High Bandwidth Memory (HBM2) Interface FPGA IP User Guide

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ID 683189
Date 3/29/2024
Public
Document Table of Contents
Document Table of Contents x
1. About the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 2. Introduction to High Bandwidth Memory 3. Stratix® 10 HBM2 Architecture 4. Creating and Parameterizing the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 5. Simulating the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 6. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Interface 7. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Controller Performance 8. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP User Guide Archives 9. Document Revision History for High Bandwidth Memory (HBM2) Interface FPGA IP User Guide
1. About the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP x
1.1. Release Information
2. Introduction to High Bandwidth Memory x
2.1. HBM2 in Intel® Stratix® 10 Devices 2.2. HBM2 DRAM Structure 2.3. Stratix® 10 HBM2 Features 2.4. Stratix® 10 HBM2 Controller Features
3. Stratix® 10 HBM2 Architecture x
3.1. Stratix® 10 HBM2 Introduction 3.2. Stratix® 10 UIB Architecture 3.3. Stratix® 10 HBM2 Controller Architecture
3.3. Stratix® 10 HBM2 Controller Architecture x
3.3.1. Stratix® 10 HBM2 Controller Details
4. Creating and Parameterizing the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP x
4.1. Creating an Quartus® Prime Pro Edition Project for High Bandwidth Memory (HBM2) Interface FPGA IP 4.2. Parameterizing the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.3. Pin Planning for the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP
4.2. Parameterizing the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP x
4.2.1. General Parameters for High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.2.2. FPGA I/O Parameters for High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.2.3. Controller Parameters for High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.2.4. Diagnostic Parameters for High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.2.5. Example Designs Parameters for High Bandwidth Memory (HBM2) Interface Intel® FPGA IP 4.2.6. Register Map IP-XACT Support for HBM2 IP
5. Simulating the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP x
5.1. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Example Design 5.2. Simulating High Bandwidth Memory (HBM2) Interface Intel® FPGA IP with ModelSim* and Questa* 5.3. Simulating High Bandwidth Memory (HBM2) Interface Intel® FPGA IP with Synopsys VCS* 5.4. Simulating High Bandwidth Memory (HBM2) Interface Intel® FPGA IP with Riviera-PRO* 5.5. Simulating High Bandwidth Memory (HBM2) Interface Intel® FPGA IP with Cadence Xcelium* Parallel Simulator 5.6. Simulating High Bandwidth Memory (HBM2) Interface Intel® FPGA IP for High Efficiency 5.7. Simulating High Bandwidth Memory (HBM2) Interface IP Instantiated in Your Project
6. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Interface x
6.1. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP High Level Block Diagram 6.2. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Controller Interface Signals 6.3. User AXI Interface Timing 6.4. User APB Interface Timing 6.5. User-controlled Accesses to the HBM2 Controller 6.6. Soft AXI Switch
6.2. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Controller Interface Signals x
6.2.1. Clock Signals 6.2.2. Reset Signals 6.2.3. Calibration Status Signals 6.2.4. Memory Interface Signals 6.2.5. User-interface Signals 6.2.6. AXI User-interface Signals 6.2.7. Sideband APB Interface 6.2.8. Avalon® Memory-Mapped (AVMM) Interface Signals
6.3. User AXI Interface Timing x
6.3.1. AXI Write Transaction 6.3.2. AXI Read Transaction 6.3.3. Improving User Logic to HBM2 Controller AXI Interface Timing
6.4. User APB Interface Timing x
6.4.1. Advanced Peripheral Bus Protocol 6.4.2. APB Interface Timing
6.5. User-controlled Accesses to the HBM2 Controller x
6.5.1. User-controlled Refreshes 6.5.2. Temperature and Calibration Status Readout 6.5.3. Controller Idle State Status 6.5.4. Power Down Status 6.5.5. ECC Error Status 6.5.6. User Interrupt 6.5.7. ECC Error Correction and Detection
6.5.6. User Interrupt x
6.5.6.1. Interrupt Enable and Conditions for Interrupt Generation 6.5.6.2. Interrupt Status 6.5.6.3. Error Valid Status
6.6. Soft AXI Switch x
6.6.1. AXI Switch Selection in HBM2 IP Catalog GUI
7. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Controller Performance x
7.1. High Bandwidth Memory (HBM2) DRAM Bandwidth 7.2. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP HBM2 IP Efficiency 7.3. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Latency 7.4. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Timing 7.5. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP DRAM Temperature Readout
1. About the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP
2. Introduction to High Bandwidth Memory
3. Stratix® 10 HBM2 Architecture
4. Creating and Parameterizing the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP
5. Simulating the High Bandwidth Memory (HBM2) Interface Intel® FPGA IP
6. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Interface
7. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Controller Performance
8. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP User Guide Archives
9. Document Revision History for High Bandwidth Memory (HBM2) Interface FPGA IP User Guide

7.3. High Bandwidth Memory (HBM2) Interface Intel® FPGA IP Latency

Read latency measures the number of clock cycles from the time the HBM2 controller receives a valid read address command, to the time that valid read data is available at the user interface. (In other words, from the instant the master asserts the ARVALID signal and the slave asserts the ARREADY signal, until the slave asserts the RVALID signal and the master asserts the RREADY signal.)

Read latency includes the controller command path latency to issue the read command to the HBM2 memory, memory read latency, and the delay in the read data path through the HBMC memory controller. Simulation reports the minimum latency in AXI core clock cycles seen during the simulation time.

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