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NawfalMotii79-PLFM_RADAR/9_Firmware/9_3_GUI/v7/processing.py
T
Jason 8ebb7016de chore(repo): PR-S — m-1..m-9 hygiene sweep (audit cleanup) 
Bundled minor-tier fixes from project_aeris10_audit_2026-05-02. No
behavioural changes to the production happy path; mostly stale comments,
defaults, and one new emit-path (m-9) that lets cosim_dir replay show
detections instead of an empty mask.

  m-1 — processing.py:59 RadarProcessor.range_doppler_map placeholder
        shape (1024, 32) -> (NUM_RANGE_BINS, NUM_DOPPLER_BINS) imported
        from radar_protocol so the legacy literal stops leaking to
        anything reading the attribute before frame 0.
  m-2 — radar_receiver_final.v:596 stale "// 32" comment for
        RP_CHIRPS_PER_FRAME -> "// 48 (PR-F: 3 sub-frames * 16)".
  m-4 — radar_protocol.py "16384 x 2 = 32768" arithmetic comment was
        already corrected by an earlier edit; verified clean.
  m-5 — usb_data_interface_ft2232h.v:961 "Frame header: 8 bytes"
        comment -> "9 bytes (PR-G: added version byte at offset 1)".
  m-6 — radar_system_top.v cold-reset host_chirps_per_elev 32 -> 48
        + status doc-comment so any sanity-checking parser sees the
        value matching RP_CHIRPS_PER_FRAME instead of latching a
        chirps_mismatch_error.
  m-7 — radar_receiver_final.v:370 RX DDC mixers_enable(1'b1)
        annotated: documented as intentional asymmetry vs TX (counter-
        UAS RX has no quiesce scenario; CDC would add cost without
        operational benefit).
  m-8 — RadarSettings range_resolution / velocity_resolution flagged
        inline as PLACEHOLDER (docstring already explains; inline
        marker makes it visible at the field).
  m-9 — gen_realdata_hex.py now also emits fullchain_cfar_flags.npy
        (uint8 detection mask) and fullchain_cfar_mag.npy (|I|+|Q|),
        produced by run_cfar_ca() with the FPGA cold-reset defaults
        (guard=2 train=8 alpha=0x30 mode=CA). Replays through
        v7.replay's COSIM_DIR loader: 22 detections on the synthetic
        scene (was 0). The hex/ directory's two new .npy files are
        included in this commit.

Regression: 247/247 (test_v7 130 + test_GUI_V65_Tk 117). Ruff clean.
2026-05-02 17:13:12 +05:45

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"""
v7.processing — Radar signal processing and GPS parsing.
Classes:
- RadarProcessor — dual-CPI fusion, multi-PRF unwrap, DBSCAN clustering,
association, Kalman tracking
- USBPacketParser — parse GPS text/binary frames from STM32 CDC
Note: RadarPacketParser (old A5/C3 sync + CRC16 format) was removed.
All packet parsing now uses production RadarProtocol (0xAA/0xBB format)
from radar_protocol.py.
"""
import struct
import time
import logging
import math
import numpy as np
from .models import (
RadarTarget, GPSData, ProcessingConfig,
SCIPY_AVAILABLE, SKLEARN_AVAILABLE, FILTERPY_AVAILABLE,
)
if SKLEARN_AVAILABLE:
from sklearn.cluster import DBSCAN
if FILTERPY_AVAILABLE:
from filterpy.kalman import KalmanFilter
if SCIPY_AVAILABLE:
from scipy.signal import windows as scipy_windows
logger = logging.getLogger(__name__)
# =============================================================================
# Utility: pitch correction (Bug #4 fix — was never defined in V6)
# =============================================================================
def apply_pitch_correction(raw_elevation: float, pitch: float) -> float:
"""
Apply platform pitch correction to a raw elevation angle.
Returns the corrected elevation = raw_elevation - pitch.
"""
return raw_elevation - pitch
# =============================================================================
# Radar Processor — signal-level processing & tracking pipeline
# =============================================================================
class RadarProcessor:
"""Full radar processing pipeline: fusion, clustering, association, tracking."""
def __init__(self):
# Placeholder shape matches production (NUM_RANGE_BINS x NUM_DOPPLER_BINS
# = 512 x 48 from radar_protocol). Overwritten on every frame; pre-frame
# readers see the correct shape rather than a legacy (1024, 32).
from radar_protocol import NUM_RANGE_BINS, NUM_DOPPLER_BINS
self.range_doppler_map = np.zeros((NUM_RANGE_BINS, NUM_DOPPLER_BINS))
self.detected_targets: list[RadarTarget] = []
self.track_id_counter: int = 0
self.tracks: dict[int, dict] = {}
self.frame_count: int = 0
self.config = ProcessingConfig()
# MTI state: store previous frames for cancellation
self._mti_history: list[np.ndarray] = []
# ---- Configuration -----------------------------------------------------
def set_config(self, config: ProcessingConfig):
"""Update the processing configuration and reset MTI history if needed."""
old_order = self.config.mti_order
self.config = config
if config.mti_order != old_order:
self._mti_history.clear()
# ---- Windowing ----------------------------------------------------------
@staticmethod
def apply_window(data: np.ndarray, window_type: str) -> np.ndarray:
"""Apply a window function along each column (slow-time dimension).
*data* shape: (range_bins, doppler_bins). Window is applied along
axis-1 (Doppler / slow-time).
"""
if window_type == "None" or not window_type:
return data
n = data.shape[1]
if n < 2:
return data
if SCIPY_AVAILABLE:
wtype = window_type.lower()
if wtype == "hann":
w = scipy_windows.hann(n, sym=False)
elif wtype == "hamming":
w = scipy_windows.hamming(n, sym=False)
elif wtype == "blackman":
w = scipy_windows.blackman(n)
elif wtype == "kaiser":
w = scipy_windows.kaiser(n, beta=14)
elif wtype == "chebyshev":
w = scipy_windows.chebwin(n, at=80)
else:
w = np.ones(n)
else:
# Fallback: numpy Hann
wtype = window_type.lower()
if wtype == "hann":
w = np.hanning(n)
elif wtype == "hamming":
w = np.hamming(n)
elif wtype == "blackman":
w = np.blackman(n)
else:
w = np.ones(n)
return data * w[np.newaxis, :]
# ---- DC Notch (zero-Doppler removal) ------------------------------------
@staticmethod
def dc_notch(data: np.ndarray) -> np.ndarray:
"""Remove the DC (zero-Doppler) component by subtracting the
mean along the slow-time axis for each range bin."""
return data - np.mean(data, axis=1, keepdims=True)
# ---- MTI (Moving Target Indication) -------------------------------------
def mti_filter(self, frame: np.ndarray) -> np.ndarray:
"""Apply MTI cancellation of order 1, 2, or 3.
Order-1: y[n] = x[n] - x[n-1]
Order-2: y[n] = x[n] - 2*x[n-1] + x[n-2]
Order-3: y[n] = x[n] - 3*x[n-1] + 3*x[n-2] - x[n-3]
The internal history buffer stores up to 3 previous frames.
"""
order = self.config.mti_order
self._mti_history.append(frame.copy())
# Trim history to order + 1 frames
max_len = order + 1
if len(self._mti_history) > max_len:
self._mti_history = self._mti_history[-max_len:]
if len(self._mti_history) < order + 1:
# Not enough history yet — return zeros (suppress output)
return np.zeros_like(frame)
h = self._mti_history
if order == 1:
return h[-1] - h[-2]
if order == 2:
return h[-1] - 2.0 * h[-2] + h[-3]
if order == 3:
return h[-1] - 3.0 * h[-2] + 3.0 * h[-3] - h[-4]
return h[-1] - h[-2]
# ---- CFAR (Constant False Alarm Rate) -----------------------------------
@staticmethod
def cfar_1d(signal_vec: np.ndarray, guard: int, train: int,
threshold_factor: float, cfar_type: str = "CA-CFAR") -> np.ndarray:
"""1-D CFAR detector.
Parameters
----------
signal_vec : 1-D array (power in linear scale)
guard : number of guard cells on each side
train : number of training cells on each side
threshold_factor : multiplier on estimated noise level
cfar_type : CA-CFAR, OS-CFAR, GO-CFAR, or SO-CFAR
Returns
-------
detections : boolean array, True where target detected
"""
n = len(signal_vec)
detections = np.zeros(n, dtype=bool)
half = guard + train
for i in range(half, n - half):
# Leading training cells
lead = signal_vec[i - half: i - guard]
# Lagging training cells
lag = signal_vec[i + guard + 1: i + half + 1]
if cfar_type == "CA-CFAR":
noise = (np.sum(lead) + np.sum(lag)) / (2 * train)
elif cfar_type == "GO-CFAR":
noise = max(np.mean(lead), np.mean(lag))
elif cfar_type == "SO-CFAR":
noise = min(np.mean(lead), np.mean(lag))
elif cfar_type == "OS-CFAR":
all_train = np.concatenate([lead, lag])
all_train.sort()
k = int(0.75 * len(all_train)) # 75th percentile
noise = all_train[min(k, len(all_train) - 1)]
else:
noise = (np.sum(lead) + np.sum(lag)) / (2 * train)
threshold = noise * threshold_factor
if signal_vec[i] > threshold:
detections[i] = True
return detections
def cfar_2d(self, rdm: np.ndarray) -> np.ndarray:
"""Apply 1-D CFAR along each range bin (across Doppler dimension).
Returns a boolean mask of the same shape as *rdm*.
"""
cfg = self.config
mask = np.zeros_like(rdm, dtype=bool)
for r in range(rdm.shape[0]):
row = rdm[r, :]
if row.max() > 0:
mask[r, :] = self.cfar_1d(
row, cfg.cfar_guard_cells, cfg.cfar_training_cells,
cfg.cfar_threshold_factor, cfg.cfar_type,
)
return mask
# ---- Full processing pipeline -------------------------------------------
def process_frame(self, raw_frame: np.ndarray) -> tuple[np.ndarray, np.ndarray]:
"""Run the full signal processing chain on a Range x Doppler frame.
Parameters
----------
raw_frame : 2-D array (range_bins x doppler_bins), complex or real
Returns
-------
(processed_rdm, detection_mask)
processed_rdm — processed Range-Doppler map (power, linear)
detection_mask — boolean mask of CFAR / threshold detections
"""
cfg = self.config
data = raw_frame.astype(np.float64)
# 1. DC Notch
if cfg.dc_notch_enabled:
data = self.dc_notch(data)
# 2. Windowing (before FFT — applied along slow-time axis)
if cfg.window_type and cfg.window_type != "None":
data = self.apply_window(data, cfg.window_type)
# 3. MTI
if cfg.mti_enabled:
data = self.mti_filter(data)
# 4. Power (magnitude squared)
power = np.abs(data) ** 2
power = np.maximum(power, 1e-20) # avoid log(0)
# 5. CFAR detection or simple threshold
if cfg.cfar_enabled:
detection_mask = self.cfar_2d(power)
else:
# Simple threshold: convert dB threshold to linear
power_db = 10.0 * np.log10(power)
noise_floor = np.median(power_db)
detection_mask = power_db > (noise_floor + cfg.detection_threshold_db)
# Update stored RDM
self.range_doppler_map = power
self.frame_count += 1
return power, detection_mask
# ---- Dual-CPI fusion ---------------------------------------------------
@staticmethod
def dual_cpi_fusion(range_profiles_1: np.ndarray,
range_profiles_2: np.ndarray) -> np.ndarray:
"""Dual-CPI fusion for better detection."""
return np.mean(range_profiles_1, axis=0) + np.mean(range_profiles_2, axis=0)
# ---- DBSCAN clustering -------------------------------------------------
@staticmethod
def clustering(detections: list[RadarTarget],
eps: float = 100, min_samples: int = 2) -> list:
"""DBSCAN clustering of detections (requires sklearn)."""
if not SKLEARN_AVAILABLE or len(detections) == 0:
return []
points = np.array([[d.range, d.velocity] for d in detections])
labels = DBSCAN(eps=eps, min_samples=min_samples).fit(points).labels_
clusters = []
for label in set(labels):
if label == -1:
continue
cluster_points = points[labels == label]
clusters.append({
"center": np.mean(cluster_points, axis=0),
"points": cluster_points,
"size": len(cluster_points),
})
return clusters
# ---- Association -------------------------------------------------------
def association(self, detections: list[RadarTarget],
_clusters: list) -> list[RadarTarget]:
"""Associate detections to existing tracks (nearest-neighbour)."""
associated = []
for det in detections:
best_track = None
min_dist = float("inf")
for tid, track in self.tracks.items():
dist = math.sqrt(
(det.range - track["state"][0]) ** 2
+ (det.velocity - track["state"][2]) ** 2
)
if dist < min_dist and dist < 500:
min_dist = dist
best_track = tid
if best_track is not None:
det.track_id = best_track
else:
det.track_id = self.track_id_counter
self.track_id_counter += 1
associated.append(det)
return associated
# ---- Kalman tracking ---------------------------------------------------
def tracking(self, associated_detections: list[RadarTarget]):
"""Kalman filter tracking (requires filterpy)."""
if not FILTERPY_AVAILABLE:
return
now = time.time()
for det in associated_detections:
if det.track_id not in self.tracks:
kf = KalmanFilter(dim_x=4, dim_z=2)
kf.x = np.array([det.range, 0, det.velocity, 0])
kf.F = np.array([
[1, 1, 0, 0],
[0, 1, 0, 0],
[0, 0, 1, 1],
[0, 0, 0, 1],
])
kf.H = np.array([
[1, 0, 0, 0],
[0, 0, 1, 0],
])
kf.P *= 1000
kf.R = np.diag([10, 1])
kf.Q = np.eye(4) * 0.1
self.tracks[det.track_id] = {
"filter": kf,
"state": kf.x,
"last_update": now,
"hits": 1,
}
else:
track = self.tracks[det.track_id]
track["filter"].predict()
track["filter"].update([det.range, det.velocity])
track["state"] = track["filter"].x
track["last_update"] = now
track["hits"] += 1
# Prune stale tracks (> 5 s without update)
stale = [tid for tid, t in self.tracks.items()
if now - t["last_update"] > 5.0]
for tid in stale:
del self.tracks[tid]
# =============================================================================
# USB / GPS Packet Parser
# =============================================================================
class USBPacketParser:
"""
Parse GPS (and general) data arriving from the STM32 via USB CDC.
Supports:
- Text format: ``GPS:lat,lon,alt,pitch\\r\\n``
- Binary format: ``GPSB`` header, 30 bytes total
"""
def __init__(self):
pass
def parse_gps_data(self, data: bytes) -> GPSData | None:
"""Attempt to parse GPS data from a raw USB CDC frame."""
if not data:
return None
try:
# Text format: "GPS:lat,lon,alt,pitch\r\n"
text = data.decode("utf-8", errors="ignore").strip()
if text.startswith("GPS:"):
parts = text.split(":")[1].split(",")
if len(parts) >= 4:
return GPSData(
latitude=float(parts[0]),
longitude=float(parts[1]),
altitude=float(parts[2]),
pitch=float(parts[3]),
timestamp=time.time(),
)
# Binary format: [GPSB 4][lat 8][lon 8][alt 4][pitch 4][CRC 2] = 30 bytes
if len(data) >= 30 and data[0:4] == b"GPSB":
return self._parse_binary_gps(data)
except (ValueError, struct.error) as e:
logger.error(f"Error parsing GPS data: {e}")
return None
@staticmethod
def _parse_binary_gps(data: bytes) -> GPSData | None:
"""Parse 30-byte binary GPS frame."""
try:
if len(data) < 30:
return None
# Simple checksum CRC
crc_rcv = (data[28] << 8) | data[29]
crc_calc = sum(data[0:28]) & 0xFFFF
if crc_rcv != crc_calc:
logger.warning("GPS binary CRC mismatch")
return None
lat = struct.unpack(">d", data[4:12])[0]
lon = struct.unpack(">d", data[12:20])[0]
alt = struct.unpack(">f", data[20:24])[0]
pitch = struct.unpack(">f", data[24:28])[0]
return GPSData(
latitude=lat,
longitude=lon,
altitude=alt,
pitch=pitch,
timestamp=time.time(),
)
except (ValueError, struct.error) as e:
logger.error(f"Error parsing binary GPS: {e}")
return None
# ============================================================================
# Utility: polar → geographic coordinate conversion
# ============================================================================
def polar_to_geographic(
radar_lat: float,
radar_lon: float,
range_m: float,
azimuth_deg: float,
) -> tuple:
"""Convert polar (range, azimuth) relative to radar → (lat, lon).
azimuth_deg: 0 = North, clockwise.
"""
r_earth = 6_371_000.0 # Earth radius in metres
lat1 = math.radians(radar_lat)
lon1 = math.radians(radar_lon)
bearing = math.radians(azimuth_deg)
lat2 = math.asin(
math.sin(lat1) * math.cos(range_m / r_earth)
+ math.cos(lat1) * math.sin(range_m / r_earth) * math.cos(bearing)
)
lon2 = lon1 + math.atan2(
math.sin(bearing) * math.sin(range_m / r_earth) * math.cos(lat1),
math.cos(range_m / r_earth) - math.sin(lat1) * math.sin(lat2),
)
return (math.degrees(lat2), math.degrees(lon2))
# ============================================================================
# Shared target extraction (used by both RadarDataWorker and ReplayWorker)
# ============================================================================
def extract_targets_from_frame(
frame,
range_resolution: float = 1.0,
velocity_resolution: float = 1.0,
gps: GPSData | None = None,
) -> list[RadarTarget]:
"""Extract RadarTarget list from a RadarFrame's detection mask.
This is the bin-to-physical conversion + geo-mapping shared between
the live and replay data paths.
Parameters
----------
frame : RadarFrame
Frame with populated ``detections``, ``magnitude``, ``range_doppler_i/q``.
range_resolution : float
Meters per range bin.
velocity_resolution : float
m/s per Doppler bin.
gps : GPSData | None
GPS position for geo-mapping (latitude/longitude).
Returns
-------
list[RadarTarget]
One target per detection cell.
"""
det_indices = np.argwhere(frame.detections > 0)
n_doppler = frame.detections.shape[1] if frame.detections.ndim == 2 else 48
doppler_center = n_doppler // 2
targets: list[RadarTarget] = []
for idx in det_indices:
rbin, dbin = int(idx[0]), int(idx[1])
mag = float(frame.magnitude[rbin, dbin])
snr = 10.0 * math.log10(max(mag, 1.0)) if mag > 0 else 0.0
range_m = float(rbin) * range_resolution
velocity_ms = float(dbin - doppler_center) * velocity_resolution
lat, lon, azimuth, elevation = 0.0, 0.0, 0.0, 0.0
if gps is not None:
azimuth = gps.heading
# Spread detections across ±15° sector for single-beam radar
if len(det_indices) > 1:
spread = (dbin - doppler_center) / max(doppler_center, 1) * 15.0
azimuth = gps.heading + spread
lat, lon = polar_to_geographic(
gps.latitude, gps.longitude, range_m, azimuth,
)
targets.append(RadarTarget(
id=len(targets),
range=range_m,
velocity=velocity_ms,
azimuth=azimuth,
elevation=elevation,
latitude=lat,
longitude=lon,
snr=snr,
timestamp=frame.timestamp,
))
return targets
# ============================================================================
# PR-Q.5 — 3-PRI Chinese-Remainder Doppler unfolding (audit C-5)
# ============================================================================
def unfold_velocity_crt(
v_meas_per_sf: list[float],
v_unamb_per_sf: list[float],
v_res_per_sf: list[float] | None = None,
max_alias_k: int = 6,
tol_factor: float = 0.5,
) -> tuple[float, str, list[float]]:
"""3-PRI Chinese-Remainder Doppler velocity unfolding.
Each per-subframe FFT measures v_true folded into a signed
[-v_unamb_i, +v_unamb_i] interval (the standard fftshift
convention). With 3 coprime PRIs (PR-Q ladder: 175/161/167 us,
giving v_unamb ≈ 40.79/44.34/42.79 m/s), brute-force search over
alias depth k_0 ∈ [-K, K] generates candidates
``v_true = v_meas_0 + k_0 · 2 · v_unamb_0``. A candidate is
*valid* when it folds back into all other active PRIs to within
``tol_factor * max(v_res)``.
Args:
v_meas_per_sf: signed velocity measurement per active sub-frame
(m/s), already folded by the FFT. Length 1, 2, or 3.
v_unamb_per_sf: per-sub-frame v_unamb (m/s), same length.
v_res_per_sf: per-sub-frame v_res (m/s). If None, assumes
``v_res = v_unamb / 8`` (matches chirps_per_subframe = 16).
max_alias_k: alias search depth in PRI-0 fold steps. K=6 covers
±6 · 2 · v_unamb_0 ≈ ±490 m/s, well above
``WaveformConfig.extended_max_velocity_mps_crt(K=6) ≈ ±266``.
tol_factor: per-PRI agreement tolerance, in units of max(v_res).
1.0 = within one bin width.
Returns:
(v_est, confidence, alias_set):
- v_est (m/s): best-fit unfolded velocity. Falls back to PRI-0's
measurement if no candidate satisfies all PRIs within tolerance.
- confidence: ``"CONFIRMED"`` / ``"LIKELY"`` / ``"AMBIGUOUS"``.
* CONFIRMED — 3-PRI input, exactly one fold within tolerance.
* LIKELY — 3-PRI input with 2 candidates, or 2-PRI input
with a unique solution.
* AMBIGUOUS — 1-PRI input (no CRT possible), 3+ candidates,
2-PRI input with 2 candidates, or no candidate
within tolerance.
- alias_set (m/s): all candidate v_true within tolerance, sorted
by goodness-of-fit (best first).
"""
n_sf = len(v_meas_per_sf)
if n_sf != len(v_unamb_per_sf):
raise ValueError("v_meas_per_sf and v_unamb_per_sf must have same length")
if n_sf == 0:
return (0.0, "AMBIGUOUS", [])
# 1-PRI input — no CRT possible (LONG-only-at-20-km regime).
if n_sf == 1:
return (v_meas_per_sf[0], "AMBIGUOUS", [v_meas_per_sf[0]])
if v_res_per_sf is None:
v_res_per_sf = [vu / 8.0 for vu in v_unamb_per_sf]
elif len(v_res_per_sf) != n_sf:
raise ValueError("v_res_per_sf, when provided, must match v_meas_per_sf length")
pri0_meas = v_meas_per_sf[0]
pri0_span = 2.0 * v_unamb_per_sf[0]
candidates: list[tuple[float, float]] = [] # (v_candidate, max_err)
for k in range(-max_alias_k, max_alias_k + 1):
v_cand = pri0_meas + k * pri0_span
max_err = 0.0
rejected = False
for i in range(1, n_sf):
vu_i = v_unamb_per_sf[i]
span_i = 2.0 * vu_i
v_pred_i = ((v_cand + vu_i) % span_i) - vu_i
err = abs(v_pred_i - v_meas_per_sf[i])
tol_i = tol_factor * v_res_per_sf[i]
if err > tol_i:
rejected = True
break
if err > max_err:
max_err = err
if not rejected:
candidates.append((v_cand, max_err))
if not candidates:
# No fold satisfies all PRIs — fall back to PRI-0, mark AMBIGUOUS.
return (pri0_meas, "AMBIGUOUS", [pri0_meas])
candidates.sort(key=lambda c: c[1])
v_best = candidates[0][0]
alias_set = [v for (v, _) in candidates]
n_cands = len(alias_set)
if n_cands >= 3:
confidence = "AMBIGUOUS"
elif n_sf == 3 and n_cands == 1:
confidence = "CONFIRMED"
elif (n_sf == 3 and n_cands == 2) or (n_sf == 2 and n_cands == 1):
confidence = "LIKELY"
else: # n_sf == 2 and n_cands == 2
confidence = "AMBIGUOUS"
return (v_best, confidence, alias_set)
def extract_targets_from_frame_crt(
frame,
waveform,
gps: GPSData | None = None,
max_alias_k: int = 6,
) -> list[RadarTarget]:
"""Extract RadarTargets from a 48-bin frame using 3-PRI CRT unfolding.
The 48 Doppler bins are organized as 3 sub-frames of 16:
bins 0..15: SHORT PRI (``waveform.pri_short_s``)
bins 16..31: MEDIUM PRI (``waveform.pri_medium_s``)
bins 32..47: LONG PRI (``waveform.pri_long_s``)
Within each sub-frame, the 16-pt FFT uses the standard signed-bin
convention: bin 0 = DC, bins 1..7 = positive v, bin 8 = Nyquist
(treated as +v_unamb), bins 9..15 = negative v.
Detections at the same range bin across different sub-frames are
grouped, and the strongest bin per (rbin, sub-frame) is taken as
that PRI's primary Doppler measurement. ``unfold_velocity_crt``
resolves aliases when ≥2 sub-frames see the target.
Falls back to the legacy single-PRI ``extract_targets_from_frame``
when the frame is not 48-bin (e.g. 32-bin legacy recordings).
"""
if frame.detections.ndim != 2 or frame.detections.shape[1] != 48:
return extract_targets_from_frame(
frame,
range_resolution=waveform.range_resolution_m,
velocity_resolution=waveform.velocity_resolution_long_mps,
gps=gps,
)
chirps_per_sf = waveform.chirps_per_subframe # 16
v_res_per_sf_all = [
waveform.velocity_resolution_short_mps,
waveform.velocity_resolution_medium_mps,
waveform.velocity_resolution_long_mps,
]
v_unamb_per_sf_all = [
waveform.max_velocity_short_mps,
waveform.max_velocity_medium_mps,
waveform.max_velocity_long_mps,
]
# Group detections: rbin -> {sf_id: (peak_bin_in_sf, peak_mag)}
clusters: dict[int, dict[int, tuple[int, float]]] = {}
det_indices = np.argwhere(frame.detections > 0)
for idx in det_indices:
rbin, dbin = int(idx[0]), int(idx[1])
sf_id = dbin // chirps_per_sf
bin_in_sf = dbin % chirps_per_sf
mag = float(frame.magnitude[rbin, dbin])
existing = clusters.setdefault(rbin, {}).get(sf_id)
if existing is None or mag > existing[1]:
clusters[rbin][sf_id] = (bin_in_sf, mag)
targets: list[RadarTarget] = []
range_resolution = waveform.range_resolution_m
for rbin in sorted(clusters.keys()):
sf_map = clusters[rbin]
active_sfs = sorted(sf_map.keys())
v_meas_list: list[float] = []
v_unamb_list: list[float] = []
v_res_list: list[float] = []
peak_mag = 0.0
for sf_id in active_sfs:
bin_in_sf, mag = sf_map[sf_id]
# Signed bin: 0..7 positive, 8 = Nyquist (treat as +8),
# 9..15 negative. Yields v in [-8·v_res, +8·v_res].
signed_bin = bin_in_sf if bin_in_sf <= 8 else bin_in_sf - chirps_per_sf
v_meas_list.append(float(signed_bin) * v_res_per_sf_all[sf_id])
v_unamb_list.append(v_unamb_per_sf_all[sf_id])
v_res_list.append(v_res_per_sf_all[sf_id])
if mag > peak_mag:
peak_mag = mag
v_est, confidence, alias_set = unfold_velocity_crt(
v_meas_list, v_unamb_list, v_res_list, max_alias_k=max_alias_k,
)
range_m = float(rbin) * range_resolution
snr = 10.0 * math.log10(max(peak_mag, 1.0)) if peak_mag > 0 else 0.0
lat, lon, azimuth, elevation = 0.0, 0.0, 0.0, 0.0
if gps is not None:
azimuth = gps.heading
lat, lon = polar_to_geographic(
gps.latitude, gps.longitude, range_m, azimuth,
)
targets.append(RadarTarget(
id=len(targets),
range=range_m,
velocity=v_est,
azimuth=azimuth,
elevation=elevation,
latitude=lat,
longitude=lon,
snr=snr,
timestamp=frame.timestamp,
velocity_confidence=confidence,
alias_set=alias_set if alias_set else None,
))
return targets
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