Thermal Design User Guide: MAX® 10 FPGA B610 Package

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ID 851247
Date 5/20/2025
Public
Document Table of Contents
Document Table of Contents x
1. Introduction to MAX® 10 FPGA B610 Package Thermal Design Guidelines 2. MAX® 10 FPGA B610 Package Mechanical Construction 3. MAX® 10 FPGA B610 Package CTM Construction 4. Quartus Requirements and Power Estimation 5. General FPGA Thermal Design Considerations 6. Thermal Design Process 7. Thermal Solution Mechanical Design 8. Vendor References 9. Document Revision History for the MAX® 10 FPGA B610 Package Thermal Design User Guide A. Thermal Design Elements
1. Introduction to MAX® 10 FPGA B610 Package Thermal Design Guidelines x
1.1. Thermal Design Requirements 1.2. Definitions of Thermal and Power Terms Used in this Document
2. MAX® 10 FPGA B610 Package Mechanical Construction x
2.1. Thermal Design Process Flow 2.2. Thermal Resistance Values Summary
3. MAX® 10 FPGA B610 Package CTM Construction x
3.1. CTM File Format 3.2. Thermal Modeling with the CTM 3.3. Obtaining the CTM
4. Quartus Requirements and Power Estimation x
4.1. Board Thermal Model 4.2. QPA Outputs
5. General FPGA Thermal Design Considerations x
5.1. FPGA Power Considerations 5.2. FPGA Maximum Allowed Power Dissipation 5.3. Static, Dynamic, and Standby Power
6. Thermal Design Process x
6.1. Package Heat Flow Path 6.2. Recommended Thermal Design Methodology
7. Thermal Solution Mechanical Design x
7.1. Mechanical Design 7.2. TIM2 Selection 7.3. Summary
7.1. Mechanical Design x
7.1.1. Bond Line Thickness (BLT) 7.1.2. Die Warpage 7.1.3. Package Loading 7.1.4. Recommended Pressure Variation Across the Package
7.2. TIM2 Selection x
7.2.1. Gap Pad TIMs 7.2.2. Gap Pad TIM Thermal Conductivity Data 7.2.3. Parametric Studies with Different TIM Materials
1. Introduction to MAX® 10 FPGA B610 Package Thermal Design Guidelines
2. MAX® 10 FPGA B610 Package Mechanical Construction
3. MAX® 10 FPGA B610 Package CTM Construction
4. Quartus Requirements and Power Estimation
5. General FPGA Thermal Design Considerations
6. Thermal Design Process
7. Thermal Solution Mechanical Design
8. Vendor References
9. Document Revision History for the MAX® 10 FPGA B610 Package Thermal Design User Guide
A. Thermal Design Elements

2.1. Thermal Design Process Flow

Based on the developmental cycle, Altera enables the thermal design process flow through multiple phases.

  • For early, rough analysis, Altera provides package thermal resistance characteristics that can be used to quickly size cooling requirements based on early power numbers.
  • As the design of the FPGA matures, Altera recommends using the Quartus Power Analyzer (QPA) to create power estimates and junction temperature targets.
  • Once the overall board and FPGA design is mature, Altera recommends using thermal simulation with compact thermal models (CTM) provided by Altera.
Note: For some 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 be required to cool the MAX® 10 device.
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