Intel Agilex® 7 General-Purpose I/O User Guide: F-Series and I-Series

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ID 683780
Date 4/19/2023
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Document Table of Contents
Document Table of Contents x
1. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O Overview 2. Intel Agilex® 7 F-Series and I-Series GPIO Banks 3. Intel Agilex® 7 F-Series and I-Series HPS I/O Banks 4. Intel Agilex® 7 F-Series and I-Series SDM I/O Banks 5. Intel Agilex® 7 F-Series and I-Series I/O Troubleshooting Guidelines 6. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O IPs 7. Programmable I/O Features Description 8. Documentation Related to the Intel Agilex® 7 General-Purpose I/O User Guide: F-Series and I-Series 9. Document Revision History for the Intel Agilex® 7 General-Purpose I/O User Guide: F-Series and I-Series
1. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O Overview x
1.1. Package Selection and I/O Vertical Migration Support 1.2. Types of I/O Banks
2. Intel Agilex® 7 F-Series and I-Series GPIO Banks x
2.1. GPIO Bank Overview 2.2. GPIO Features 2.3. GPIO Implementation Guide 2.4. GPIO Termination 2.5. GPIO Design Guidelines 2.6. GPIO Simulation
2.1. GPIO Bank Overview x
2.1.1. GPIO Bank Structure 2.1.2. GPIO Buffers and Registers
2.2. GPIO Features x
2.2.1. Supported I/O Standards for GPIO Banks 2.2.2. GPIO Buffer Behavior 2.2.3. Programmable I/O Element Features for the GPIO Bank
2.2.3. Programmable I/O Element Features for the GPIO Bank x
2.2.3.1. Guidelines: Programmable Output Slew Rate Control 2.2.3.2. Guidelines: Programmable Open-Drain Output 2.2.3.3. Guidelines: Programmable Bus-Hold 2.2.3.4. Guidelines: Programmable Pull-Up Resistor 2.2.3.5. Guidelines: Programmable De-Emphasis
2.3. GPIO Implementation Guide x
2.3.1. I/O Assignments with the Intel® Quartus® Prime Assignment Editor 2.3.2. Assigning Pin I/O Standards in the Intel® Quartus® Prime Pin Planner
2.3.1. I/O Assignments with the Intel® Quartus® Prime Assignment Editor x
2.3.1.1. Assigning Pin I/O Standards in the Intel® Quartus® Prime Assignment Editor 2.3.1.2. Assigning Programmable IOE Features in the Intel® Quartus® Prime Assignment Editor 2.3.1.3. GPIO Programmable IOE Features Assignment Names and Settings
2.4. GPIO Termination x
2.4.1. Single-Ended I/O Termination in F-Series and I-Series Devices 2.4.2. True Differential Signaling I/O Termination
2.4.1. Single-Ended I/O Termination in F-Series and I-Series Devices x
2.4.1.1. Single-Ended I/O Standard OCT Termination 2.4.1.2. OCT Calibration Block 2.4.1.3. Single-Ended I/O Standards External Termination 2.4.1.4. Single-Ended I/O Termination Implementation Guide
2.4.1.1. Single-Ended I/O Standard OCT Termination x
2.4.1.1.1. RS OCT 2.4.1.1.2. RT OCT 2.4.1.1.3. Dynamic OCT
2.4.1.4. Single-Ended I/O Termination Implementation Guide x
2.4.1.4.1. Configuring OCT Using the Assignment Editor 2.4.1.4.2. OCT Features Assignment Names and Settings
2.4.2. True Differential Signaling I/O Termination x
2.4.2.1. True Differential Signaling I/O Standard OCT Termination 2.4.2.2. True Differential Signaling I/O Standard External Termination
2.4.2.1. True Differential Signaling I/O Standard OCT Termination x
2.4.2.1.1. Configuring Differential Input RD OCT Using the Assignment Editor 2.4.2.1.2. Guidelines: Differential Input RD OCT
2.5. GPIO Design Guidelines x
2.5.1. VREF Sources and VREF Pins 2.5.2. I/O Standards Implementation Based on VCCIO_PIO Voltages 2.5.3. OCT Calibration Block Requirement 2.5.4. I/O Pins Placement Requirements 2.5.5. I/O Standard Selection and I/O Bank Supply Compatibility Check 2.5.6. Simultaneous Switching Noise 2.5.7. Special Pins Requirement 2.5.8. External Memory Interface Pin Placement Requirements 2.5.9. HPS Shared I/O Requirements 2.5.10. Clocking Requirements 2.5.11. SDM Shared I/O Requirements 2.5.12. Unused Pins 2.5.13. Voltage Setting for Unused GPIO Banks 2.5.14. GPIO Pins During Power Sequencing 2.5.15. Drive Strength Requirement for GPIO Input Pins 2.5.16. Maximum DC Current Restrictions 2.5.17. 1.2 V I/O Interface Voltage Level Compatibility 2.5.18. GPIO Pins for the Avalon® Streaming Interface Configuration Scheme 2.5.19. Maximum True Differential Signaling Receiver Pairs Per I/O Lane
2.6. GPIO Simulation x
2.6.1. IBIS Models 2.6.2. HSPICE* Models 2.6.3. Net Length Reports
3. Intel Agilex® 7 F-Series and I-Series HPS I/O Banks x
3.1. HPS I/O Bank Overview 3.2. HPS I/O Features 3.3. HPS I/O Implementation Guide 3.4. HPS I/O Design Guidelines 3.5. HPS I/O Simulation
3.2. HPS I/O Features x
3.2.1. Supported I/O Standards for HPS I/O Banks 3.2.2. HPS I/O Buffer Behavior 3.2.3. Programmable I/O Element Features for the HPS I/O Bank
3.3. HPS I/O Implementation Guide x
3.3.1. Configuring Open Drain Feature for the HPS I/O 3.3.2. I/O Assignments with the Intel® Quartus® Prime Assignment Editor 3.3.3. Assigning Pin I/O Standards in the Intel® Quartus® Prime Pin Planner
3.3.2. I/O Assignments with the Intel® Quartus® Prime Assignment Editor x
3.3.2.1. Assigning Programmable IOE Features in the Intel® Quartus® Prime Assignment Editor 3.3.2.2. HPS I/O Programmable IOE Features Assignment Names and Settings
3.4. HPS I/O Design Guidelines x
3.4.1. Unused Pins 3.4.2. HPS I/O Pins During Power Sequencing 3.4.3. HPS Shared I/O Requirements
3.5. HPS I/O Simulation x
3.5.1. HPS IBIS Models 3.5.2. Net Length Reports
4. Intel Agilex® 7 F-Series and I-Series SDM I/O Banks x
4.1. SDM I/O Bank Overview 4.2. SDM I/O Features 4.3. SDM I/O Design Guidelines 4.4. SDM I/O Simulation
4.2. SDM I/O Features x
4.2.1. Supported I/O Standards for SDM I/O Banks 4.2.2. SDM I/O Buffer Behavior 4.2.3. I/O Standards and Features for Configuration Pins
4.3. SDM I/O Design Guidelines x
4.3.1. Unused Pins 4.3.2. SDM I/O Pins During Power Sequencing
4.4. SDM I/O Simulation x
4.4.1. SDM IBIS Models 4.4.2. Net Length Reports
6. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O IPs x
6.1. GPIO Intel® FPGA IP 6.2. OCT Intel® FPGA IP
6.1. GPIO Intel® FPGA IP x
6.1.1. Release Information for GPIO Intel® FPGA IP 6.1.2. Generating the GPIO Intel® FPGA IP 6.1.3. GPIO Intel® FPGA IP Parameter Settings 6.1.4. GPIO Intel® FPGA IP Interface Signals 6.1.5. GPIO Intel® FPGA IP Architecture 6.1.6. Verifying Resource Utilization and Design Performance 6.1.7. GPIO Intel® FPGA IP Timing 6.1.8. GPIO Intel® FPGA IP Design Examples
6.1.2. Generating the GPIO Intel® FPGA IP x
6.1.2.1. Intel® FPGA IP Generation Output
6.1.3. GPIO Intel® FPGA IP Parameter Settings x
6.1.3.1. Guideline: Swap datain_h and datain_l Ports in Migrated IP
6.1.4. GPIO Intel® FPGA IP Interface Signals x
6.1.4.1. Shared Signals 6.1.4.2. Data Bit-Order for Data Interface 6.1.4.3. Input and Output Bus High and Low Bits 6.1.4.4. Data Interface Signals and Corresponding Clocks
6.1.5. GPIO Intel® FPGA IP Architecture x
6.1.5.1. GPIO Intel® FPGA IP Data Paths 6.1.5.2. Register Packing
6.1.5.1. GPIO Intel® FPGA IP Data Paths x
6.1.5.1.1. Input Path 6.1.5.1.2. Output and Output Enable Paths
6.1.7. GPIO Intel® FPGA IP Timing x
6.1.7.1. Timing Components 6.1.7.2. Delay Elements 6.1.7.3. Timing Analysis 6.1.7.4. Timing Closure Guidelines
6.1.7.3. Timing Analysis x
6.1.7.3.1. Single Data Rate Input Register 6.1.7.3.2. Full-Rate or Half-Rate DDIO Input Register 6.1.7.3.3. Single Data Rate Output Register 6.1.7.3.4. Full-Rate or Half-Rate DDIO Output Register
6.1.8. GPIO Intel® FPGA IP Design Examples x
6.1.8.1. GPIO Intel® FPGA IP Synthesizable Intel® Quartus® Prime Design Example 6.1.8.2. GPIO Intel® FPGA IP Simulation Design Example
6.2. OCT Intel® FPGA IP x
6.2.1. Release Information 6.2.2. Generating the OCT Intel® FPGA IP 6.2.3. OCT Intel® FPGA IP Parameter Settings 6.2.4. OCT Intel® FPGA IP Signals 6.2.5. QSF Assignments 6.2.6. OCT Intel® FPGA IP Architecture 6.2.7. OCT Intel® FPGA IP Design Example
6.2.2. Generating the OCT Intel® FPGA IP x
6.2.2.1. Intel® FPGA IP Generation Output
6.2.7. OCT Intel® FPGA IP Design Example x
6.2.7.1. Generating the Intel® Quartus® Prime Design Example
7. Programmable I/O Features Description x
7.1. Programmable Pre-Emphasis 7.2. Programmable De-Emphasis 7.3. Programmable Differential Output Voltage
1. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O Overview
2. Intel Agilex® 7 F-Series and I-Series GPIO Banks
3. Intel Agilex® 7 F-Series and I-Series HPS I/O Banks
4. Intel Agilex® 7 F-Series and I-Series SDM I/O Banks
5. Intel Agilex® 7 F-Series and I-Series I/O Troubleshooting Guidelines
6. Intel Agilex® 7 F-Series and I-Series General-Purpose I/O IPs
7. Programmable I/O Features Description
8. Documentation Related to the Intel Agilex® 7 General-Purpose I/O User Guide: F-Series and I-Series
9. Document Revision History for the Intel Agilex® 7 General-Purpose I/O User Guide: F-Series and I-Series

6.1.4. GPIO Intel® FPGA IP Interface Signals

Depending on the parameter settings you specify, different interface signals are available for the GPIO IP.
Figure 30.  GPIO IP Interfaces


Figure 31.  GPIO Interface Signals
Table 44.  Pad Interface SignalsThe pad interface is the physical connection from the GPIO IP to the pad. This interface can be an input, output or bidirectional interface, depending on the IP configuration. In this table, SIZE is the data width specified in the IP parameter editor.
Signal Name Direction Description
pad_in[SIZE-1:0] Input

Input signal from the pad.
pad_in_b[SIZE-1:0] Input

Negative node of the differential input signal from the pad. This port is available if you turn on the Use differential buffer option.

pad_out[SIZE-1:0] Output Output signal to the pad.
pad_out_b[SIZE-1:0] Output

Negative node of the differential output signal to the pad. This port is available if you turn on the Use differential buffer option.

pad_io[SIZE-1:0] Bidirectional

Bidirectional signal connection with the pad.
pad_io_b[SIZE-1:0] Bidirectional

Negative node of the differential bidirectional signal connection with the pad. This port is available if you turn on the Use differential buffer option.

Table 45.  Data Interface SignalsThe data interface is an input or output interface from the GPIO IP to the FPGA core. In this table, SIZE is the data width specified in the IP parameter editor.
Signal Name Direction Description
din[DATA_SIZE-1:0] Input

Data input from the FPGA core in output or bidirectional mode. DATA_SIZE depends on the register mode:

  • Bypass or simple register— DATA_SIZE = SIZE
  • DDIO without half-rate logic— DATA_SIZE = 2 × SIZE
  • DDIO with half-rate logic— DATA_SIZE = 4 × SIZE
dout[DATA_SIZE-1:0] Output

Data output to the FPGA core in input or bidirectional mode, DATA_SIZE depends on the register mode:

  • Bypass or simple register— DATA_SIZE = SIZE
  • DDIO without half-rate logic— DATA_SIZE = 2 × SIZE
  • DDIO with half-rate logic— DATA_SIZE = 4 × SIZE
oe[OE_SIZE-1:0] Input

OE input from the FPGA core in output mode with Enable output enable port turned on, or bidirectional mode. OE is active high. When transmitting data, set this signal to 1. When receiving data, set this signal to 0. OE_SIZE depends on the register mode:

  • Bypass or simple register— DATA_SIZE = SIZE
  • DDIO without half-rate logic— DATA_SIZE = SIZE
  • DDIO with half-rate logic— DATA_SIZE = 2 × SIZE

For ×4 DQ group implementation, refer to the related information.
Table 46.  Clock Interface SignalsThe clock interface is an input clock interface. It consists of different signals, depending on the configuration. The GPIO IP can have zero, one, two, or four clock inputs. Clock ports appear differently in different configurations to reflect the actual function performed by the clock signal.
Signal Name Direction Description
ck Input

In input and output paths, this clock feeds a packed register or DDIO if you turn off the Half Rate logic parameter.

In bidirectional mode, this clock is the unique clock for the input and output paths if you turn off the Separate input/output Clocks parameter.

ck_fr Input

In input and output paths, these clocks feed the full-rate and half-rate DDIOs if your turn on the Half Rate logic parameter.

In bidirectional mode, the input and output paths use these clocks if you turn off the Separate input/output Clocks parameter.

ck_hr
ck_in Input

In bidirectional mode, these clocks feed a packed register or DDIO in the input and output paths if you specify both these settings:

  • Turn off the Half Rate logic parameter.
  • Turn on the Separate input/output Clocks parameter.
ck_out
ck_fr_in Input

In bidirectional mode, these clocks feed a full-rate and half-rate DDIOs in the input and output paths if you specify both of these settings:

  • Turn on the Half Rate logic parameter.
  • Turn on the Separate input/output Clocks parameter.

For example, ck_fr_out feeds the full-rate DDIO in the output path.

ck_fr_out
ck_hr_in
ck_hr_out
cke Input Clock enable.

For ×4 DQ group implementation, refer to the related information.
Table 47.  Termination Interface SignalsThe termination interface connects the GPIO IP to the I/O buffers.
Signal Name Direction Description
terminationcontrol Input Input from the termination control block (OCT) to the buffers. It sets the buffer series and parallel impedance values.
Table 48.  Reset Interface SignalsThe reset interface connects the GPIO IP core to the DDIOs. For ×4 DQ group implementation, refer to the related information.
Signal Name Direction Description
sclr Input

Synchronous clear input. Not available if you select None or Preset for the Enable synchronous clear / preset port option.

aclr Input

Asynchronous clear input. Active high. Not available if you select None or Preset for the Enable asynchronous clear / preset port option.

aset Input

Asynchronous set input. Active high. Not available if you select None or Clear for the Enable asynchronous clear / preset port option.

sset Input Synchronous set input. Not available if you select None or Clear for the Enable synchronous clear / preset port option.

Section Content
Shared Signals
Data Bit-Order for Data Interface
Input and Output Bus High and Low Bits
Data Interface Signals and Corresponding Clocks

Related Information
Level Two Title