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Diffstat (limited to 'ONBOARDING.md')
| -rw-r--r-- | ONBOARDING.md | 26 |
1 files changed, 16 insertions, 10 deletions
diff --git a/ONBOARDING.md b/ONBOARDING.md index 1b36a72..25f1286 100644 --- a/ONBOARDING.md +++ b/ONBOARDING.md @@ -39,7 +39,7 @@ The binding constraint is **NOT the gradient** — it's **forward fixed-point ST optimization makes attention more expressive/non-conservative, the operator loses contraction, a complex-eigenvalue pair of its Jacobian crosses the imaginary axis (**a supercritical Hopf bifurcation**), the relaxation stops converging (residual → 0.1+), and training breaks. Controls that hold it: **`resreg`** (penalize the T1 residual), -**`jacreg`** (penalize the Jacobian norm), and the new **`eigreg`** (leading-abscissa / log-norm control, §5). +**`jacreg`** (penalize the Jacobian norm), and the new **`eigreg`** (v2: TRUE leading map-eigenvalue / spectral control, §5). > This stability question generalized into a **standalone paper** — *"Dynamics and Convergence of Equilibrium > Learning"* (the report we shared with Ben Scellier is that spin-off, in `/home/yurenh2/aep-dynamics/`): the Hopf + > a leading-spectral-signal cure, shown across MLP/CNN/RNN and across learning rules (EP and DEQ/RBP). ept is the @@ -47,12 +47,16 @@ converging (residual → 0.1+), and training breaks. Controls that hold it: **`r ## 5. Open problems — where you can plug in (ranked) 1. **★ Crack from-scratch below 2.0 (the crux).** We *ultimately need* from-scratch (no magic warm checkpoint) for a - real / hardware result. Diagnosis (via the new `--fingerprint`): the warm source `s2000` is a **deeply contractive** - operator (numerical abscissa −10) with a well-aligned EP gradient; a from-scratch plateau operator sits **near the - Hopf boundary** (abscissa +1.11) with a modestly worse gradient — and *training drifts the operator toward the - boundary as it learns* (val 3.16→2.24 tracks abscissa −10→+1.11). **Hypothesis to test:** hold the operator - deeply-contractive from scratch with `--eigreg` (leading-abscissa control) → crack the plateau without a warm start. - Tools are built and default-off: `diag_cos.py` (`--diag_cos N`, `--fingerprint`), `eig_control.py` (`--eigreg`). + real / hardware result. The stability signal that matters is the **TRUE leading eigenvalue of the forward map** + (`eig_probe.py` FD-JVP — it resolves the complex Hopf pair): the healthy warm source `s2000` sits at Re μ ≈ −0.02, + and un-stabilized runs cross to +0.44 / +1.35 as CE drops. ⚠️ *Retraction (2026-07-03):* an earlier fingerprint + story ("warm = deeply contractive ω=−10 vs scratch = near-boundary ω=+1.11") was a power-iteration artifact — the + gold-standard Lanczos audit (`ep_run/eig_recheck.py`) shows the **numerical abscissa ω is +5..+13 on ALL operators** + (stable and unstable alike; non-normality gap ω−α ≈ 10), so ω / log-norm / Jacobian-norm quantities are **not usable + stability signals** for this operator family. **Hypothesis to test:** control the true map eigenvalue from scratch + with `--eigreg` (v2 = soft one-sided penalty on |λ|_lead(I+εJ_F), the aep-dynamics 'spectral' steering ported to + C512; `eig_control.py::spec_penalty`) → crack the plateau without a warm start. Tools built and default-off: + `diag_cos.py` (`--diag_cos N`, `--fingerprint` — reports ρ / Re μ), `eig_control.py` (`--eigreg`, `--eig_margin 0.995`). 2. **Scaling** to hundreds-of-M / small-LLM (gated on cloud compute — a Scellier/AWS path is in progress). 3. **Speed** (`ep_run/profile_ep.py`, `cos_sweep.py`): the holo a-select is ~56% of the step; `t2sel` is a cosine-preserving speed lever (160→80 ≈ 1.8× free); multi-GPU data-parallel EP is untried. @@ -63,8 +67,10 @@ converging (residual → 0.1+), and training breaks. Controls that hold it: **`r - **`lt_ep_train.py`** — everything: the block, `ep_step` (EP training), `bptt_step` (exact-gradient control), `relax`, `evaluate`, the residual/jacreg controllers, the training loop. The one file to read first. - **`holo_ep.py`** — the adaptive-T2 nudged-phase estimator (`holo_a_select`, `holo_a_track`). -- **`diag_cos.py`** (new) — `cos(EP, BPTT)` trajectory + operator `fingerprint` (res / cos / numerical-abscissa / val). -- **`eig_control.py`** (new) — the `--eigreg` leading-abscissa control (power-iteration, scalable, analog-compatible). +- **`diag_cos.py`** (new) — `cos(EP, BPTT)` trajectory + operator `fingerprint` (res / cos / ρ / Re μ / val). +- **`eig_control.py`** (new) — `--eigreg` v2: TRUE leading map-eigenvalue control (`spec_penalty`, 2-D subspace + iteration, matvec-only, analog-compatible; the ω/numerical-abscissa version is kept as diagnostic only — refuted by + `eig_recheck.py`, the Lanczos audit). - `eig_probe.py`, `cos_sweep.py`, `profile_ep.py`, `bp_transformer.py` (BP baseline) — probes / baselines. - `data/` (TinyStories-BPE, ~712M) and `runs/` (~8G checkpoints) — **git-ignored; get these separately.** @@ -77,7 +83,7 @@ python3 lt_ep_train.py --mode ep --attn_mode thick --B 24 --C 512 --H 16 --T 256 --steps 32000 --data data/tinystories_bpe --ckpt runs/myrun.pt --state runs/myrun.state ``` Diagnostics: add `--diag_cos 500` (log cos-to-BPTT over training) · `--init_ckpt <ckpt> --fingerprint` (print an -operator's 4-D fingerprint) · `--eigreg 0.1 --eig_margin 1.0` (leading-abscissa control, alt to `--jacreg`). +operator's fingerprint: res/cos/ρ/Reμ/val) · `--eigreg 0.1 --eig_margin 0.995` (true map-eigenvalue control, alt to `--jacreg`). BP baseline (fair control): `--mode bptt`. **All experiment processes must use `nohup`.** **Getting the data & checkpoints (git-ignored — not in this repo):** one command. |
