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1. Stratix® 10 Clocking and PLL Overview
2. Stratix® 10 Clocking and PLL Architecture and Features
3. Stratix® 10 Clocking and PLL Design Considerations
4. Stratix® 10 Clocking and PLL Implementation Guides
5. Clock Control Intel® FPGA IP Core References
6. IOPLL Intel® FPGA IP Core References
7. IOPLL Reconfig Intel® FPGA IP Core References
8. Stratix® 10 Clocking and PLL User Guide Archives
9. Document Revision History for the Stratix® 10 Clocking and PLL User Guide
2.2.1. PLL Features
2.2.2. PLL Usage
2.2.3. PLL Architecture
2.2.4. PLL Control Signals
2.2.5. Clock Feedback Modes
2.2.6. Clock Multiplication and Division
2.2.7. Programmable Phase Shift
2.2.8. Programmable Duty Cycle
2.2.9. PLL Cascading
2.2.10. Clock Switchover
2.2.11. PLL Reconfiguration and Dynamic Phase Shift
2.2.12. PLL Calibration
4.3.4.1. Design Example 1: .mif Streaming Reconfiguration Using IOPLL Reconfig IP Core
4.3.4.2. Design Example 2: Advanced Mode Reconfiguration Using IOPLL Reconfig IP Core
4.3.4.3. Design Example 3: Clock Gating Reconfiguration Using IOPLL Reconfig IP Core
4.3.4.4. Design Example 4: Dynamic Phase Shift Using IOPLL Reconfig IP Core
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2.2.5.2. LVDS Compensation Mode
The purpose of LVDS compensation mode is to maintain the same data and clock timing relationship seen at the pins of the internal serializer/deserializer (SERDES) capture register, except that the clock is inverted (180° phase shift). Thus, LVDS compensation mode ideally compensates for the delay of the LVDS clock network, including the difference in delay between the following two paths:
- Data pin-to-SERDES capture register
- Clock input pin-to-SERDES capture register
The output counter must provide the 180° phase shift.
Figure 11. Example of Phase Relationship Between the Clock and Data in LVDS Compensation Mode