培训安排:
第一阶段:
概述
SOCEncounter的基本界面操作
布图(Floorplan)
电源网络设计(power?plan)
布局(Placement)
扫描链重排与优化(Scan?Chain?Re-ordering)
早期布线特性分析(TrialRoute)
1) Advance and High performance design challenged– Encounter solution-RCP
Traditional synthesis tools use vendor-supplied wire-load models based on fanouts, which do not provide accurate wire delay information especially for designs where a significant portion of the delays are contributed by the wires. The RCP flow uses a complete placement and considers congestion and legal placement as a cost function during the RTL-to-gates phase, to create a better netlist. This flow ensures both the best accuracy and the most predictable closure with back-end tools.
-CCOPT
Clock Concurrent Optimization technology, also known as CCopt, which delivers superior capabilities for designers faced with increasing performance, power and area challenges. Specifically, ccopt technology has delivered significant quality of silicon (QoS) on high-speed processor designs in the areas of:
n ?Power (clock tree power reduction up to 30 percent and total power improvements of up to 10 percent),
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n ?Performance (improvements of up to 100 MHz for a GHz design), and
n ?Area (clock tree area reduction up to 30 percent)
-GigaOpt
The new GigaOpt technology inside EDI System produces high-quality results faster than traditional optimization engines by harnessing the power of multiple CPUs. GigaOpt does multi-threading combined base and SI delay timing optimization.
2) ?Mixed Signal Physical Implementation flow
- Introduction
- Integration Constraints
- Netlist Driven Mixed Signal Flow
3) ?RDL co-design flow
- Flipchip introduce
- Encounter Flipchip flow
- RDL co-design
In this course, you willRun timing optimization?
Run silicon virtual prototyping?
Run placement with the Amoeba placer?
Estimate parasitics and generate delay information?
Analyze congestion after running Trial Route?
Create clock trees?
Create physical partitions (hierarchy) and timing budgets?
Run signal integrity analysis?
Optimize timing?
Run NanoRoute? Ultra detail routing?
Apply postroute timing and signal integrity optimization
In this course, you will get a high-level technical overview of the SoC Encounter flow. However, to gain in-depth knowledge about each tool, refer to the Related Courses list and take the corresponding course(s).
l Laker structure、Environment setup、Viewing design
l Basic drawing、Technology File、Import & Export design
l Customize your LAKER、DRC & Third-Party Integration link
Laker L2 Training
l Rule-Driven、Magic cell、User Define Device (UDD)、Path Finder
l P2P router、Route by Label、Laker Advance Function
Synthesis flow?
Application of design constraints?
Optimization strategies?
?
Synthesis of datapath structures?
Synthesis for low power?
Interface to place and route?
Design for testability (optional)?
第二阶段:
q Selecting and Highlighting Objects in the Design
q Floorplanning the Design
q Planning Power?
q Running Detail Placement
q Scan Optimization and Reordering
q Analyzing Route Feasibility with?Trial Route
q Extracting Parasitics and Analyzing Timing
q Multi-Mode Multi-Corner Analysis
q Optimizing and Closing Timing
q Implementing the Clock Tree
q Routing Power with?Special Route
q Analyzing Power Routing Optimization
q Routing for Signal Integrity, Timing, and Design for Yield
q Evaluating Routing Problems
q Wire Editing
q Signal Integrity
寄生参数提取和静态时序分析(Extraction?and?STA)
多模多角分析(MMMC)
时序优化(Timing?Optimization)
时钟树生成(CTS)
电源网络布线(Special?Route)
功耗分析(Power?Analysis)
第三阶段:Laker Schematic Driven Layout Training
Laker SDL 流程介绍
Laker L3 实例教程
练习一:Laker-L3的基本接口操作
练习二:如何将Design读进Laker L3
练习三:Layout的绘制与Stick Diagram的运用
练习四:Laker Net Router的操作
练习五:Matching Creation的运用
练习六:重复电路的画法(Copy Associate & Pattern Reuse)
练习七:ECO的运用 |
