Thermal Design User Guide: Agilex™ 3 FPGAs and SoCs

Download PDF
ID 851249
Date 5/12/2025
Public
Document Table of Contents
Document Table of Contents x
1. Introduction to Agilex™ 3 FPGA Thermal Design Guidelines 2. Agilex™ 3 FPGA Mechanical Construction 3. Agilex™ 3 FPGA Compact Thermal Model (CTM) Construction 4. Power and Thermal Calculator (PTC) 5. Thermal Design Process 6. General FPGA Thermal Design Considerations 7. Design Examples 8. Heat Sinks 9. Document Revision History for the Thermal Design User Guide: Agilex™ 3 FPGAs and SoCs A. Agilex™ 3 FPGA Product Keys and Package Drawings
1. Introduction to Agilex™ 3 FPGA Thermal Design Guidelines x
1.1. Thermal Design Requirements 1.2. Thermal Design Flow 1.3. Definitions of Thermal and Power Terms Used in this Document
2. Agilex™ 3 FPGA Mechanical Construction x
2.1. Built-in Temperature Sensors
2.1. Built-in Temperature Sensors x
2.1.1. Agilex™ 3 FPGA Temperature Rating
3. Agilex™ 3 FPGA Compact Thermal Model (CTM) Construction x
3.1. CTM File Format 3.2. Thermal Modeling with the CTM 3.3. CTM Top Temperature, TCASE Virtual Sensor 3.4. Obtaining the CTM
4. Power and Thermal Calculator (PTC) x
4.1. PTC Thermal Tab Parameters 4.2. Thermal Analysis with the PTC 4.3. PTC Thermal Tab Calculation Options 4.4. Thermal Resistances and Low Power Devices 4.5. Sensor Temperatures on the PTC Thermal Tab
5. Thermal Design Process x
5.1. Package Heat Flow Path 5.2. Variables Affecting the Heat Flow Path 5.3. Recommended Thermal Design Method
6. General FPGA Thermal Design Considerations x
6.1. FPGA Power Considerations
6.1. FPGA Power Considerations x
6.1.1. FPGA Maximum Allowed Power Dissipation 6.1.2. Static, Dynamic, and Standby Power 6.1.3. Future-Proofing an FPGA Thermal Design
7. Design Examples x
7.1. Example 1: Find Cooling Solution for Maximum Junction Temperature Limit 7.2. Example 2: Find Available Thermal Margin for Cooling Solution 7.3. Example 3: Find the Ambient Temperature for a Specified Cooling Solution
8. Heat Sinks x
8.1. Attachment Force 8.2. Thermal Interface Material (TIM)
8.2. Thermal Interface Material (TIM) x
8.2.1. Common TIM2 Materials
8.2.1. Common TIM2 Materials x
8.2.1.1. TIM2 Performance Parameters And Challenges 8.2.1.2. Understanding Resistance and Pressure Map Curves
1. Introduction to Agilex™ 3 FPGA Thermal Design Guidelines
2. Agilex™ 3 FPGA Mechanical Construction
3. Agilex™ 3 FPGA Compact Thermal Model (CTM) Construction
4. Power and Thermal Calculator (PTC)
5. Thermal Design Process
6. General FPGA Thermal Design Considerations
7. Design Examples
8. Heat Sinks
9. Document Revision History for the Thermal Design User Guide: Agilex™ 3 FPGAs and SoCs
A. Agilex™ 3 FPGA Product Keys and Package Drawings

5. Thermal Design Process

Altera recommends conducting a system thermal analysis as early as possible in the design cycle to ensure that there is sufficient cooling for the maximum predicted heat dissipation in the targeted FPGA application. FPGAs do not have a rated thermal design power. A given FPGA can be used with various designs, where each has unique power dissipation characteristics. Altera also recommends that you allow some margin for your cooling design when possible; this can prove useful when subsequent application or design changes result in greater power dissipation than initially anticipated.

Note: For a few low power applications, if the ambient temperatures and board temperatures are low and there is sufficiently large air flow, a large amount of heat generated by the FPGA can go through to the board and a heat sink may not even be required to cool the Agilex™ 3 device.

Before beginning thermal analysis, you require a good understanding of the PTC and CTM; these are described below.


Section Content
Package Heat Flow Path
Variables Affecting the Heat Flow Path
Recommended Thermal Design Method

Level Two Title