Introduction to Altera® IP Cores

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ID 683102
Date 3/31/2025
Public
Document Table of Contents
Document Table of Contents x
Answers to Top FAQs 1. Introduction to Altera IP Cores
1. Introduction to Altera IP Cores x
1.1. Altera IP Catalog and Parameter Editor 1.2. Installing and Licensing Altera* IP Cores 1.3. Best Practices for Altera* IP 1.4. IP General Settings 1.5. Specifying the IP Parameters and Options ( Quartus® Prime Pro Edition) 1.6. Generating IP Cores ( Quartus® Prime Standard Edition) 1.7. Generating Example Designs for Altera* IP 1.8. Modifying an IP Variation 1.9. Upgrading IP Cores 1.10. Simulating Altera* IP Cores 1.11. Synthesizing IP Cores in Other EDA Tools 1.12. Support for the IEEE 1735 Encryption Standard 1.13. Introduction to Altera* IP Cores Revision History 1.14. Introduction to Altera* IP Cores Archives
1.1. Altera IP Catalog and Parameter Editor x
1.1.1. The Parameter Editor
1.2. Installing and Licensing Altera* IP Cores x
1.2.1. Intel FPGA IP Evaluation Mode 1.2.2. Checking the IP License Status 1.2.3. FPGA IP Versioning 1.2.4. Adding IP to IP Catalog
1.5. Specifying the IP Parameters and Options ( Quartus® Prime Pro Edition) x
1.5.1. IP Core Generation Output ( Quartus® Prime Pro Edition) 1.5.2. Scripting IP Core Generation
1.6. Generating IP Cores ( Quartus® Prime Standard Edition) x
1.6.1. IP Core Generation Output ( Quartus® Prime Standard Edition)
1.9. Upgrading IP Cores x
1.9.1. Upgrading IP Cores at Command-Line 1.9.2. Migrating IP Cores to a Different Device 1.9.3. Troubleshooting IP or Platform Designer System Upgrade
1.10. Simulating Altera* IP Cores x
1.10.1. Supported Simulators 1.10.2. Supported Simulation Flows 1.10.3. Generating IP Simulation Files 1.10.4. Scripting IP Simulation 1.10.5. Using NativeLink Simulation ( Quartus® Prime Standard Edition)
1.10.4. Scripting IP Simulation x
1.10.4.1. Generating a Combined Simulator Setup Script
1.10.4.1. Generating a Combined Simulator Setup Script x
1.10.4.1.1. Sourcing Aldec ActiveHDL* or Riviera Pro* Simulator Setup Scripts 1.10.4.1.2. Sourcing Cadence Incisive* Simulator Setup Scripts 1.10.4.1.3. Sourcing Cadence Xcelium* Simulator Setup Scripts 1.10.4.1.4. Sourcing QuestaSim* Simulator Setup Scripts 1.10.4.1.5. Sourcing Synopsys VCS* (2-Step) Simulator Setup Scripts 1.10.4.1.6. Sourcing Synopsys VCS* (3-Step) Simulator Setup Scripts
1.10.5. Using NativeLink Simulation ( Quartus® Prime Standard Edition) x
1.10.5.1. Setting Up NativeLink Simulation ( Quartus® Prime Standard Edition) 1.10.5.2. Generating IP Functional Simulation Models ( Quartus® Prime Standard Edition)
1.11. Synthesizing IP Cores in Other EDA Tools x
1.11.1. Instantiating IP Cores in HDL
1.11.1. Instantiating IP Cores in HDL x
1.11.1.1. Accessing HDL Code Templates
1.11.1.1. Accessing HDL Code Templates x
1.11.1.1.1. Example Top-Level Verilog HDL Module 1.11.1.1.2. Example Top-Level VHDL Module
1.12. Support for the IEEE 1735 Encryption Standard x
1.12.1. Introduction to the IEEE 1735 Standalone Encryptor 1.12.2. IEEE1735 Standalone Encryptor Modes
1.12.2. IEEE1735 Standalone Encryptor Modes x
1.12.2.1. Using Quartus Mode for IEEE1735 Encryption 1.12.2.2. Using Supported Simulator Mode for IEEE1735 Encryption 1.12.2.3. Using Partial Encryption
Answers to Top FAQs
1. Introduction to Altera IP Cores

1.10.5.2. Generating IP Functional Simulation Models ( Quartus® Prime Standard Edition)

Altera provides IP functional simulation models for some Altera* IP supporting 40nm FPGA devices.
To generate IP functional simulation models:
  1. Turn on the Generate Simulation Model option when parameterizing the IP core.
  2. When you simulate your design, compile only the .vo or .vho for these IP cores in your simulator. Do not compile the corresponding HDL file. The encrypted HDL file supports synthesis by only the Quartus® Prime software.
    Note:
    • Altera* IP cores that do not require IP functional simulation models for simulation, do not provide the Generate Simulation Model option in the IP core parameter editor.
    • Many recently released Altera* IP cores support RTL simulation using IEEE Verilog HDL encryption. IEEE encrypted models are significantly faster than IP functional simulation models. Simulate the models in both Verilog HDL and VHDL designs.
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