Title: Hardware Safety Methodology for Electronic Systems: A Practitioner's Guide Author: Alexander Novickis (alex.novickis@gmail.com) Functional safety standards require quantitative demonstration that random hardware failures will not cause hazardous events above acceptable probabilities. This paper provides a complete practitioner's guide to ISO 26262 Part 5 hardware safety, covering the full lifecycle from safety goals through validation. We present the FMEDA workflow with five detailed worked examples (MCU, sensor, power supply, FPGA, dual-channel system), a catalog of 30+ safety mechanisms with diagnostic coverage values, and cross-standard comparison across ISO 26262, IEC 61508, DO-254, and EN 50129. New sections cover semiconductor IC design methodology for ASIL compliance (ISO 26262-11), including SEooC development, IC safety manuals, on-chip safety architectures, and qualification strategies. Advanced analysis methods (Markov, HAZOP, STPA, Monte Carlo) and safety verification techniques (fault injection, safety case argumentation) are presented with practical guidance. Failure rate databases (SN 29500, IEC 62380, FIDES, MIL-HDBK-217F) are compared quantitatively. Common architectural, analytical, and process mistakes are documented with lessons learned from real projects. Keywords: functional safety, ISO 26262, IEC 61508, DO-254, EN 50129, FMEDA, FMEA, FTA, HAZOP, STPA, hardware metrics, SPFM, LFM, PMHF, diagnostic coverage, safety mechanisms, ASIL, SIL, semiconductor safety, automotive safety, reliability engineering, safety integrity levels, failure rate databases, SN 29500, IEC 62380, FIDES, MIL-HDBK-217F, fault injection, safety case, dependent failure analysis, SEooC, IC safety manual