Overview
In this class, you will extend PrimeTime's signoff static timing analysis capability to accurately analyze peak power, average power, clock network power, and multi-voltage power.
A job aid will guide you through the setup requirements and command flow to perform an appropriate power analysis type (average vs. peak; instantaneous peak vs. cycle-accurate peak).
Skills learned include:
determining possible analysis methods, based on the available data and the application needs
applying a methodology to confirm that the power analysis performed was complete and correct
applying debugging technique(s) if necessary
generating and interpreting all of the standard PrimeTime PX reports for switching activity peak power, average power, clock network power, and multi-voltage power analyses
generating and viewing peak-power waveforms
To analyze power on multi-voltage designs, you will be using the unified power format (IEEE 1801 UPF) based flow.
Objectives
At the end of this workshop the student should be able to:
Read the required timing and power data; verify their completeness
Perform peak and average power analysis in the GUI and shell interface
Perform SDC clock-frequency-based power scaling in VCD/SAIF average power flow
Generate VCD and SAIF switching activity files by simulating RTL and gate-level designs
Distinguish between event-based and cycle-accurate peak power (CAPP) analysis
Dump and view peak power waveforms
Perform conditional peak power analysis
Determine quality of analyses from switching activity and power reports
Estimate pre-layout clock-tree power
Annotate clock-network power
Determine power savings due to clock gating
Specify PVT corner and libraries for multi -voltage power analysis
Interpret UPF power intent of a multi voltage design
Perform UPF-flow-based multi-voltage power analysis
Perform concurrent multi-rail power analysis using UPF
Course Outline
Introduction to Power Analysis
Average Power Analysis
Peak Power Analysis
Clock Network Power Analysis
Multivoltage Power Analysi
第二階段 PrimeTime 1
Overview
In this workshop you will learn to perform Static Timing Analysis (STA) using PrimeTime by executing the appropriate high-level summary reports to initiate your analysis, customizing and interpreting detailed timing reports for debugging, and exploring and analyzing the clocks that dictate STA results.
You will also learn to maximize your productivity by validating inherited scripts for your design, by creating scripts using a Synopsys-recommended methodology, by identifying opportunities to improve run time, and by customizing your environment for ease of running and debugging.
The workshop includes comprehensive hands-on labs, which provide an opportunity to apply key concepts covered during the lectures.
Objectives
At the end of this workshop the student should be able to:
Generate summary reports of the design violations organized by clock, by slack, by timing check, or by where they occur: on boundary paths or register-to-register paths.
Interpret violation details, both for netlist and for constraints, in a timing report for setup and hold, recovery and removal, and clock-gating setup and hold
Generate timing reports for specific paths and with specific details
Validate, confirm, debug, enhance, and execute a PrimeTime run script
Create a PrimeTime run script based on seed scripts from the RMgen (Reference Methodology Generator) utility
Identify opportunities to improve run time
Create a saved session and subsequently restore the saved session
Identify the clocks, where they are defined, and which ones interact, on an unfamiliar design
Reduce pessimism using path-based analysis
Course Outline
Unit 1
Does your Design Meet Timing?
Objects, Attributes, Collections
Constraints in a Timing Report
Timing Arcs in a Timing Report
Control which Paths are Reported
Unit 2
Summary Reports
Validate & Enhance PrimeTime Session
Analysis Types and Back Annotation
Getting to Know Your Clocks
Unit 3
Additional Checks and Constraints
Path-Based Analysis
Conclusion and Intersecting Technolog
第三階段 PrimeTime 2: Debugging Constraints
Overview
This workshop addresses the most time-consuming part of static timing analysis: debugging constraints. The workshop provides a method to identify potential timing problems, identify the cause, and determine the effects of these problems. Armed with this information, students will now be able to confirm that constraints are correct or, if incorrect, will have sufficient information to correct the problem.
Incorrect STA constraints must be identified because they obscure real timing violations and can cause two problems: either the real violations are missed and not reported or violations are reported that are not real, making it difficult to find the real violations hidden among them.
Objectives
At the end of this workshop the student should be able to:
Pinpoint the cause and determine the effects of check_timing and report_analysis_coverage warnings
Execute seven PrimeTime commands and two custom procedures to trace from the warning to the cause and explore objects in that path
Systematically debug scripts to eliminate obvious problems using PrimeTime
Independently and fully utilize check_timing and report_analysis_coverage to flag remaining constraint problems
Identify key pieces of a timing report for debugging final constraint problems
Course Outline
Finding Problems
Tools of the Trade
Applying Tools of the Trade to Common Scenarios
A Recommended Debugging Flow
Debugging Clocks
Conclusion
第四階段 PrimeTime SI: Crosstalk Delay and Noise
Overview
In this class, you will learn the basic concepts of crosstalk, their effects on timing and noise, how PrimeTime SI can be used to identify these effects, and how PrimeTime SI can be used to perform hat-if analysis to guide the place and route tools in the fixing of violations. You will apply the PrimeTime SI flow and methodology for chip-level crosstalk analysis. The labs will demonstrate the use of PrimeTime SI to analyze crosstalk failures on an actual design.
Best practice methodologies will give you the insights to drive the PrimeTime SI tool at its optimum performance and to generate quality results.
Hands-on labs follow each training module, allowing you to apply the skills learned in lecture.
Objectives
At the end of this workshop the student should be able to:
Run PTSI for crosstalk delay and noise analysis
Use the key reports in the shell and GUI to identify violations due to crosstalk, and to guide timing closure
Define clock relationships for improved timing accuracy
Apply useful commands to catch and report incomplete inputs to PTSI
More finely control PTSI and your fixing tool using the following techniques
Manually control delta delay and noise calculations for specific nets
Apply path-based analysis
Apply what-if analysis, both automatically and manually
Course Outline
Run PrimeTime SI: Crosstalk Delay
Completing your Inputs for PTSI
Run PrimeTime SI: Crosstalk Noise
Improving Accuracy
ECO Flows
第五階段 TetraMAX
Overview
In this three-day workshop, you will learn how use TetraMAX? to perform the following tasks:
Generate test patterns for stuck-at faults given a scan gate-level design created by DFT Compiler or other tools
Describe the test protocol and test pattern timing using STIL
Debug DRC and stuck-at fault coverage problems using the Graphical Schematic Viewer
Troubleshoot fault coverage problems
Save and validate test patterns
Troubleshoot simulation failures
Diagnose failures on the ATE
This workshop also includes an overview of the fundamentals of manufacturing test, such as:
What is manufacturing test?
Why perform manufacturing test?
What is a stuck-at fault?
What is a scan chain?
An overview of the Adaptive Scan and Power-Aware APTG features in TetraMAX? will also be presented.
Objectives
At the end of this workshop the student should be able to:
Incorporate TetraMAX? ATPG in a design and test methodology that produces desired fault coverage, ATPG vector count and ATPG run-time for a full-scan or almost full-scan design
Create a STIL Test Protocol File for a design by using Quick STIL menus or commands, DFT Compiler, or from scratch
Use the Graphical Schematic Viewer to analyze and debug warning messages from Design Rule Check or fault coverage problems after ATPG
Describe when and how to use at least three options to increase test coverage and/or decrease the number of required test patterns
Save test patterns in a proper format for simulation and transfer to an ATE
Validate test patterns in simulation using MAX Testbench
Describe the difference between the Transition Delay and Path Delay fault models
Use timing exceptions with At-Speed testing to mask slow cells
Limit switching activity with Power-Aware ATPG
Perform Transition Delay testing including Slack-Based Transition Delay
Use On-Chip Clocking (OCC) to provide launch and capture clock pulse for At-Speed testing
Generate critical paths from PrimeTime for performing Path Delay testing
Use TetraMAX? diagnosis features to analyze failures on the ATE
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