wip

2025-05-30 19:34:11 +02:00 · 2025-05-30 19:34:11 +02:00 · 630bcf3fc4
commit 630bcf3fc4
parent 38faeedee1
1 changed files with 0 additions and 107 deletions
--- a/process_chunk.py
+++ b/process_chunk.py
@ -1,107 +0,0 @@
 #!/usr/bin/env python3
 """
 Erkennt 211 Hz + 422 Hz (Oberton) in WAV-Dateien.
 Speichert WAV + PNG nur bei Erkennung.
 Blockiert Folgetreffer für definierte Zeit (SKIP_SECONDS).
 """
 import numpy as np
 import soundfile as sf
 from scipy.fft import fft, fftfreq
 import matplotlib.pyplot as plt
 import os
 # === Konfiguration ===
 FILENAME = "1b.flac"
 TARGET_FREQ = 211
 OCTAVE_FREQ = TARGET_FREQ * 2
 TOLERANCE = 1
 THRESHOLD_BASE = 0.3
 THRESHOLD_OCT = THRESHOLD_BASE / 10
 CHUNK_SECONDS = 2
 CLIP_PADDING_BEFORE = 2
 CLIP_PADDING_AFTER = 8
 SKIP_SECONDS = 10
 OUTDIR = "events"
 os.makedirs(OUTDIR, exist_ok=True)
 # === WAV/Audio-Datei laden ===
 data, rate = sf.read(FILENAME, dtype='float32')
 if data.ndim > 1:
    data = data.mean(axis=1)
 samples_per_chunk = int(rate * CHUNK_SECONDS)
 total_chunks = len(data) // samples_per_chunk
 detections = []
 next_allowed_time = 0  # für Skip-Logik
 # === Analyse-Loop ===
 for i in range(total_chunks):
    timestamp = i * CHUNK_SECONDS
    if timestamp < next_allowed_time:
        continue
    segment = data[i * samples_per_chunk : (i + 1) * samples_per_chunk]
    if len(segment) == 0:
        continue
    freqs = fftfreq(len(segment), d=1/rate)
    fft_vals = np.abs(fft(segment))
    pos_mask = freqs > 0
    freqs = freqs[pos_mask]
    fft_vals = fft_vals[pos_mask]
    peak_freq = freqs[np.argmax(fft_vals)]
    peak_mag = np.max(fft_vals)
    # Energien normiert
    mask_base = (freqs >= TARGET_FREQ - TOLERANCE) & (freqs <= TARGET_FREQ + TOLERANCE)
    energy_base = np.mean(fft_vals[mask_base]) / peak_mag
    mask_oct = (freqs >= OCTAVE_FREQ - TOLERANCE) & (freqs <= OCTAVE_FREQ + TOLERANCE)
    energy_oct = np.mean(fft_vals[mask_oct]) / peak_mag
    is_peak_near_target = TARGET_FREQ - TOLERANCE <= peak_freq <= TARGET_FREQ + TOLERANCE
    detected = is_peak_near_target and energy_base > THRESHOLD_BASE and energy_oct > THRESHOLD_OCT
    if detected:
        detections.append((timestamp, round(energy_base, 4), round(energy_oct, 4), round(peak_freq, 2)))
        next_allowed_time = timestamp + SKIP_SECONDS
        # Ausschnitt extrahieren
        start = max(0, int((timestamp - CLIP_PADDING_BEFORE) * rate))
        end = min(len(data), int((timestamp + CLIP_PADDING_AFTER) * rate))
        clip = (data[start:end] * 32767).astype(np.int16)
        base_filename = os.path.join(OUTDIR, f"event_{int(timestamp):04}s")
        wav_name = f"{base_filename}.wav"
        png_name = f"{base_filename}.png"
        # WAV speichern
        sf.write(wav_name, clip, rate, subtype="PCM_24")
        print(f"🟢 WAV gespeichert: {wav_name} (211Hz: {energy_base:.4f}, 422Hz: {energy_oct:.4f}, Peak: {peak_freq:.1f} Hz)")
        # PNG Spektrogramm
        plt.figure(figsize=(10, 4))
        # Verstärke das Signal künstlich, um schwache Ereignisse im dB-Spektrum sichtbarer zu machen
        plt.specgram((clip / 32767.0), NFFT=32768, Fs=rate, noverlap=512, cmap="plasma", vmin=-80, vmax=-35)
        plt.title(f"Ereignis @ {timestamp:.2f}s")
        plt.xlabel("Zeit (s)")
        plt.ylabel("Frequenz (Hz)")
        plt.ylim(0, 1000)
        plt.colorbar(label="Intensität (dB)")
        plt.tight_layout()
        plt.savefig(png_name)
        plt.close()
        print(f"📷 PNG gespeichert: {png_name}")
 # === Zusammenfassung ===
 print("\n🎯 Erkennungen:")
 for ts, eb, eo, pf in detections:
    print(f"- {ts:.2f}s | 211Hz: {eb} | 422Hz: {eo} | Peak: {pf:.1f} Hz")
 if not detections:
    print("→ Keine gültigen Ereignisse erkannt.")