Intel® Quartus® Prime Standard Edition User Guide: Design Constraints

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ID 683492
Date 1/10/2019
Public
Document Table of Contents
Document Table of Contents x
1. Constraining Designs 2. Managing Device I/O Pins A. Intel® Quartus® Prime Standard Edition User Guides
1. Constraining Designs x
1.1. Specifying Design Constraints Designs in the GUI 1.2. Constraining Designs with Tcl Scripts 1.3. A Fully Iterative Scripted Flow 1.4. Constraining Designs Revision History
1.1. Specifying Design Constraints Designs in the GUI x
1.1.1. Global Constraints and Assignments 1.1.2. Node, Entity, and Instance-Level Constraints 1.1.3. Probing Between Components of the Intel® Quartus® Prime GUI 1.1.4. Specifying Timing Constraints in the GUI
1.1.2. Node, Entity, and Instance-Level Constraints x
1.1.2.1. Specify Instance-Specific Constraints in Assignment Editor 1.1.2.2. Specify I/O Constraints in Pin Planner 1.1.2.3. Adjust Constraints with the Chip Planner 1.1.2.4. Constraining Designs with the Design Partition Planner
1.2. Constraining Designs with Tcl Scripts x
1.2.1. Create a Project and Apply Constraints 1.2.2. Assigning a Pin 1.2.3. Generating Intel® Quartus® Prime Settings Files 1.2.4. Synopsys* Design Constraint (.sdc) Files 1.2.5. Tcl-only Script Flows
1.2.5. Tcl-only Script Flows x
1.2.5.1. Tcl-only Timing Analysis
2. Managing Device I/O Pins x
2.1. I/O Planning Overview 2.2. Assigning I/O Pins 2.3. Importing and Exporting I/O Pin Assignments 2.4. Validating Pin Assignments 2.5. Verifying I/O Timing 2.6. Viewing Routing and Timing Delays 2.7. Analyzing Simultaneous Switching Noise 2.8. Scripting API 2.9. Managing Device I/O Pins Revision History
2.1. I/O Planning Overview x
2.1.1. Basic I/O Planning Flow 2.1.2. Integrating PCB Design Tools 2.1.3. Intel Device Terms
2.2. Assigning I/O Pins x
2.2.1. Assigning to Exclusive Pin Groups 2.2.2. Assigning Slew Rate and Drive Strength 2.2.3. Assigning Differential Pins 2.2.4. Entering Pin Assignments with Tcl Commands 2.2.5. Entering Pin Assignments in HDL Code
2.2.3. Assigning Differential Pins x
2.2.3.1. Overriding I/O Placement Rules on Differential Pins
2.2.5. Entering Pin Assignments in HDL Code x
2.2.5.1. Using Synthesis Attributes 2.2.5.2. Using Low-Level I/O Primitives
2.3. Importing and Exporting I/O Pin Assignments x
2.3.1. Importing and Exporting for PCB Tools 2.3.2. Migrating Assignments to Another Target Device
2.4. Validating Pin Assignments x
2.4.1. I/O Assignment Validation Rules 2.4.2. Checking I/O Pin Assignments in Real-Time 2.4.3. I/O Assignment Analysis 2.4.4. Understanding I/O Analysis Reports
2.4.3. I/O Assignment Analysis x
2.4.3.1. Early I/O Assignment Analysis Without Design Files 2.4.3.2. I/O Assignment Analysis With Design Files 2.4.3.3. Overriding Default I/O Pin Analysis
2.5. Verifying I/O Timing x
2.5.1. Running Advanced I/O Timing 2.5.2. Adjusting I/O Timing and Power with Capacitive Loading
2.5.1. Running Advanced I/O Timing x
2.5.1.1. Board Trace Models 2.5.1.2. Defining the Board Trace Model 2.5.1.3. Modifying the Board Trace Model 2.5.1.4. Specifying Near-End vs Far-End I/O Timing Analysis 2.5.1.5. Advanced I/O Timing Analysis Reports
2.8. Scripting API x
2.8.1. Generate Mapped Netlist 2.8.2. Reserve Pins 2.8.3. Set Location 2.8.4. Exclusive I/O Group 2.8.5. Slew Rate and Current Strength
1. Constraining Designs
2. Managing Device I/O Pins
A. Intel® Quartus® Prime Standard Edition User Guides

2.5. Verifying I/O Timing

You must verify board-level signal integrity and I/O timing when assigning I/O pins. High-speed interface operation requires a quality signal and low propagation delay at the far end of the board route. Click Tools > Timing Analyzer to confirm timing after making I/O pin assignments.

For example, if you change the slew rates or drive strengths of some I/O pins with ECOs, you can verify timing without recompiling the design. You must understand I/O timing and what factors affect I/O timing paths in your design. The accuracy of the output load specification of the output and bidirectional pins affects the I/O timing results.

The Intel® Quartus® Prime software supports three different methods of I/O timing analysis:

Table 10.  I/O Timing Analysis Methods

I/O Timing Analysis

Description

Advanced I/O timing analysis

Analyze I/O timing with your board trace model to report accurate, “board-aware” simulation models. Configures a complete board trace model for each I/O standard or pin. Timing Analyzer applies simulation results of the I/O buffer, package, and board trace model to generate accurate I/O delays and system level signal information. Use this information to improve timing and signal integrity.

I/O timing analysis

Analyze I/O timing with default or specified capacitive load without signal integrity analysis. Timing Analyzer reports tCO to an I/O pin using a default or user-specified value for a capacitive load.

Full board routing simulation

Use Intel-provided or Intel® Quartus® Prime software-generated IBIS or HSPICE I/O models for simulation in Mentor Graphics* HyperLynx* and Synopsys* HSPICE.

Note: Advanced I/O timing analysis is supported only for .28nm and larger device families. For devices that support advanced I/O timing, it is the default method of I/O timing analysis. For all other devices, you must use a default or user-specified capacitive load assignment to determine tCO and power measurements.

For more information about advanced I/O timing support, refer to the appropriate device handbook for your target device. For more information about board-level signal integrity and tips on how to improve signal integrity in your high-speed designs, refer to the Altera Signal Integrity Center page of the Altera website.

For information about creating IBIS and HSPICE models with the Intel® Quartus® Prime software and integrating those models into HyperLynx* and HSPICE simulations, refer to the Signal Integrity Analysis with Third Party Tools chapter.


Section Content
Running Advanced I/O Timing
Adjusting I/O Timing and Power with Capacitive Loading

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