StarVLSI Reader Quiz – Set 2 - VLSI training and placement

StarVLSI Reader Quiz – Test Your Physical Design Knowledge

You’ve explored the fundamentals of Physical Design, from floorplanning and placement to timing, power integrity, and advanced-node challenges. Now it’s time to check how well those concepts actually stuck.

This quiz is based on key ideas discussed in the StarVLSI blog series and reflects real-world scenarios faced in SoC physical design. It’s meant to test understanding, not memory tricks.

👉 Instructions:

Each question has one correct answer
Choose the best option for each
Answer keys will be shared 2–3 days after the quiz is published

Take your time. Think like a physical design engineer. Silicon doesn’t forgive guesswork.

Name

Contact Number

In large SoC floorplanning, macros should be placed first primarily to:

Reduce synthesis runtime

Improve LVS convergence

Optimize scan insertion

Minimize routing congestion and timing bottlenecks

Improper die aspect ratio most directly affects:

RTL simulation performance

Netlist hierarchy

IO protocol compatibility

Routing congestion and clock distribution

When planning multiple power domains, isolation cells must be:

Added after CTS

Placed during DRC fixing

Inserted during packaging

Inserted at domain boundaries before placement

High congestion after global placement is usually due to:

Improper STA constraints

Incorrect synthesis library

DRC violations

Poor macro placement and pin density

Cell density constraints are applied to:

Reduce EM violations

B. Improve LVS correlation

Balance clock skew

Control routability and congestion

Target skew in high-performance SoCs is minimized to:

Reduce DRC violations

Improve power ring alignment

Optimize IO placement

Improve setup and hold margins

Clock buffers are inserted mainly to:

Reduce routing layers

Improve LVS matching

Increase die utilization

Balance clock latency and skew

Crosstalk noise is minimized by:

Increasing clock skew

Reducing cell density

Increasing die size

Shielding and spacing critical nets

Global routing primarily produces:

Final metal connections

Signoff parasitics

Power grid mesh

Estimated routing paths and congestion maps

Setup violations are typically fixed by:

Reducing power grid width

Increasing EM margin

Adjusting IO pads

Buffer insertion and path optimization

Engineering Change Orders (ECO) are used:

Before synthesis

During macro placement

During packaging

After routing to fix timing or functional issues

IR drop issues are mainly resolved by:

Increasing clock buffers

Reducing skew

Changing macro orientation

Strengthening power grid and adding straps

Electromigration risk increases with:

Low switching activity

Reduced metal width

Increased routing layers

High current density and temperature

LVS verifies:

Timing closure

Power integrity

Placement legality

Layout connectivity matches schematic/netlist

DRC ensures:

Functional correctness

Timing closure

ECO validation

Compliance with fabrication rules

Correct Physical Design flow order:

Placement → Floorplan → Routing → CTS

CTS → Placement → Routing → Floorplan

Routing → Floorplan → CTS → Placement

Floorplan → Placement → CTS → Routing → Signoff

Post-route STA uses:

RTL simulation vectors

Floorplan constraints

Scan chains

Extracted parasitics (SPEF)

Which packaging trend enables stacking of multiple dies vertically?

Flip-chip packaging

Wafer bonding

Wire bonding

3D-IC integration

Which emerging trend is improving physical design automation?

FPGA prototyping

Analog circuit modeling

Manual layout techniques

AI-driven EDA optimization

In advanced nodes, which factor is increasingly dominant in determining performance?

Transistor switching speed only

Package size

Synthesis runtime

Interconnect delay and resistance

You’ve Completed the Quiz

Nice work making it to the end. Physical Design isn’t about memorizing tools or buzzwords. It’s about understanding trade-offs, constraints, and why things break when you least want them to.

We’ll be publishing the answer key in 2–3 days, along with brief explanations to help you review the concepts and spot gaps in understanding.

Until then, reflect on the questions you found tricky. Those usually point to areas that matter most in real projects and interviews.

Keep learning. Silicon rewards preparation, not optimism.

StarVLSI Reader Quiz – Set 2

StarVLSI Reader Quiz – Test Your Physical Design Knowledge

You’ve Completed the Quiz

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