serial_audio_catcher/tdoa_sharp_noises.py

import numpy as np
import time
from datetime import datetime

FIFO_PATH = "/tmp/esp32_audio"
SAMPLE_RATE = 16000
CHANNELS = 2
BYTES_PER_SAMPLE = 2

# Detection and processing params
BLOCK_FRAMES = 2048          # ~128 ms @16k; large enough to catch an impulse
IMPULSE_WINDOW = 256         # samples around the detected peak for GCC-PHAT
BAND_LOW = 1000              # Hz
BAND_HIGH = 4000             # Hz
MARGIN = 3.0                 # multiplier above rolling baseline for impulse detection
ALPHA = 0.01                 # rolling baseline EMA smoothing
COOLDOWN = 0.5               # seconds; suppress retriggers from echoes

# Geometry
MIC_DISTANCE = 0.20          # meters between microphones
SPEED_OF_SOUND = 343.0       # m/s

def read_block(f, block_bytes):
    data = f.read(block_bytes)
    if not data or len(data) < block_bytes:
        return None
    return np.frombuffer(data, dtype=np.int16)

def bandpass_fft(x, fs, low, high):
    """Simple FFT band-pass: zero out bins outside [low, high]."""
    n = len(x)
    X = np.fft.rfft(x)
    freqs = np.fft.rfftfreq(n, d=1.0/fs)
    mask = (freqs >= low) & (freqs <= high)
    X_filtered = X * mask
    x_filtered = np.fft.irfft(X_filtered, n=n)
    return x_filtered.astype(x.dtype)

def gcc_phat(sig, refsig, fs, max_tau=None, interp=1):
    """
    GCC-PHAT lag estimation between sig and refsig.
    Returns time delay (tau) in seconds.
    """
    n = sig.shape[0] + refsig.shape[0]
    # FFT
    SIG = np.fft.rfft(sig, n=n)
    REFSIG = np.fft.rfft(refsig, n=n)
    R = SIG * np.conj(REFSIG)
    denom = np.abs(R)
    R = R / (denom + 1e-15)
    cc = np.fft.irfft(R, n=(interp * n))

    if max_tau is None:
        # physical max tau based on mic distance
        max_tau = MIC_DISTANCE / SPEED_OF_SOUND

    max_shift = int(interp * fs * max_tau)
    mid = cc.shape[0] // 2
    cc = np.concatenate((cc[mid - max_shift: mid + max_shift + 1],))
    shift = np.argmax(cc) - max_shift
    tau = shift / float(interp * fs)
    return tau

def tau_to_angle(tau, mic_distance, speed_of_sound):
    """
    Convert time difference to angle (-90..+90) assuming linear 2-mic array and far-field.
    """
    # clamp sin argument to [-1,1]
    arg = (tau * speed_of_sound) / mic_distance
    arg = max(-1.0, min(1.0, arg))
    angle_rad = np.arcsin(arg)
    return np.degrees(angle_rad)

def main():
    block_bytes = BLOCK_FRAMES * CHANNELS * BYTES_PER_SAMPLE
    baseline = None
    last_trigger = 0.0

    with open(FIFO_PATH, "rb") as f:
        print("Listening: GCC-PHAT + impulse window + band-pass + cooldown")
        while True:
            audio = read_block(f, block_bytes)
            if audio is None:
                continue

            # Split stereo
            left = audio[0::2]
            right = audio[1::2]

            # Compute per-block peak level for rolling baseline
            left_peak = np.max(np.abs(left))
            right_peak = np.max(np.abs(right))
            current_level = (left_peak + right_peak) / 2.0

            if baseline is None:
                baseline = current_level
                continue
            baseline = (1 - ALPHA) * baseline + ALPHA * current_level
            threshold = baseline * MARGIN

            # Cooldown gate
            now = time.time()
            if now - last_trigger < COOLDOWN:
                continue

            # Impulse gate: only proceed if strong spike above rolling threshold
            if max(left_peak, right_peak) <= threshold:
                continue

            # Find impulse index using combined magnitude
            combined = np.abs(left) + np.abs(right)
            peak_idx = int(np.argmax(combined))

            # Window around impulse for robust localization
            half = IMPULSE_WINDOW // 2
            start = max(0, peak_idx - half)
            end = min(len(left), peak_idx + half)
            l_win = left[start:end]
            r_win = right[start:end]

            # Band-pass to 1–4 kHz to reduce low rumble/high hiss
            l_bp = bandpass_fft(l_win.astype(np.float32), SAMPLE_RATE, BAND_LOW, BAND_HIGH)
            r_bp = bandpass_fft(r_win.astype(np.float32), SAMPLE_RATE, BAND_LOW, BAND_HIGH)

            # GCC-PHAT for TDOA
            # cap max_tau to physical limit to avoid spurious peaks
            max_tau = MIC_DISTANCE / SPEED_OF_SOUND
            tau = gcc_phat(l_bp, r_bp, SAMPLE_RATE, max_tau=max_tau, interp=1)
            angle = tau_to_angle(tau, MIC_DISTANCE, SPEED_OF_SOUND)

            # Timestamp and report
            ts = datetime.now().strftime("%Y-%m-%d %H:%M:%S.%f")[:-3]
            louder = "LEFT" if left_peak > right_peak else "RIGHT"
            print(f"[{ts}] Loud impulse: {louder} louder | TDOA={tau*1000:.2f} ms | angle≈{angle:.1f}° "
                  f"(baseline={baseline:.1f}, L={left_peak}, R={right_peak})")

            # Arm cooldown
            last_trigger = now

if __name__ == "__main__":
    main()