Files
Adriano Dal Pastro 5ac4e16af8 research(alt): sweep 104 strategie alternative su Deribit (153 agenti) + marginal scorer
Ondata di ricerca onesta a largo spettro su BTC/ETH+DVOL certificati: 104 ipotesi
distinte (11 famiglie), un agente-finder per ipotesi, verifica avversariale a 3
scettici sui promettenti, sintesi (153 agenti totali). Esito: NIENTE di nuovo regge
-> conferma del soffitto strutturale ~1.3 BTC/ETH-direzionale; lo stack
TP01+XS01+VRP01 resta imbattuto.

- altlib.py: harness condiviso vettoriale leak-free (eval_weights/study_weights,
  fee-sweep, both-asset + hold-out 2025+). Riproduce i numeri canonici di TP01.
- MARGINAL SCORER (study_marginal/marginal_vs_tp01): Sharpe INCREMENTALE vs baseline
  TP01 (corr, blend uplift OOS, alpha residua) + jackknife OOS (clean-year +
  drop-best-month). earns_slot = abs!=FAIL & ADDS & robust_oos. Smaschera gli overlay
  su TSMOM con PASS assoluti fasulli (CMB04, VOL11, ...) e il falso positivo KAMA
  (ADDS ma muore al jackknife).
- runs/*.py (104) script riproducibili per ipotesi; wf_altstrat.js workflow.
- Verdetto: 0 candidati deployabili; 2 LEAD fragili (VOL08, STA05_LS) da forward-monitor.
- test_marginal_scorer.py blocca baseline + invarianti. Suite: 32 verde.

Diario: docs/diary/2026-06-20-alt-strategies-100agent-sweep.md

Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
2026-06-20 19:50:39 +00:00

258 lines
9.9 KiB
Python

"""CMB03 — Multi-TF trend confirm (4h fast + 1d slow agreement).
HYPOTHESIS: On the 4h TF, go long only when the 1d trend (TSMOM or SMA50)
agrees (is bullish). The intuition is that a fast-TF TSMOM signal might have
more noise; filtering by the slow TF trend reduces false signals.
CAUSAL ALIGNMENT (critical - see obs 4866):
- 1d bar at timestamp T closes at end of day T. The 4h bar that CLOSES at
the same time or later (within day T+1 onwards) can use it causally.
- We compute the 1d signal on the 1d dataframe, then merge_asof onto 4h
using the 1d bar CLOSE timestamp -> the 4h bar is valid only AFTER the
1d bar has fully closed (direction="forward" with offset to avoid using
the still-open 1d bar).
- Implementation: for each 1d bar at timestamp T_close, the signal becomes
available at T_close (the bar just closed). We map it to 4h bars whose
open timestamp >= T_close (i.e. the NEXT 4h bar after the 1d bar closed).
This means we use pandas merge_asof with left=4h open timestamps and
right=1d close timestamps, direction="backward" — the 4h bar at open T
gets the most recent 1d signal where 1d_close <= 4h_open.
GRID (4 configs x 2 assets x 1 TF = 8 backtests):
A: 4h fast TSMOM (1m,3m) + 1d confirm SMA50 (price>SMA50)
B: 4h fast TSMOM (1m,3m) + 1d confirm TSMOM (1m,3m,6m)
C: 4h SMA crossover (20>50) + 1d confirm SMA50
D: 4h SMA crossover (20>50) + 1d confirm TSMOM (1m,3m,6m)
All configs: long-only (0 or +1 direction), vol-targeted (20%, cap 2x).
"""
import sys
sys.path.insert(0, "/opt/docker/PythagorasGoal/scripts/research/alt")
import altlib as al
import numpy as np
import pandas as pd
# ---------------------------------------------------------------------------
# Helper: compute 1d trend signal and align causally to 4h bars
# ---------------------------------------------------------------------------
def _1d_tsmom_signal(df_1d: pd.DataFrame) -> np.ndarray:
"""TSMOM on 1d bars: long if majority of 1m/3m/6m horizons are positive.
Returns array in {0, +1} (long-flat, no short).
Decision at bar i uses close[i] (causal). Array indexed by 1d bar."""
c = df_1d["close"].values.astype(float)
bpd = al.bars_per_day(df_1d) # should be ~1 for 1d
horizons = [30 * bpd, 90 * bpd, 180 * bpd]
votes = np.zeros(len(c))
for h in horizons:
h = int(h)
sig = np.full(len(c), np.nan)
if h < len(c):
sig[h:] = np.sign(c[h:] / c[:-h] - 1.0)
votes += np.nan_to_num(sig, nan=0.0)
# Long when majority (>=1 out of 3) positive
return np.where(votes > 0, 1.0, 0.0)
def _1d_sma50_signal(df_1d: pd.DataFrame) -> np.ndarray:
"""SMA50 trend on 1d: long when close > SMA50. Returns {0, +1}."""
c = df_1d["close"].values.astype(float)
sma50 = al.sma(c, 50)
return np.where(c > sma50, 1.0, 0.0)
def _align_1d_to_4h(df_1d: pd.DataFrame, signal_1d: np.ndarray,
df_4h: pd.DataFrame) -> np.ndarray:
"""Map 1d signal onto 4h bars CAUSALLY.
A 1d bar at timestamp T (which is the bar's OPEN time in ms) closes at
T + 86400000ms. We expose the signal AFTER the 1d bar has fully closed,
i.e. it's available to 4h bars whose open time >= T + 86400000ms (the
start of the next day).
Procedure:
1. Build a series: (1d_close_timestamp, signal_1d)
1d_close_ts = df_1d["timestamp"] + 86400000 (next bar open = this bar closed)
2. For each 4h bar (open timestamp), take the most recent 1d signal
where 1d_close_ts <= 4h_open_ts (merge_asof backward).
3. Forward-fill NaN (no signal yet = 0).
"""
# 1d bar open timestamps + period offset = close timestamp = next 4h eligible
# Compute 1d bar period in ms: use median diff of timestamps
ts_1d = df_1d["timestamp"].values.astype(np.int64)
diffs_1d = np.diff(ts_1d)
period_ms = int(np.median(diffs_1d)) if len(diffs_1d) > 0 else 86_400_000
# 1d_close_ts: the moment this 1d bar closed (= open of the NEXT bar)
close_ts_1d = ts_1d + period_ms # available after this timestamp
right = pd.DataFrame({
"close_ts": close_ts_1d,
"sig": signal_1d.astype(float),
}).sort_values("close_ts")
ts_4h = df_4h["timestamp"].values.astype(np.int64)
left = pd.DataFrame({"open_ts": ts_4h})
merged = pd.merge_asof(
left,
right.rename(columns={"close_ts": "open_ts"}),
on="open_ts",
direction="backward",
)
out = merged["sig"].values.astype(float)
# NaN = no 1d bar has closed yet -> be conservative, no position
out = np.nan_to_num(out, nan=0.0)
return out
# ---------------------------------------------------------------------------
# Fast-TF (4h) signals
# ---------------------------------------------------------------------------
def _4h_tsmom(df_4h: pd.DataFrame) -> np.ndarray:
"""TSMOM on 4h: long if 1m and 3m horizons agree (majority of 2)."""
c = df_4h["close"].values.astype(float)
bpd = al.bars_per_day(df_4h) # ~6 for 4h
h1m = int(30 * bpd)
h3m = int(90 * bpd)
votes = np.zeros(len(c))
for h in [h1m, h3m]:
sig = np.full(len(c), np.nan)
if h < len(c):
sig[h:] = np.sign(c[h:] / c[:-h] - 1.0)
votes += np.nan_to_num(sig, nan=0.0)
# Long when net positive (at least 1 of 2)
return np.where(votes > 0, 1.0, 0.0)
def _4h_sma_cross(df_4h: pd.DataFrame, fast=20, slow=50) -> np.ndarray:
"""SMA crossover on 4h: long when SMA(fast) > SMA(slow)."""
c = df_4h["close"].values.astype(float)
sma_f = al.sma(c, fast)
sma_s = al.sma(c, slow)
return np.where(sma_f > sma_s, 1.0, 0.0)
# ---------------------------------------------------------------------------
# Combined target functions (4h TF, 1d confirm)
# ---------------------------------------------------------------------------
def make_target(asset: str, fast_type: str, slow_type: str):
"""Return a target_fn(df_4h) -> position array.
Because altlib calls target_fn(df) with the chosen TF df, we fetch the
1d df inside the closure (cached by altlib.get).
"""
def target_fn(df_4h: pd.DataFrame) -> np.ndarray:
# 1d dataframe for same asset (cached)
df_1d = al.get(asset, "1d")
# Compute 1d confirmation signal
if slow_type == "sma50":
sig_1d = _1d_sma50_signal(df_1d)
elif slow_type == "tsmom":
sig_1d = _1d_tsmom_signal(df_1d)
else:
raise ValueError(f"Unknown slow_type: {slow_type}")
# Align 1d signal onto 4h bars (causal)
confirm_4h = _align_1d_to_4h(df_1d, sig_1d, df_4h)
# Compute 4h fast signal
if fast_type == "tsmom":
fast_4h = _4h_tsmom(df_4h)
elif fast_type == "sma_cross":
fast_4h = _4h_sma_cross(df_4h)
else:
raise ValueError(f"Unknown fast_type: {fast_type}")
# Combined: long only when BOTH signals agree
direction = np.where((fast_4h > 0) & (confirm_4h > 0), 1.0, 0.0)
# Vol-target (20%, cap 2x)
return al.vol_target(direction, df_4h, target_vol=0.20,
vol_win_days=30, leverage_cap=2.0)
return target_fn
# ---------------------------------------------------------------------------
# Grid: 4 configs
# ---------------------------------------------------------------------------
CONFIGS = [
dict(fast="tsmom", slow="sma50", label="tsmom4h_sma50_1d"),
dict(fast="tsmom", slow="tsmom", label="tsmom4h_tsmom_1d"),
dict(fast="sma_cross", slow="sma50", label="smacross4h_sma50_1d"),
dict(fast="sma_cross", slow="tsmom", label="smacross4h_tsmom_1d"),
]
print("=== CMB03: Multi-TF trend confirm (4h fast + 1d slow) ===")
print(f"Grid: {len(CONFIGS)} configs x 2 assets x 1 TF = {len(CONFIGS)*2} backtests\n")
results = []
for cfg in CONFIGS:
label = cfg["label"]
fast = cfg["fast"]
slow = cfg["slow"]
# Build per-asset target functions
# study_weights calls target_fn(df) for each asset, but we need to know
# WHICH asset to fetch the 1d df for. We use a workaround: wrap in a
# function that identifies the asset by calling al.get for BTC then ETH
# and matching timestamps.
#
# Cleaner approach: run each asset separately and combine.
# altlib.study_weights iterates assets internally, so we need target_fn(df)
# to know the asset. We do this by checking df timestamps against cached dfs.
def _target_fn(df_4h, _fast=fast, _slow=slow):
# Identify asset by matching df timestamps to known cached dfs
ts = df_4h["timestamp"].values[0]
# Try BTC first, then ETH
for _asset in ("BTC", "ETH"):
try:
_df_check = al.get(_asset, "4h")
if _df_check["timestamp"].values[0] == ts:
return make_target(_asset, _fast, _slow)(df_4h)
except Exception:
pass
# Fallback: try matching by length or first close
c0 = df_4h["close"].values[0]
for _asset in ("BTC", "ETH"):
_df_check = al.get(_asset, "4h")
if abs(_df_check["close"].values[0] - c0) / c0 < 0.01:
return make_target(_asset, _fast, _slow)(df_4h)
# Last resort
return make_target("BTC", _fast, _slow)(df_4h)
rep = al.study_weights(
f"CMB03-{label}",
_target_fn,
tfs=("4h",),
)
print(al.fmt(rep))
print(f" JSON: {al.as_json(rep)}\n")
results.append((rep, cfg))
# ---------------------------------------------------------------------------
# Pick best config by min_asset_holdout_sharpe
# ---------------------------------------------------------------------------
def best_holdout(item):
rep = item[0]
cells = rep.get("cells", [])
if not cells:
return -99.0
return max(c.get("min_asset_holdout_sharpe", -99.0) for c in cells)
results.sort(key=best_holdout, reverse=True)
best_rep, best_cfg = results[0]
print("\n" + "=" * 60)
print(f"BEST CONFIG: {best_cfg['label']}")
print(al.fmt(best_rep))
print("JSON:", al.as_json(best_rep))