Intel® Cyclone® 10 LP Core Fabric and General Purpose I/Os Handbook
ID
683777
Date
2/15/2023
Public
1. Logic Elements and Logic Array Blocks in Intel® Cyclone® 10 LP Devices
2. Embedded Memory Blocks in Intel® Cyclone® 10 LP Devices
3. Embedded Multipliers in Intel® Cyclone® 10 LP Devices
4. Clock Networks and PLLs in Intel® Cyclone® 10 LP Devices
5. I/O and High Speed I/O in Intel® Cyclone® 10 LP Devices
6. Configuration and Remote System Upgrades
7. SEU Mitigation in Intel® Cyclone® 10 LP Devices
8. JTAG Boundary-Scan Testing for Intel® Cyclone® 10 LP Devices
9. Power Management in Intel® Cyclone® 10 LP Devices
2.1. Embedded Memory Capacity
2.2. Intel® Cyclone® 10 LP Embedded Memory General Features
2.3. Intel® Cyclone® 10 LP Embedded Memory Operation Modes
2.4. Intel® Cyclone® 10 LP Embedded Memory Clock Modes
2.5. Intel® Cyclone® 10 LP Embedded Memory Configurations
2.6. Intel® Cyclone® 10 LP Embedded Memory Design Consideration
2.7. Embedded Memory Blocks in Intel® Cyclone® 10 LP Devices Revision History
4.2.1. PLL Features
4.2.2. PLL Architecture
4.2.3. External Clock Outputs
4.2.4. Clock Feedback Modes
4.2.5. Clock Multiplication and Division
4.2.6. Post-Scale Counter Cascading
4.2.7. Programmable Duty Cycle
4.2.8. PLL Control Signals
4.2.9. Clock Switchover
4.2.10. Programmable Bandwidth
4.2.11. Programmable Phase Shift
4.2.12. PLL Cascading
4.2.13. PLL Reconfiguration
4.2.14. Spread-Spectrum Clocking
5.1. Intel® Cyclone® 10 LP I/O Standards Support
5.2. I/O Resources in Intel® Cyclone® 10 LP Devices
5.3. Intel FPGA I/O IP Cores for Intel® Cyclone® 10 LP Devices
5.4. Intel® Cyclone® 10 LP I/O Elements
5.5. Intel® Cyclone® 10 LP Clock Pins Input Support
5.6. Programmable IOE Features in Intel® Cyclone® 10 LP Devices
5.7. I/O Standards Termination
5.8. Intel® Cyclone® 10 LP High-Speed Differential I/Os and SERDES
5.9. Using the I/Os and High Speed I/Os in Intel® Cyclone® 10 LP Devices
5.10. I/O and High Speed I/O in Intel® Cyclone® 10 LP Devices Revision History
5.8.2.1. LVDS I/O Standard in Intel® Cyclone® 10 LP Devices
5.8.2.2. Bus LVDS I/O Standard in Intel® Cyclone® 10 LP Devices
5.8.2.3. RSDS, Mini-LVDS, and PPDS I/O Standard in Intel® Cyclone® 10 LP Devices
5.8.2.4. LVPECL I/O Standard in Intel® Cyclone® 10 LP Devices
5.8.2.5. Differential SSTL I/O Standard in Intel® Cyclone® 10 LP Devices
5.8.2.6. Differential HSTL I/O Standard in Intel® Cyclone® 10 LP Devices
5.9.1. Guideline: Validate Your Pin Placement
5.9.2. Guideline: Check for Illegal Pad Placements
5.9.3. Guideline: Voltage-Referenced I/O Standards Restriction
5.9.4. Guideline: Simultaneous Usage of Multiple I/O Standards
5.9.5. Guideline: LVTTL or LVCMOS Inputs in Intel® Cyclone® 10 LP Devices
5.9.6. Guideline: Differential Pad Placement
5.9.7. Guideline: Board Design for Signal Quality
6.1.4.1. Configuring Intel® Cyclone® 10 LP Devices with the JRunner Software Driver
6.1.4.2. Configuring Intel® Cyclone® 10 LP Devices with Jam STAPL
6.1.4.3. JTAG Single-Device Configuration
6.1.4.4. JTAG Multi-Device Configuration
6.1.4.5. Combining JTAG and AS Configuration Schemes
6.1.4.6. Programming Serial Configuration Devices In-System with the JTAG Interface
6.1.4.7. JTAG Instructions
6.5. Remote System Upgrades
Intel® Cyclone® 10 LP devices contain dedicated remote system upgrade circuitry.
You can use this feature to upgrade your system from a remote location in AS configuration schemes.
Figure 106. Intel® Cyclone® 10 LP Remote System Upgrade Block Diagram
You can design your system to manage remote upgrades of the application configuration images in the configuration device. The following list is the sequence of the remote system upgrade:
- The logic (embedded processor or user logic) in the Intel® Cyclone® 10 LP device receives a configuration image from a remote location. You can connect the device to the remote source using communication protocols such as TCP/IP, PCI, user datagram protocol (UDP), UART, or a proprietary interface.
- The logic stores the configuration image in non-volatile configuration memory.
- The logic starts reconfiguration cycle using the newly received or updated configuration image.
When an error occurs, the circuitry detects the error, reverts to a safe configuration image, and provides error status to your design.