VCC, VCCP, and VCCERAM must operate at the same voltage level, should share the same power plane on the board, and be sourced from the same regulator unless the SmartVID feature is used, as described below.

You can operate -1 and -2 speed grade devices at 0.9V or 0.95V typical value. You can operate -3 speed grade device only at 0.9V typical value. Operating at 0.95V results in higher core performance and higher power consumption. For more information about the performance and power consumption, refer to the Intel® Quartus® Prime software timing reports and Intel® Arria® 10 Early Power Estimator (EPE).

For details about the recommended operating conditions, refer to the Electrical Characteristics in the device datasheet.

Use the Intel® Arria® 10 Early Power Estimator (EPE) to determine the current requirements for VCCP and other power supplies. Decoupling for these pins depends on the decoupling requirements of the specific board. See Notes 2, 3, 4, 5, 6, and 10.

VCC, VCCP, and VCCERAM must operate at the same voltage level, should share the same power plane on the board, and be sourced from the same regulator unless the SmartVID feature is used, as described below.

You can operate -1 and -2 speed grade devices at 0.9V or 0.95V typical value. You can operate -3 speed grade device only at 0.9V typical value. Operating at 0.95V results in higher core performance and higher power consumption. For more information about the performance and power consumption, refer to the Intel® Quartus® Prime software timing reports and Intel® Arria® 10 Early Power Estimator (EPE).

For details about the recommended operating conditions, refer to the Electrical Characteristics in the device datasheet.

Use the Intel® Arria® 10 Early Power Estimator (EPE) to determine the current requirements for VCC and other power supplies. Decoupling for these pins depends on the decoupling requirements of the specific board. See Notes 2, 3, 4, 5, 6, and 10.

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 required by the specified bank. When these pins require the same voltage level as VCCPGM, you have the option to tie them to the same regulator as VCCPGM. Not all I/O banks support 2.5V or 3.0V supplies. Not all devices support 3.0V I/O standard. For more details, refer to the I/O and High Speed I/O in Intel® Arria® 10 Devices.

For the power rail sharing, refer to the Power Supply Sharing Guidelines for Intel® Arria® 10 Devices.

See Notes 2, 3, 4, 8, and 10.

Connect these pins to a 1.2V, 1.5V, or 1.8V power supply. When dual-purpose configuration pins are used for configuration, tie VCCIO of the bank to the same regulator as VCCPGM, ranging from 1.2V, 1.5V, or 1.8V. When you do not use dual-purpose configuration pins for configuration, connect VCCIO to 1.2V, 1.25V, 1.35V, 1.5V, or 1.8V.

When these pins require the same voltage level as VCCIO, you have the option to tie them to the same regulator as VCCIO.

Provide a minimum decoupling of 47nF for the VCCPGM power rail near the VCCPGM pin.

For the power rail sharing, refer to the Power Supply Sharing Guidelines for Intel® Arria® 10 Devices.

See Notes 2, 3, 4, and 10.

Connect all VCCERAM pins to a 0.9V or 0.95V linear or low noise switching power supply.

You have the option to share VCCL_HPS with VCCERAM plane if the VCCL_HPS voltage is at the same level for Intel® Arria® 10 SX devices.

VCC, VCCP, and VCCERAM must operate at the same voltage level, should share the same power plane on the board, and be sourced from the same regulator. When sharing the same regulator for VCCERAM, VCC, and VCCP, the SmartVID feature is not available. If you use the SmartVID feature, then VCC and VCCP need to be sourced by a dedicated regulator that is separate from the VCCERAM regulator.

When you use the SmartVID feature, VCCERAM must be equal to 0.9V.

See Notes 2, 3, 7, and 10.

When using the design security volatile key, connect this pin to a non-volatile battery power source in the range of 1.2V - 1.8V.

When not using the volatile key, tie this pin to a supply ranging from more than 1.5V to 1.8V. If 1.8V is selected when the design security key is unused, you have the option to source this pin from the same regulator as VCCPT.

This pin must be properly powered as per the recommended voltage range as the POR circuitry of the Intel® Arria® 10 devices monitoring VCCBAT.

Provide a minimum decoupling of 47nF for the VCCBAT power rail near the VCCBAT pin.

For the power rail sharing, refer to the Power Supply Sharing Guidelines for Intel® Arria® 10 Devices.

If VREF pins are not used, connect them to either the VCCIO in the bank in which the pin resides or GND. See Notes 2, 8, 10, and 11.

The following lists the four pairs of VREF pins in the RF40 package of the Intel® Arria® 10 GX devices that must be connected to the same voltage source on the board:

• VREFB2AN0 and VREFB2FN0
• VREFB2KN0 and VREFB2LN0
• VREFB3AN0 and VREFB3BN0
• VREFB3GN0 and VREFB3HN0

VCCLSENSE and GNDSENSE are differential remote sense pins for the VCC power. Connect your regulators’ differential remote sense lines to the respective VCCLSENSE and GNDSENSE pins. This compensates for the DC IR drop associated with the PCB and device package from the VCC power. Route these connections as differential pair traces and keep them isolated from any other noise source.

Connect VCCLSENSE and GNDSENSE lines to the regulator’s remote sense inputs when I_CC current >30A or when the SmartVID feature is used.

VCCLSENSE and GNDSENSE line connections are optional if I_CC current <=30A and the SmartVID feature is not used. However, Intel® recommends connecting the VCCLSENSE and GNDSENSE for regulators that support remote sense line feature.

If you do not use the VCCLSENSE and GNDSENSE pins, leave the VCCLSENSE and GNDSENSE pins unconnected.