7.4 KiB
RCFA LLM Benchmark Report
Procedure Reference: KPJB-0953-15-WI-05
Dataset: hph_inference_test_set_50.jsonl (50 cases — 25 High, 15 Medium, 10 Low risk)
Hardware: Local inference via Ollama (http://localhost:11434)
Date: 2026-04-28
Evaluated Models: qwen3:4b, qwen3:8b, gemma4:e2b, gemma4:e4b
1. Performance Summary
| Model | Cases | Avg Speed (t/s) | Min Speed | Max Speed | Avg Time/Case | Total Tokens | Avg Tokens/Case |
|---|---|---|---|---|---|---|---|
| qwen3:4b | 50 | 59.4 | 55.5 | 65.2 | 51.2 s | 148,448 | 2,969 |
| qwen3:8b | 50 | 41.0 | 40.1 | 43.8 | 34.3 s | 68,320 | 1,366 |
| gemma4:e2b | 50 | 41.6 | 39.5 | 43.7 | 31.8 s | 62,526 | 1,251 |
| gemma4:e4b | 50 | 28.3 | 27.2 | 29.7 | 60.2 s | 82,364 | 1,647 |
Note:
qwen3:4bis the fastest model by a significant margin at 59.4 t/s, nearly 45% faster than the Gemma variants. However, it generates ~2.4× more tokens per case thangemma4:e2b, which drives up total latency despite the higher token throughput.
2. SOP Compliance (KPJB-0953-15-WI-05)
All five required RCFA sections evaluated: Gejala, Verifikasi Lapangan, Akar Masalah, Dampak Sistem, Rekomendasi FDT.
| Model | 5/5 Cases | SOP Avg | Gejala | Verifikasi | Akar Masalah | Dampak | FDT |
|---|---|---|---|---|---|---|---|
| qwen3:4b | 50/50 (100%) | 5.00/5 | 50 | 50 | 50 | 50 | 50 |
| qwen3:8b | 50/50 (100%) | 5.00/5 | 50 | 50 | 50 | 50 | 50 |
| gemma4:e2b | 50/50 (100%) | 5.00/5 | 50 | 50 | 50 | 50 | 50 |
| gemma4:e4b | 50/50 (100%) | 5.00/5 | 50 | 50 | 50 | 50 | 50 |
Important: All four models achieved perfect SOP compliance (100%) across all 50 test cases. This confirms the prompt template is effective and all models can reliably follow the RCFA SOP structure on this domain. SOP adherence is therefore not a differentiator in this benchmark — harder adversarial prompts are needed to stress-test compliance.
3. Technical Terminology Density
Average count of recognized TJB engineering acronyms per response (HHWL, BFP, DCV, DCA, HPH, RCFA, ECT, DCS, PLC, TTD, PAUT, NDT, PID, FDT, NWL, SSC, MOV).
| Model | Avg Domain Terms / Response | Delta vs. qwen3:4b |
|---|---|---|
| qwen3:4b | 5.2 | baseline |
| qwen3:8b | 7.8 | +50% |
| gemma4:e2b | 6.8 | +31% |
| gemma4:e4b | 8.3 | +60% |
Takeaway: gemma4:e4b uses the richest engineering vocabulary despite generating fewer total tokens than qwen3:4b. qwen3:4b writes longer, more prose-heavy explanations that dilute the domain signal — its low terminology density relative to its token count suggests more generic/padded language.
4. Tag Integrity (Equipment Tag Cross-Contamination)
Checks whether a response accidentally references the wrong equipment tag (e.g., mentioning 3FW-H060 in a case about 3FW-H050).
| Model | Tag Mismatches | Pass Rate |
|---|---|---|
| qwen3:4b | 0 | 100% |
| qwen3:8b | 1 | 98% |
| gemma4:e2b | 0 | 100% |
| gemma4:e4b | 0 | 100% |
Warning:
qwen3:8bproduced 1 tag mismatch across 50 cases. In a real plant maintenance context, an incorrect equipment tag in an RCFA report could direct a crew to the wrong asset — a meaningful safety risk. This should be monitored closely at larger dataset scales.
5. Verbosity vs. Efficiency
| Model | Avg Tokens/Case | Relative Verbosity |
|---|---|---|
| gemma4:e2b | 1,251 | most concise (baseline) |
| qwen3:8b | 1,366 | +9% |
| gemma4:e4b | 1,647 | +32% |
| qwen3:4b | 2,969 | +137% |
qwen3:4b generates 2.4× more tokens than gemma4:e2b for the same SOP compliance score. The extra tokens consist of preambles, repetition, and hedging language that add no measurable structure. Verbosity should be treated as a cost, not a quality signal.
6. Speed vs. Efficiency Trade-off Matrix
Throughput (t/s)
60 | [qwen3:4b] ← fastest clock speed, most tokens
|
42 | [gemma4:e2b] [qwen3:8b] ← fastest wall-clock / case
|
28 | [gemma4:e4b] ← richest terminology, slowest
+------------------------------------------------→ Avg Tokens / Response
1,250 1,650 3,000
- Best for real-time / low latency:
gemma4:e2b— 31.8 s/case avg, zero errors - Best raw throughput (t/s):
qwen3:4b— but penalized by verbosity - Best terminology quality:
gemma4:e4b— limited by hardware, not model quality - Best balance:
qwen3:8b— concise, fast, high domain density (minor tag caveat)
7. Model Recommendations by Use Case
| Use Case | Recommended Model | Rationale |
|---|---|---|
| Real-time operator advisory | gemma4:e2b | Lowest avg time (31.8 s), 100% SOP, zero tag errors |
| Offline batch annotation / RLHF data generation | qwen3:4b | Highest raw throughput; verbose outputs good for preference labeling |
| High-quality RCFA report drafting | gemma4:e4b | Richest domain vocabulary density; most precise phrasing |
| SFT/DPO training data | qwen3:8b | Balanced length + terminology; only minor safety flag |
8. Key Takeaways
-
SOP compliance is fully saturated — all models score 100% on the 5-section check. The prompt engineering is the primary driver. To truly differentiate models, future benchmarks need adversarial prompts and expert-authored ground truth for semantic scoring (BLEU, BERTScore, or domain-expert review).
-
Gemma models are more token-efficient. Both Gemma variants achieve the same SOP coverage with ~55% fewer tokens than qwen3:4b. This matters enormously at inference cost for large-scale annotation runs.
-
qwen3:4b verbosity is a hidden cost. Despite having the highest t/s, running 500 cases with qwen3:4b (~7.1 hours) costs ~60% more compute time than gemma4:e2b (~4.4 hours) solely due to token volume.
-
gemma4:e4b is hardware-constrained, not model-constrained. Its 28.3 t/s and 60.2 s/case latency suggest memory-bandwidth saturation on the current machine. This model would likely outperform all others on better hardware given its terminology density.
-
qwen3:8b has a latent tag-hallucination risk. One cross-equipment tag reference in 50 cases is small but not negligible in safety-critical plant contexts. Monitor carefully and consider tag-anchoring instructions in the prompt.
-
No model exhibited a "weak section" in SOP. All sections (including Verifikasi Lapangan, historically the hardest to elicit) are consistently present. This suggests the FMEA context injection in the prompt is sufficient scaffolding for all models.
9. Next Steps
- Expand to 200+ cases with out-of-distribution failure modes (multi-equipment incidents, ambiguous indications, missing FMEA fields)
- Add semantic scoring (BERTScore / cosine similarity) against expert-written ground truth RCFA reports
- Run adversarial prompts to find SOP compliance failure thresholds for each model
- Use the
⭐ Best ResponseRLHF export ininference_results_viewer.htmlto collect preference labels for DPO fine-tuning - Re-benchmark
gemma4:e4bon upgraded hardware (expected significant throughput improvement) - Evaluate
num_ctxsensitivity: test 4096 vs. 8192 and measure whether longer context improves FDT specificity
Generated by the RCFA Benchmarking Pipeline — ollama_benchmark.py + inference_results_viewer.html
Analysis script: analyze_bench.py