Silicon Debug Engineer
Beaverton, OR, USA
Posted on Jun 24, 2026
Do you have a passion for solving the hardest problems in silicon? Do you thrive at the intersection of circuit theory, device physics, and hands-on failure investigation? As part of our Silicon Debug group, you'll take complex, often elusive silicon failures and systematically uncover their root cause — from electrical characterization all the way down to physical analysis. You and your team will apply deep engineering fundamentals and cutting-edge failure analysis techniques to enable product ramp at scale. Your efforts will directly impact the quality and reliability of state-of-the-art ASICs that power experiences for millions of customers worldwide. Join us, and you'll play a central role in ensuring the silicon we build is everything it needs to be. We have an extraordinary opportunity for Silicon Debug Engineers to investigate and root-cause failures in advanced custom digital megacells (SRAM memories, on-chip sensors, custom data paths) used in high-performance, low-power SoCs. You will bridge the gap between electrical debug and physical failure analysis, working at the frontier of silicon investigation.
Imagine yourself at the center of our SoC bring-up and product ramp effort, collaborating across circuit design, process engineering, DFT, and failure analysis teams — with a critical impact on getting functional products to millions of customers quickly.
- Drive the silicon debug effort involving custom circuits from initial bring-up through volume ramp, owning failure isolation from symptom to root cause.
- Work with circuit design teams to define silicon characterization and debug requirements for test chips and product chips.
- Engage with PE / DFT / FA teams to plan and execute electrical and physical characterization strategies.
- Perform design analysis, modeling/simulation, SPICE simulation, statistical analysis, and silicon bring-up to understand and reproduce failure signatures.
- Work closely with systems and lab teams to reproduce circuit-level behavior using MBIST, functional diagnostics, and characterization structures.
- Plan and interpret FA analysis — translating electrical failure signatures into targeted physical analysis strategies and understanding how FA technique choices impact observable circuit behavior.
- Leverage eFA and pFA techniques including Dynamic Laser Stimulus (DLS), Lock-in Thermography (LIT), Nanoprobe, Focused Ion Beam (FIB), TEM/SEM, EMMI, and Physical Failure Analysis (PFA) to identify defect mechanisms and localize failures to specific circuit nodes.
- Understand the circuit impact of FA techniques — including how photon emission, voltage contrast, charge injection, sample preparation, and probe-induced perturbations may influence or mask failure modes during analysis.
- BSEE/MSEE
- Experience in one or more of the following areas: SRAM circuits, custom circuit design, silicon debug.
- Experience in design or debug of low-voltage / low-power custom circuits.
- Deep understanding of deep-submicron device physics, leakage mechanisms, and technology interactions with device behavior.
- Solid understanding of device matching, device noise sources (1/f, thermal), extrinsic noise sources (supply noise, jitter), and their impact on high-precision circuits.
- Familiarity with electrical failure analysis (eFA) techniques and physical failure analysis (pFA) workflows, and the ability to plan FA strategies based on electrical debug data.
- Understanding of Dynamic Lock-in Thermography (DLS) and Lock-in Thermography (LIT) for localization of resistive and leakage defects, including their sensitivity limits and how thermal signatures correlate to specific circuit fault modes.
- Knowledge of Nanoprobe techniques for electrical probing of deep-submicron nodes, and appreciation of how probe contact, voltage bias, and electron beam exposure can perturb sensitive analog or memory circuits.
- Awareness of how physical sample preparation steps (deprocessing, FIB cross-section, delayering) can alter or destroy evidence of electrical failures, and how to coordinate FA plans that preserve failure signatures.
- Ability to interpret FA results (photon emission maps, OBIRCH, thermal maps, TEM/SEM imagery) in the context of circuit topology and failure electrical signatures.
- Ability to conduct structured experiments during silicon debug, gather and analyze large datasets, and utilize scripting to support efficient handling of debug data.
- Proficiency in scripting languages (Python, Perl, or others) and CAD automation tools.
- Knowledge of industry-standard circuit design and simulation tools.