5ac4e16af8
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>
292 lines
12 KiB
Python
292 lines
12 KiB
Python
"""OPT07 — Collar Overlay
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IDEA: Long spot + buy protective put + sell covered call (zero-ish cost collar).
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- Long 1 unit spot BTC/ETH
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- Sell OTM call at strike K_call = S * exp(+call_otm * sigma * sqrt(T))
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- Buy OTM put at strike K_put = S * exp(-put_otm * sigma * sqrt(T))
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Net premium ≈ call premium received - put premium paid (can be near-zero or small debit/credit
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depending on the strikes chosen).
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Goal: reduce drawdown vs buy&hold by capping upside (call) and flooring downside (put).
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Does this improve risk-adjusted return (Sharpe)?
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Hypothesis: the vol risk premium means we receive more on the call than we pay for the put
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(IV > RV historically), so the collar should produce a positive carry vs buying naked insurance.
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In a crash the put activates and limits losses. Net effect should be improved Sharpe.
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MODELED: premiums computed via Black-Scholes with DVOL as IV (no skew, no slippage on options).
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DVOL history starts 2021-03 -> backtest from 2021-03 only.
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CAVEAT: modeled, lead-only.
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Grid (4 configs, 1 TF = 4 study_weights calls -> <=8 total backtests):
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1. Symmetric collar: call OTM=0.10, put OTM=0.10 (weekly)
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2. Tighter collar: call OTM=0.05, put OTM=0.05 (weekly)
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3. Asymmetric: call OTM=0.05, put OTM=0.10 (debit collar, more protection, less upside cap)
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4. Asymmetric: call OTM=0.10, put OTM=0.05 (credit collar, less protection, more upside cap)
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Style: study_weights (continuous position ~1x long + option overlay adjustments at settlement).
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"""
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import sys
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sys.path.insert(0, "/opt/docker/PythagorasGoal/scripts/research/alt")
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import altlib as al
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import numpy as np
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import pandas as pd
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from scipy.stats import norm
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# ── Black-Scholes call and put prices ────────────────────────────────────────
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def bs_call(S: float, K: float, T: float, sigma: float, r: float = 0.0) -> float:
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"""Black-Scholes call price. T in years. sigma annualized."""
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if T <= 0 or sigma <= 0 or S <= 0 or K <= 0:
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return 0.0
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d1 = (np.log(S / K) + (r + 0.5 * sigma**2) * T) / (sigma * np.sqrt(T))
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d2 = d1 - sigma * np.sqrt(T)
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return float(S * norm.cdf(d1) - K * np.exp(-r * T) * norm.cdf(d2))
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def bs_put(S: float, K: float, T: float, sigma: float, r: float = 0.0) -> float:
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"""Black-Scholes put price via put-call parity."""
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c = bs_call(S, K, T, sigma, r)
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return float(c - S + K * np.exp(-r * T))
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# ── Collar P&L per settlement cycle ──────────────────────────────────────────
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def collar_cycle_return(S_start: float, S_end: float,
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K_call: float, K_put: float,
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call_prem: float, put_cost: float) -> float:
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"""
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Compute the net return of a collar for one option cycle.
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At initiation:
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- Receive call_prem (sell call)
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- Pay put_cost (buy put)
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Net option carry = call_prem - put_cost (per unit of spot, as fraction of S_start)
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At settlement:
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Spot P&L: S_end / S_start - 1
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Call settled: -max(0, S_end - K_call) / S_start (we're short call)
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Put settled: +max(0, K_put - S_end) / S_start (we're long put)
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Total: (S_end/S_start - 1)
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- max(0, S_end - K_call) / S_start
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+ max(0, K_put - S_end) / S_start
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+ (call_prem - put_cost) / S_start
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Which simplifies to the textbook collar:
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If S_end >= K_call: net = (K_call/S_start - 1) + carry (upside capped)
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If S_end <= K_put: net = (K_put/S_start - 1) + carry (downside floored)
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Otherwise: net = (S_end/S_start - 1) + carry
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"""
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carry = (call_prem - put_cost) / S_start # net option premium (positive = net credit)
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if S_end >= K_call:
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return (K_call / S_start - 1.0) + carry
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elif S_end <= K_put:
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return (K_put / S_start - 1.0) + carry
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else:
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return (S_end / S_start - 1.0) + carry
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# ── Build collar target array ─────────────────────────────────────────────────
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def build_collar_target(close: np.ndarray, sigma_ann: np.ndarray,
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call_otm: float, put_otm: float,
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roll_bars: int, T_years: float) -> np.ndarray:
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"""
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Build a synthetic 'effective position' array for the collar strategy.
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At each bar i, target[i] is held during bar i+1.
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On settlement bars: effective position encodes the full cycle's collar P&L.
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On non-settlement bars (mid-cycle): position = 1.0 (pure spot, no adjustment yet).
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Settlement bar technique (same as OPT01):
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target[i-1] * r_spot[i] ≈ cc_return for the cycle
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For multi-bar cycles: option_adj = collar_r - cycle_spot_r is applied at settlement.
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"""
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n = len(close)
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target = np.ones(n) # default: long spot
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# Find first bar with valid DVOL
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first_valid = np.where(np.isfinite(sigma_ann) & (sigma_ann > 0))[0]
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if len(first_valid) == 0:
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return target
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start_bar = int(first_valid[0])
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r_spot = al.simple_returns(close)
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# Initialize first collar at start_bar
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S0 = close[start_bar]
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sig0 = sigma_ann[start_bar]
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option_K_call = None
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option_K_put = None
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call_prem = 0.0
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put_cost = 0.0
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cycle_start_bar = start_bar
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cycle_start_price = S0
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if sig0 > 0 and np.isfinite(sig0):
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K_call = S0 * np.exp(call_otm * sig0 * np.sqrt(T_years))
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K_put = S0 * np.exp(-put_otm * sig0 * np.sqrt(T_years))
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option_K_call = K_call
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option_K_put = K_put
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call_prem = bs_call(S0, K_call, T_years, sig0)
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put_cost = bs_put(S0, K_put, T_years, sig0)
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for i in range(start_bar + 1, n):
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bars_in_cycle = i - cycle_start_bar
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if option_K_call is None or option_K_put is None:
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# No active collar -> pure spot
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target[i - 1] = 1.0
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# Try to re-initialize
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sig_i = sigma_ann[i]
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if np.isfinite(sig_i) and sig_i > 0:
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S_i = close[i]
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K_call = S_i * np.exp(call_otm * sig_i * np.sqrt(T_years))
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K_put = S_i * np.exp(-put_otm * sig_i * np.sqrt(T_years))
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option_K_call = K_call
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option_K_put = K_put
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call_prem = bs_call(S_i, K_call, T_years, sig_i)
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put_cost = bs_put(S_i, K_put, T_years, sig_i)
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cycle_start_bar = i
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cycle_start_price = S_i
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continue
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if bars_in_cycle >= roll_bars:
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# Settlement bar: compute collar payoff for the full cycle
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S_end = close[i]
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S_start = cycle_start_price
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collar_r = collar_cycle_return(
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S_start, S_end,
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option_K_call, option_K_put,
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call_prem, put_cost
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)
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cycle_spot_r = S_end / S_start - 1.0
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# Encode the option adjustment on the settlement bar
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r_i = r_spot[i]
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option_adj = collar_r - cycle_spot_r # premium carry ± cap/floor adjustments
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if abs(r_i) > 1e-10:
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target[i - 1] = 1.0 + option_adj / r_i
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else:
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# r_spot[i] ≈ 0: no spot movement on settlement bar -> just carry position=1
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# (option_adj can't be embedded cleanly, but it's typically small)
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target[i - 1] = 1.0
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# Roll new collar
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sig_new = sigma_ann[i]
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if np.isfinite(sig_new) and sig_new > 0:
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K_call_new = S_end * np.exp(call_otm * sig_new * np.sqrt(T_years))
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K_put_new = S_end * np.exp(-put_otm * sig_new * np.sqrt(T_years))
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option_K_call = K_call_new
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option_K_put = K_put_new
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call_prem = bs_call(S_end, K_call_new, T_years, sig_new)
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put_cost = bs_put(S_end, K_put_new, T_years, sig_new)
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else:
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option_K_call = None
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option_K_put = None
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call_prem = 0.0
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put_cost = 0.0
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cycle_start_bar = i
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cycle_start_price = S_end
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else:
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# Mid-cycle: hold spot (position=1, no adjustment)
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target[i - 1] = 1.0
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target = np.nan_to_num(target, nan=1.0)
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# Clip extreme values (guard against division artifacts when r_spot ≈ 0)
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target = np.clip(target, -5.0, 5.0)
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return target
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# ── Per-asset runner (wraps study_weights) ────────────────────────────────────
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def run_collar(call_otm: float, put_otm: float, roll_days: int = 7,
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tfs: tuple = ("1d",)) -> dict:
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"""Run collar study for one config. Returns report dict."""
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name = f"OPT07-COLLAR-C{int(call_otm*100)}P{int(put_otm*100)}-roll{roll_days}d"
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T_years = roll_days / 365.25
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cells = []
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for tf in tfs:
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per_asset = {}
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fee_ok_all = True
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for asset in al.CERTIFIED:
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df = al.get(asset, tf)
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sigma_ann = al.dvol(df, asset) / 100.0
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roll_bars = roll_days # 1d tf: 1 bar = 1 day
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tgt = build_collar_target(
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df["close"].values.astype(float),
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sigma_ann,
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call_otm=call_otm,
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put_otm=put_otm,
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roll_bars=roll_bars,
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T_years=T_years
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)
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base = al.eval_weights(df, tgt, fee_side=al.FEE_SIDE)
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sweep = {
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f"{2*f*100:.2f}%RT": al.eval_weights(df, tgt, fee_side=f)["full"]["sharpe"]
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for f in al.FEE_SWEEP
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}
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fee_ok = sweep.get("0.20%RT", -9) > 0
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fee_ok_all = fee_ok_all and fee_ok
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per_asset[asset] = dict(
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full=base["full"], holdout=base["holdout"],
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tim=base["time_in_market"],
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turnover=base["turnover_per_year"],
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fee_sweep=sweep, yearly=base["yearly"]
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)
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min_full = min(per_asset[a]["full"]["sharpe"] for a in al.CERTIFIED)
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min_hold = min(per_asset[a]["holdout"].get("sharpe", 0.0) for a in al.CERTIFIED)
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cells.append(dict(
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tf=tf, per_asset=per_asset,
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min_asset_full_sharpe=round(min_full, 3),
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min_asset_holdout_sharpe=round(min_hold, 3),
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full_sharpe=round(float(np.mean([per_asset[a]["full"]["sharpe"] for a in al.CERTIFIED])), 3),
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fee_survives=fee_ok_all
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))
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verdict = al._verdict(cells)
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return dict(name=name, kind="weights", cells=cells, verdict=verdict)
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# ── Main: small grid ──────────────────────────────────────────────────────────
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if __name__ == "__main__":
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# Grid: 4 configs x 1 TF = 4 study calls = 8 total asset backtests (fine for 2 CPUs)
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CONFIGS = [
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# (call_otm, put_otm, roll_days, description)
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(0.10, 0.10, 7, "symmetric 10%/10% weekly"),
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(0.05, 0.05, 7, "tight 5%/5% weekly"),
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(0.05, 0.10, 7, "debit collar: call 5% / put 10% -> more downside protection"),
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(0.10, 0.05, 7, "credit collar: call 10% / put 5% -> less protection, net credit"),
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]
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print("OPT07 Collar Overlay — MODELED on DVOL (lead-only, from 2021-03)")
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print("Long spot + sell OTM call + buy OTM put (zero-ish cost collar)")
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print()
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best_rep = None
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best_score = -999.0
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for call_otm, put_otm, roll_days, desc in CONFIGS:
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print(f"--- {desc} (call_otm={call_otm}, put_otm={put_otm}, roll={roll_days}d) ---")
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rep = run_collar(call_otm=call_otm, put_otm=put_otm, roll_days=roll_days, tfs=("1d",))
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print(al.fmt(rep))
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score = rep["verdict"].get("best_holdout_sharpe", -9)
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if score > best_score:
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best_score = score
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best_rep = rep
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print()
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print("=" * 60)
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print("BEST CONFIG:")
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print(al.fmt(best_rep))
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print()
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print("JSON:", al.as_json(best_rep))
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