and group 29T to group 40T are unavailable.
12. For CQ and CQn groups, group 2T is unavailable.
PCG-01016-1.4
Copyright © 2015 Altera Corp.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Power Reqs ≤ 6.5Gbps Option 1
Example 1. Power Supply Sharing Guidelines for Arria V GZ Transceivers with Data Rates <= 6.5Gbps, and all of the following conditions are true:
ATX PLL is not being used, DFE/AEQ/EyeQ are not being used, and no provision is being made to use any of these features in the future (Option 1)
Example Requiring 3 Power Regulators
Power
Pin Name
Regulator
Count
Voltage
Level (V)
Supply
Tolerance
Power
Source
Regulator
Sharing
Notes
Share
VCC, VCCHIP, and VCCHSSI must share regulators. If not using HIP, VCCHIP may
be tied to GND. Also, when you do not use any of the transceivers on one side of the
device, VCCHSSI on that side of the device may be tied to GND.
VCC
VCCHIP_L
VCCHSSI_[L,R]
1
0.85
± 30mV
VCCR_GXB[L,R]
Switcher
(*)
Isolate
VCCT_GXB[L,R]
VCCIO
VCCPD
VCC_AUX
Share
if 2.5V
Varies
VCCPGM
2
VCCA_GXB[L,R]
± 5%
Switcher (*)
2.5
Isolate
VCCA_FPLL
VCCPT
VCCH_GXB[L,R]
VCCD_FPLL
3
1.5
± 50mV
Linear or
Switcher (*)
Share
May be able to share VCCR_GXB and VCCT_GXB with VCC, VCCHIP, and
VCCHSSI with a proper isolation filter.
If all of these supplies require 2.5V and the regulator selected satisfies the power
specifications, these supplies may all be tied in common. However, for any other
voltage you will require as many regulators as there are variations of supplies in your
specific design. VCCPD must be greater than or equal to VCCIO.
Use the EPE tool to assist in determining the power required for your specific design.
May be able to share VCCA_GXB, VCC_AUX, and VCCA_FPLL with the same
regulator as VCCIO, VCCPD, and VCCPGM when all power rails require 2.5V, but
only with a proper isolation filter. Depending on the regulator capabilities, this supply
may be shared with multiple Arria V GZ devices.
If not sharing a regulator, the VCCPT supply should not exceed a tolerance of ±
50mV, however the other power supplies in this group can tolerate ± 5%. Depending
on the regulator capabilities this supply may be shared with multiple Arria V GZ
devices.
VCCBAT
(*) When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
Use the EPE (Early Power Estimation) tool to assist in determining the power required for your specific design.
Each board design requires its own power analysis to determine the required power regulators needed to satisfy the specific board design requirements. An example block diagram using the
Arria V GZ transceiver-based device with data rates less than or equal to 6.5Gbps is provided in Figure 1.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
PCG-01016-1.4
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Figure 1. Example Power Supply Block Diagram for Arria V GZ Transceivers with Data Rates <= 6.5Gbps, and all of the following conditions are true: ATX PLL is not being used,
DFE/AEQ/EyeQ are not being used, and no provision is being made to use any of these features in the future (Option 1)
*When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
PCG-01016-1.4
Copyright © 2015 Altera Corp.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Power Reqs ≤ 6.5Gbps Option 2
Example 2. Power Supply Sharing Guidelines for Arria V GZ Transceivers with Data Rates <= 6.5Gbps, and at least one of the following conditions is true:
ATX PLL is being used, DFE/AEQ/EyeQ are being used, or provision is being made to use any of these features in the future (Option 2)
Example Requiring 5 Power Regulators
Power
Pin Name
Regulator
Count
Voltage
Level (V)
Supply
Tolerance
Power
Source
Regulator
Sharing
Share
Isolate
VCC
VCCHIP_L
1
0.85
± 30mV
Switcher
(*)
2
1.0
± 30mV
Linear or
Switcher (*)
VCCHSSI_[L,R]
VCCR_GXB[L,R]
VCCT_GXB[L,R]
VCCIO
Varies
3
± 5%
Switcher (*)
VCC_AUX
VCCA_FPLL
VCCA_GXB[L,R]
Share
if 2.5V
2.5
4
3.0
± 5%
Linear or
Switcher (*)
VCCD_FPLL
5
1.5
± 50mV
Linear or
Switcher (*)
May be able to share VCC_AUX and VCCA_FPLL with the same regulator as
VCCIO, VCCPD, and VCCPGM when all power rails require 2.5V, but only with a
proper isolation filter. Depending on the regulator capabilities this supply may be
shared with multiple Arria V GZ devices.
Isolate
VCCPT
VCCH_GXB[L,R]
VCC, VCCHIP, and VCCHSSI must share regulators. If not using HIP, VCCHIP may
be tied to GND. Also, when you are not using any of the transceivers on one side of
the device, VCCHSSI on that side of the device may be tied to GND.
If all of these supplies require 2.5V and the regulator selected satisfies the power
specifications then these supplies may all be tied in common. However, for any other
voltage you will require as many regulators as there are variations of supplies in your
specific design. VCCPD must be greater than or equal to VCCIO.
Use the EPE tool to assist in determining the power required for your specific design.
VCCPD
VCCPGM
Notes
Share
If not sharing a regulator, the VCCPT supply should not exceed a tolerance of ±
50mV, however the other power supplies in this group can tolerate ± 5%. Depending
on the regulator capabilities this supply may be shared with multiple Arria V GZ
devices.
VCCBAT
(*) When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
Use the EPE (Early Power Estimation) tool to assist in determining the power required for your specific design.
Each board design requires its own power analysis to determine the required power regulators needed to satisfy the specific board design requirements. An example block diagram using the
Arria V GZ transceiver-based device with data rates less than or equal to 6.5Gbps is provided in Figure 2.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
PCG-01016-1.4
Copyright © 2015 Altera Corp.
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Arria V GZ Device Family Pin Connection Guidelines
PCG-01016-1.4
Figure 2. Example Power Supply Block Diagram for Arria V GZ Transceivers with Data Rates <= 6.5Gbps, and at least one of the following conditions is true:
ATX PLL is being used, DFE/AEQ/EyeQ are being used, or provision is being made to use any of these features in the future (Option 2)
*When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
PCG-01016-1.4
Copyright © 2015 Altera Corp.
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PCG-01016-1.4
Power Regs > 6.5Gbps ≤ 12.5Gbps
Example 3. Power Supply Sharing Guidelines for Arria V GZ Transceivers with Data Rates Between 6.5Gbps and 12.5Gbps
Example Requiring 5 Power Regulators
Power
Pin Name
Regulator
Count
Voltage
Level (V)
Supply
Tolerance
Power
Source
± 30mV
Switcher
(*)
Regulator
Sharing
VCC
VCCHIP_L
1
0.85
VCCHSSI_[L,R]
Share
VCCIO
VCCPD
Share
if 2.5V
Varies
VCCPGM
2
± 5%
VCC_AUX
Switcher
(*)
2.5
VCCA_FPLL
3
1.0
or 1.05 (**)
Share
Although VCCR_GXB and VCCT_GXB may share a regulator, for a better performance
and to meet PCIe Gen. 3 jitter specifications, these power supplies should be isolated
from each other with at least 60dB of isolation for a 1MHz to 100MHz bandwidth.
± 30mV
or ± 20mV (**)
Linear or
Switcher
(*)
VCCD_FPLL
Share
Isolate
4
1.5
± 50mV
Linear or
Switcher
(*)
5
3.0
± 5%
Linear or
Switcher
(*)
VCCBAT
VCCA_GXB[L,R]
If all of these supplies require 2.5V and the regulator selected satisfies the power
specifications then these supplies may all be tied in common. However, for any other
voltage you will require as many regulators as there are variations of supplies in your
specific design. VCCPD must be greater than or equal to VCCIO.
Use the EPE tool to assist in determining the power required for your specific design.
Isolate
VCCPT
VCCH_GXB[L,R]
VCC, VCCHIP, and VCCHSSI must share regulators. If not using HIP, VCCHIP may be
tied to GND. Also, when you are not using any of the transceivers on one side of the
device, VCCHSSI on that side of the device may be tied to GND.
May be able to share VCC_AUX and VCCA_FPLL with the same regulator as VCCIO,
VCCPD, and VCCPGM when all power rails require 2.5V, but only with a proper
isolation filter. Depending on the regulator capabilities this supply may be shared with
multiple Arria V GZ devices.
VCCR_GXB[L,R]
VCCT_GXB[L,R]
Notes
If not sharing a regulator, the VCCPT supply should not exceed a tolerance of ± 50mV,
however the other power supplies in this group can tolerate ± 5%. Depending on the
regulator capabilities this supply may be shared with multiple Arria V GZ devices.
(*) When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
(**) When data rate is >10.3Gbps and DFE is used.
Each board design requires its own power analysis to determine the required power regulators needed to satisfy the specific board design requirements. An example block diagram using the
Arria V GZ transceiver-based device with data rates between 6.5Gbps and 12.5Gbps is provided in Figure 3.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
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Arria V GZ Device Family Pin Connection Guidelines
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Figure 3. Example Power Supply Block Diagram for Arria V GZ Transceivers with Data Rates Between 6.5Gbps and 12.5Gbps
*When using a switcher to supply these voltages the switcher must be a low noise switcher as defined in note 7.
***Although VCCR_GXB and VCCT_GXB may share a regulator, for better performance these power supplies should be isolated from each other with at least 60dB of
isolation for 1MHz o 100MHz bandwidth.
Refer to power up sequence recommendation in Arria V Devices Handbook: Power Managament in Arria V Devices.
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Arria V GZ Device Family Pin Connection Guidelines
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Revision History
Revision
Description of Changes
Date
1.0
Initial release.
11/19/2012
1.1
- Added note (4) to VCC, VCCD_FPLL, VCCIO[1:8], VCCPGM, VCCPD[1:8], VCCHIP_L, and VCCHSSI_[L,R] pins.
- Added note (5) to VCCA_GXB[L,R][0:2], VCCH_GXB[L,R][0:2], VCCT_GXB[L,R][0:2], VCCR_GXB[L,R][0:2], VCCHIP_L, and
VCCHSSI_[L,R] pins.
- Added note (11) to DQS, DQSn, and DQ pins.
- Added note (12) to CQ and CQn pins.
- Updated notes (7) and (10) in the Pin Connection Guidelines.
- Updated the connection guidelines to nIO_PULLUP, REFCLK_[L,R][0:5]p, REFCLK_[L,R][0:5]n, VCCR_GXB[L,R][0:2], and
VCCT_GXB[L,R][0:2] pins.
- Moved the RREF_[T,B][L,R] pin to the Reference Pins section.
4/19/2013
1.2
- Updated the pin description of the DIFFIO_RX_[T,B][#:#]p and DIFFIO_RX_[T,B][#:#]n pins.
- Updated the connection guidelines to the TMS, TDI, TRST, REFCLK_ [0:5] [L,R]p, and REFCLK_ [0:5] [L,R]n pins.
- Updated note (10) in the Pin Connection Guidelines.
10/7/2013
1.3
-This document is no longer preliminary.
-Updated the connection guidelines of the VCCBAT pin.
-Updated the connection guidelines of REFCLK_ [0:5] [L,R]p and REFCLK_ [0:5] [L,R]n pins.
11/14/2014
1.4
-Updated content in the Disclaimer section.
-Added links referring to Arria V Device Handbook: Power Management in Arria V Devices for all power sharing guidelines tables and
figures.
PCG-01016-1.4
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5/19/2015
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