Agilex™ 7 Clocking and PLL User Guide: M-Series

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ID 769001
Date 11/27/2024
Public
Document Table of Contents
Document Table of Contents x
1. Agilex™ 7 FPGA M-Series Clocking and PLL Overview 2. M-Series Clocking and PLL Architecture and Features 3. M-Series Clocking and PLL Design Considerations 4. Clock Control Intel® FPGA IP Core 5. IOPLL Intel® FPGA IP Core 6. I/O PLL Reconfiguration Using EMIF Calibration IP 7. Agilex™ 7 Clocking and PLL User Guide: M-Series Archives 8. Document Revision History for the Agilex™ 7 Clocking and PLL User Guide: M-Series
1. Agilex™ 7 FPGA M-Series Clocking and PLL Overview x
1.1. Clock Networks Overview 1.2. PLLs Overview
2. M-Series Clocking and PLL Architecture and Features x
2.1. Clock Networks Architecture and Features 2.2. PLLs Architecture and Features
2.1. Clock Networks Architecture and Features x
2.1.1. Clock Network Architecture 2.1.2. Clock Resources 2.1.3. Clock Control Features
2.1.1. Clock Network Architecture x
2.1.1.1. Clock Network Hierarchy 2.1.1.2. Clock Sectors 2.1.1.3. Programmable Clock Routing
2.1.3. Clock Control Features x
2.1.3.1. Clock Gating 2.1.3.2. Clock Divider
2.1.3.1. Clock Gating x
2.1.3.1.1. Root Clock Gate 2.1.3.1.2. Sector Clock Gate 2.1.3.1.3. I/O PLL Clock Gate 2.1.3.1.4. LAB Clock Gate
2.2. PLLs Architecture and Features x
2.2.1. PLL Features 2.2.2. PLL Usage 2.2.3. PLL Locations 2.2.4. PLL Architecture 2.2.5. PLL Control Signals 2.2.6. PLL Feedback Modes 2.2.7. Clock Multiplication and Division 2.2.8. Programmable Phase Shift 2.2.9. Programmable Duty Cycle 2.2.10. PLL Cascading 2.2.11. PLL Input Clock Switchover 2.2.12. PLL Reconfiguration and Dynamic Phase Shift 2.2.13. PLL Calibration
2.2.5. PLL Control Signals x
2.2.5.1. Reset 2.2.5.2. Locked
2.2.6. PLL Feedback Modes x
2.2.6.1. Direct Compensation Mode 2.2.6.2. LVDS Compensation Mode 2.2.6.3. Source Synchronous Compensation Mode 2.2.6.4. Normal Compensation Mode 2.2.6.5. Zero-Delay Buffer Mode 2.2.6.6. External Feedback Mode
2.2.11. PLL Input Clock Switchover x
2.2.11.1. Automatic Switchover 2.2.11.2. Automatic Switchover with Manual Override 2.2.11.3. Manual Clock Switchover
2.2.13. PLL Calibration x
2.2.13.1. Power-Up Calibration 2.2.13.2. User Calibration 2.2.13.3. Static Phase Error Calibration 2.2.13.4. Output Clock Duty Cycle Correction
3. M-Series Clocking and PLL Design Considerations x
3.1. Guidelines: Clock Switchover 3.2. Guidelines: Timing Closure 3.3. Guidelines: Resetting the PLL 3.4. Guidelines: Configuration Constraints 3.5. Clocking Constraints 3.6. IP Core Constraints 3.7. Guideline: Achieving 5% Duty Cycle for fOUT_EXT ≥ 300 MHz Using tx_outclk Port from LVDS SERDES Intel® FPGA IP
4. Clock Control Intel® FPGA IP Core x
4.1. Release Information for Clock Control Intel® FPGA IP 4.2. Clock Control Intel® FPGA IP Core Parameters 4.3. Clock Control Intel® FPGA IP Core Ports and Signals
5. IOPLL Intel® FPGA IP Core x
5.1. Release Information for IOPLL Intel® FPGA IP 5.2. IOPLL IP Core Parameters 5.3. IOPLL IP Core Ports and Signals
5.2. IOPLL IP Core Parameters x
5.2.1. IOPLL IP Core Parameters - PLL Tab 5.2.2. IOPLL IP Core Parameters - Settings Tab 5.2.3. IOPLL IP Core Parameters - Cascading Tab 5.2.4. IOPLL IP Core Parameters - Advanced Parameters Tab
6. I/O PLL Reconfiguration Using EMIF Calibration IP x
6.1. Release Information for EMIF Calibration IP 6.2. Implementing I/O PLL Reconfiguration using EMIF Calibration IP 6.3. Reconfiguration Through EMIF Calibration IP 6.4. Axilite Interface Ports in the EMIF Calibration IP 6.5. Address Bus and Data Bus Settings
6.2. Implementing I/O PLL Reconfiguration using EMIF Calibration IP x
6.2.1. Setting Up the IOPLL Intel® FPGA IP 6.2.2. Setting Up the EMIF Calibration IP 6.2.3. Connectivity Between IOPLL and EMIF Calibration IP
6.3. Reconfiguration Through EMIF Calibration IP x
6.3.1. Enabling Reconfiguration for The Desired I/O PLL 6.3.2. Clearing off Calibration Statuses 6.3.3. Reconfiguring The I/O PLL 6.3.4. Recalibration Using EMIF Calibration IP 6.3.5. Clock Gating Using EMIF Calibration IP (Optional)
6.5. Address Bus and Data Bus Settings x
6.5.1. Divide Settings and the Corresponding Data Bit Setting for Reconfiguration 6.5.2. Data Bus Setting for Clock Gating Reconfiguration 6.5.3. Data Bus Setting For Charge Pump Current
1. Agilex™ 7 FPGA M-Series Clocking and PLL Overview
2. M-Series Clocking and PLL Architecture and Features
3. M-Series Clocking and PLL Design Considerations
4. Clock Control Intel® FPGA IP Core
5. IOPLL Intel® FPGA IP Core
6. I/O PLL Reconfiguration Using EMIF Calibration IP
7. Agilex™ 7 Clocking and PLL User Guide: M-Series Archives
8. Document Revision History for the Agilex™ 7 Clocking and PLL User Guide: M-Series

2.2.6.3. Source Synchronous Compensation Mode

If the data and clock signals arrive at the same time on the input pins, the same phase relationship is maintained at the clock and data ports of any IOE input register. Data and clock signals at the IOE experience similar buffer delays as long as you use the same I/O standard. Only one output clock can be compensated in source synchronous compensation mode.

Intel recommends source synchronous mode for source synchronous data transfers.

Figure 13. Example of Phase Relationship Between Clock and Data in Source Synchronous Mode


The source synchronous mode compensates for the delay of the clock network used and any difference in the delay between the following two paths:

  • Data pin to the IOE register input
  • Clock input pin to the PLL PFD input

The M-Series PLL can compensate multiple pad-to-input-register paths, such as a data bus when it is set to use source synchronous compensation mode.

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