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model.py β Specialised HΞ± encoder (Stage 1 HΞ±) with MAE.
Compact version of SpectralEncoder adapted for spectra cropped
to 128 bins around HΞ± (6512.8β6612.8 Γ
).
Architecture :
Spectre HΞ± [128] β Patches [31, 8] β Projection [31, 128]
β + Wavelength PE β Masquage 60% β [CLS] + Visibles [~13, 128]
β Transformer 4L β CLS embedding z_halpha [128]
β MAE Decoder [reconstruction]
Key differences from the full encoder (stage1/model.py):
- Input : 128 bins (vs 4096)
- Patches : 8 px, overlap 4, step 4 β 31 patches (vs 511)
- d_model : 128 (vs 256)
- n_layers : 4 (vs 6)
- No GRL/discriminator (negative result confirmed)
- ~300K params (vs ~5.3M)
"""
import math
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
from config import ModelConfig
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
# MASQUAGE CONTIGU
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
def contiguous_masking(n_patches: int, mask_ratio: float = 0.60,
n_blocks: int = 3) -> np.ndarray:
"""
Generate a contiguous-block mask for MAE.
Adapted for 31 patches (vs 511 for the full encoder):
- 60% masking β ~19 masked patches, ~12 visible
- 3 contiguous blocks (vs 4) because the sequence is short
Avec 12 patches visibles + 1 CLS = 13 tokens pour l'encodeur.
C'est suffisant pour un Transformer 4 couches.
"""
n_masked = int(n_patches * mask_ratio)
if n_masked == 0 or n_patches < n_blocks:
return np.zeros(n_patches, dtype=bool)
mask = np.zeros(n_patches, dtype=bool)
block_size = max(1, n_masked // n_blocks)
possible_starts = np.arange(0, max(1, n_patches - block_size))
if len(possible_starts) < n_blocks:
starts = possible_starts
else:
starts = np.sort(
np.random.choice(possible_starts, size=n_blocks, replace=False)
)
for s in starts:
end = min(s + block_size, n_patches)
mask[s:end] = True
# Fill if necessary
current = mask.sum()
if current < n_masked:
unmasked = np.where(~mask)[0]
extra = min(n_masked - current, len(unmasked))
if extra > 0:
chosen = np.random.choice(unmasked, size=extra, replace=False)
mask[chosen] = True
return mask
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
# ENCODAGE POSITIONNEL PAR LONGUEUR D'ONDE
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
class WavelengthPE(nn.Module):
"""
Sinusoidal positional encoding based on wavelength (Γ
).
Identique au full encoder : PE(Ξ») = sin/cos(Ξ» / 10000 Γ div_term).
Even over a 100 Γ
window, the relative position is physically
significative : les ailes bleue (Ξ» < 6562.8) et rouge (Ξ» > 6562.8)
of HΞ± have different physical meanings (V/R ratio, asymmetries).
"""
def __init__(self, d_model: int = 128):
super().__init__()
self.d_model = d_model
div_term = torch.exp(
torch.arange(0, d_model, 2).float() * (-math.log(10000.0) / d_model)
)
self.register_buffer("div_term", div_term)
def forward(self, lambda_means: torch.Tensor) -> torch.Tensor:
"""
lambda_means: [B, N_patches] β Ξ» moyen de chaque patch (en Γ
).
Retourne: [B, N_patches, d_model].
"""
pos = lambda_means.unsqueeze(-1) / 10000.0
pe = torch.zeros(*lambda_means.shape, self.d_model,
device=lambda_means.device)
pe[..., 0::2] = torch.sin(pos * self.div_term)
pe[..., 1::2] = torch.cos(pos * self.div_term)
return pe
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
# DΓCODEUR MAE
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
class MAEDecoder(nn.Module):
"""
Lightweight MAE decoder for reconstructing masked HΞ± patches.
Smaller than the full encoder decoder:
- d_decoder = 64 (vs 128)
- n_layers = 2
- head projette vers patch_size = 8 (vs 16)
"""
def __init__(self, d_encoder: int, d_decoder: int, n_layers: int,
n_heads: int, patch_size: int):
super().__init__()
self.d_decoder = d_decoder
# Projection encoder β decoder
self.proj = nn.Linear(d_encoder, d_decoder)
# Mask token appris
self.mask_token = nn.Parameter(torch.randn(1, 1, d_decoder) * 0.02)
# Decoder mini-Transformer
decoder_layer = nn.TransformerEncoderLayer(
d_model=d_decoder, nhead=n_heads,
dim_feedforward=d_decoder * 4,
activation="gelu", batch_first=True, dropout=0.1,
)
self.decoder = nn.TransformerEncoder(decoder_layer, num_layers=n_layers)
# Prediction head: d_decoder β patch_size
self.head = nn.Linear(d_decoder, patch_size)
def forward(self, encoded_visible, visible_pe, full_pe, mask):
"""
Reconstruct masked patches.
Inputs:
encoded_visible : [B, N_vis, d_encoder]
visible_pe : [B, N_vis, d_decoder]
full_pe : [B, N_all, d_decoder]
mask : [B, N_all] β True = masked
Output:
[B, N_all, patch_size]
"""
B, N_all = mask.shape
vis = self.proj(encoded_visible)
full_seq = self.mask_token.expand(B, N_all, -1).clone()
vis_positions = (~mask)
full_seq[vis_positions] = vis.reshape(-1, self.d_decoder)
full_seq = full_seq + full_pe
decoded = self.decoder(full_seq)
return self.head(decoded)
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
# ENCODEUR SPECTRAL HΞ±
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
class SpectralEncoderHalpha(nn.Module):
"""
MAE Transformer encoder for cropped HΞ± spectra (128 bins).
Pipeline interne :
1. Patchify : split into 31 patches of 8 pixels (step=4)
2. Projection : chaque patch [8] β token [128]
3. PE : positional encoding based on Ξ»
4. Masquage : ne garde que ~40% des patches (12 visibles)
5. [CLS] : global summary token
6. Transformer : 4 couches d'auto-attention
7. Sortie : z_halpha = LayerNorm(CLS) β β^128
Avec 128 bins au lieu de 4096 :
- 31 patches au lieu de 511
- 12 visibles au lieu de 153
- ~10Γ faster to run
"""
def __init__(self, cfg: ModelConfig):
super().__init__()
self.cfg = cfg
self.patch_size = cfg.patch_size
self.patch_overlap = cfg.patch_overlap
self.d_model = cfg.d_model
self.step = cfg.patch_size - cfg.patch_overlap # = 4
# Projection patch β token
self.patch_proj = nn.Linear(cfg.patch_size, cfg.d_model)
# Encodage positionnel
self.wave_pe = WavelengthPE(cfg.d_model)
# Token CLS
self.cls_token = nn.Parameter(torch.randn(1, 1, cfg.d_model) * 0.02)
# Transformer
encoder_layer = nn.TransformerEncoderLayer(
d_model=cfg.d_model,
nhead=cfg.n_heads,
dim_feedforward=cfg.d_ff,
dropout=cfg.dropout,
activation="gelu",
batch_first=True,
)
self.encoder = nn.TransformerEncoder(
encoder_layer, num_layers=cfg.n_layers
)
# Normalisation finale
self.norm = nn.LayerNorm(cfg.d_model)
def patchify(self, flux, wavelengths, validity):
"""
Split the 128-bin spectrum into 31 patches of 8 pixels.
Avec step=4 : N = (128 - 8) / 4 + 1 = 31 patches
"""
patches = flux.unfold(-1, self.patch_size, self.step)
lam_patches = wavelengths.unfold(-1, self.patch_size, self.step)
val_patches = validity.unfold(-1, self.patch_size, self.step)
lambda_means = lam_patches.mean(-1)
patch_valid = val_patches.mean(-1)
return patches, lambda_means, patch_valid
def forward(self, flux, wavelengths, validity, mask=None):
"""
Forward pass.
Inputs:
flux : [B, 128]
wavelengths : [B, 128]
validity : [B, 128]
mask : [B, 31] optional
Outputs:
z : [B, d_model] β CLS embedding (z_halpha)
encoded : [B, N_vis, d_model] β encoded visible tokens
patches : [B, 31, 8] β all patches
lambda_means : [B, 31] β mean Ξ» per patch
mask : [B, 31] β mask used
wpe : [B, 31, d_model] β positional encoding
"""
B = flux.shape[0]
# Patchify
patches, lambda_means, patch_valid = self.patchify(
flux, wavelengths, validity
)
N = patches.shape[1]
# Projection + PE
tokens = self.patch_proj(patches)
wpe = self.wave_pe(lambda_means)
tokens = tokens + wpe
# Masquage MAE
if mask is None:
mask = torch.zeros(B, N, dtype=torch.bool, device=flux.device)
visible_mask = ~mask
n_visible = visible_mask[0].sum().item()
visible_tokens = tokens[visible_mask].view(B, n_visible, self.d_model)
visible_pe = wpe[visible_mask].view(B, n_visible, self.d_model)
# CLS + tokens visibles
cls = self.cls_token.expand(B, -1, -1)
input_tokens = torch.cat([cls, visible_tokens], dim=1)
# Masque d'attention
visible_valid = patch_valid[visible_mask].view(B, n_visible)
attn_pad = torch.cat([
torch.ones(B, 1, device=flux.device),
(visible_valid > 0.1).float()
], dim=1)
src_key_padding_mask = (attn_pad == 0)
# Transformer
encoded = self.encoder(
input_tokens, src_key_padding_mask=src_key_padding_mask
)
# Embedding CLS
z = self.norm(encoded[:, 0])
return z, encoded[:, 1:], patches, lambda_means, mask, wpe
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
# MODΓLE COMPLET β STAGE 1 HΞ±
# ββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββββ
class Stage1HalphaModel(nn.Module):
"""
Assembly: HΞ± Encoder + MAE Decoder.
No instrument discriminator (GRL removed).
The only loss is the MAE reconstruction of masked patches.
"""
def __init__(self, model_cfg: ModelConfig):
super().__init__()
self.encoder = SpectralEncoderHalpha(model_cfg)
self.mae_decoder = MAEDecoder(
d_encoder=model_cfg.d_model,
d_decoder=model_cfg.d_decoder,
n_layers=model_cfg.n_decoder_layers,
n_heads=model_cfg.n_decoder_heads,
patch_size=model_cfg.patch_size,
)
# PE projection for the decoder
self.pe_proj = nn.Linear(model_cfg.d_model, model_cfg.d_decoder)
def forward(self, flux, wavelengths, validity, mask):
"""
Forward pass : encoder β reconstruction MAE.
Inputs:
flux : [B, 128]
wavelengths : [B, 128]
validity : [B, 128]
mask : [B, 31] β MAE mask
Returns:
z : [B, 128] β CLS embedding (z_halpha)
mae_loss : scalar β MSE reconstruction of masked patches
reconstructed : [B, 31, 8] β patches reconstruits
patches : [B, 31, 8] β patches originaux (cible)
mask : [B, 31] β mask used
"""
# Encode
z, encoded_vis, patches, lambda_means, mask, wpe = self.encoder(
flux, wavelengths, validity, mask
)
B, N, P = patches.shape
# PE for the decoder
full_pe = self.pe_proj(wpe)
vis_mask = ~mask
n_vis = vis_mask[0].sum().item()
vis_pe = full_pe[vis_mask].view(B, n_vis, -1)
# MAE decoding
reconstructed = self.mae_decoder(encoded_vis, vis_pe, full_pe, mask)
# MAE loss: MSE on masked patches only
target = patches
mae_loss = ((reconstructed - target) ** 2)
mask_expanded = mask.unsqueeze(-1).expand_as(mae_loss)
n_masked_total = mask_expanded.sum()
if n_masked_total > 0:
mae_loss = (mae_loss * mask_expanded.float()).sum() / n_masked_total
else:
mae_loss = mae_loss.mean()
return {
"z": z,
"mae_loss": mae_loss,
"reconstructed": reconstructed,
"patches": patches,
"mask": mask,
}
def get_embeddings(self, flux, wavelengths, validity):
"""
Inference mode: CLS embeddings without masking.
Retourne z_halpha β β^128.
"""
z, _, _, _, _, _ = self.encoder(flux, wavelengths, validity, mask=None)
return z
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