ChTheo/RFG_stm32_ADC_receiver_GUI
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base: ChTheo:head-fixer
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ChTheo:master ChTheo:head-fixer ChTheo:log-detector ChTheo:stupid ChTheo:normaliser ChTheo:refactor
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compare: ChTheo:ce11c38b44175b955324e147d2ec3e55e1824a53
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ChTheo:head-fixer ChTheo:log-detector ChTheo:stupid ChTheo:normaliser ChTheo:master ChTheo:refactor

5 Commits
head-fixer ... ce11c38b44

Author SHA1 Message Date
Theodor Chikin
ce11c38b44 --logscale enabled by default 2026-03-03 19:54:58 +03:00
Theodor Chikin
1e098ffa89 implemented new binary mode (--logscale): 2 32-bit values: avg_1, avg_2. Also implemented log-detector mode: avg_1,2 are processed as lg(signal_power) in def _log_pair_to_sweep. Tuning variables: LOG_BASE, LOG_SCALER, LOG_POSTSCALER. 2026-03-03 19:50:44 +03:00
Theodor Chikin
f4a3e6546a add 32-bit binary sweep parsing and percentile scaling for raw waterfall 2026-03-03 18:49:12 +03:00
Theodor Chikin
7d714530bc implemented new normalisator mode: projector. It takes upper and lower evenlopes of ref signal and projects raw data from evenlopes scope to +-1000 2026-02-11 13:25:21 +03:00
awe
415084e66b graph upd 2026-02-11 13:21:37 +03:00
1 changed files with 575 additions and 169 deletions
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632
RFG_ADC_dataplotter.py
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@ -33,13 +33,18 @@ import numpy as np
WF_WIDTH = 1000 # максимальное число точек в ряду водопада WF_WIDTH = 1000 # максимальное число точек в ряду водопада
FFT_LEN = 1024 # длина БПФ для спектра/водопада спектров FFT_LEN = 1024 # длина БПФ для спектра/водопада спектров
LOG_BASE = 10.0
LOG_SCALER = 0.001 # int32 значения приходят в fixed-point лог-шкале с шагом 1e-3
LOG_POSTSCALER = 1000
LOG_EXP_LIMIT = 300.0 # запас до переполнения float64 при возведении LOG_BASE в степень
# Порог для инверсии сырых данных: если среднее значение свипа ниже порога — # Порог для инверсии сырых данных: если среднее значение свипа ниже порога —
# считаем, что сигнал «меньше нуля» и домножаем свип на -1 # считаем, что сигнал «меньше нуля» и домножаем свип на -1
DATA_INVERSION_THRASHOLD = 10.0 DATA_INVERSION_THRASHOLD = 10.0
Number = Union[int, float] Number = Union[int, float]
SweepInfo = Dict[str, Any] SweepInfo = Dict[str, Any]
SweepPacket = Tuple[np.ndarray, SweepInfo] SweepAuxCurves = Optional[Tuple[np.ndarray, np.ndarray]]
SweepPacket = Tuple[np.ndarray, SweepInfo, SweepAuxCurves]
def _format_status_kv(data: Mapping[str, Any]) -> str: def _format_status_kv(data: Mapping[str, Any]) -> str:
@ -85,6 +90,154 @@ def _parse_spec_clip(spec: Optional[str]) -> Optional[Tuple[float, float]]:
return None return None
def _log_value_to_linear(value: int) -> float:
"""Преобразовать fixed-point логарифмическое значение в линейную шкалу."""
exponent = max(-LOG_EXP_LIMIT, min(LOG_EXP_LIMIT, float(value) * LOG_SCALER))
return float(LOG_BASE ** exponent)
def _log_pair_to_sweep(avg_1: int, avg_2: int) -> float:
"""Разность двух логарифмических усреднений в линейной шкале."""
return (_log_value_to_linear(avg_1) - _log_value_to_linear(avg_2))*LOG_POSTSCALER
def _compute_auto_ylim(*series_list: Optional[np.ndarray]) -> Optional[Tuple[float, float]]:
"""Общий Y-диапазон по всем переданным кривым с небольшим запасом."""
y_min: Optional[float] = None
y_max: Optional[float] = None
for series in series_list:
if series is None:
continue
arr = np.asarray(series)
if arr.size == 0:
continue
finite = arr[np.isfinite(arr)]
if finite.size == 0:
continue
cur_min = float(np.min(finite))
cur_max = float(np.max(finite))
y_min = cur_min if y_min is None else min(y_min, cur_min)
y_max = cur_max if y_max is None else max(y_max, cur_max)
if y_min is None or y_max is None:
return None
if y_min == y_max:
pad = max(1.0, abs(y_min) * 0.05)
else:
pad = 0.05 * (y_max - y_min)
return (y_min - pad, y_max + pad)
def _normalize_sweep_simple(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Простая нормировка: поэлементное деление raw/calib."""
w = min(raw.size, calib.size)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
with np.errstate(divide="ignore", invalid="ignore"):
out[:w] = raw[:w] / calib[:w]
out = np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
return out
def _build_calib_envelopes(calib: np.ndarray) -> Tuple[np.ndarray, np.ndarray]:
"""Оценить нижнюю/верхнюю огибающие калибровочной кривой."""
n = int(calib.size)
if n <= 0:
empty = np.zeros((0,), dtype=np.float32)
return empty, empty
y = np.asarray(calib, dtype=np.float32)
finite = np.isfinite(y)
if not np.any(finite):
zeros = np.zeros_like(y, dtype=np.float32)
return zeros, zeros
if not np.all(finite):
x = np.arange(n, dtype=np.float32)
y = y.copy()
y[~finite] = np.interp(x[~finite], x[finite], y[finite]).astype(np.float32)
if n < 3:
return y.copy(), y.copy()
dy = np.diff(y)
s = np.sign(dy).astype(np.int8, copy=False)
if np.any(s == 0):
for i in range(1, s.size):
if s[i] == 0:
s[i] = s[i - 1]
for i in range(s.size - 2, -1, -1):
if s[i] == 0:
s[i] = s[i + 1]
s[s == 0] = 1
max_idx = np.where((s[:-1] > 0) & (s[1:] < 0))[0] + 1
min_idx = np.where((s[:-1] < 0) & (s[1:] > 0))[0] + 1
x = np.arange(n, dtype=np.float32)
def _interp_nodes(nodes: np.ndarray) -> np.ndarray:
if nodes.size == 0:
idx = np.array([0, n - 1], dtype=np.int64)
else:
idx = np.unique(np.concatenate(([0], nodes, [n - 1]))).astype(np.int64)
return np.interp(x, idx.astype(np.float32), y[idx]).astype(np.float32)
upper = _interp_nodes(max_idx)
lower = _interp_nodes(min_idx)
swap = lower > upper
if np.any(swap):
tmp = upper[swap].copy()
upper[swap] = lower[swap]
lower[swap] = tmp
return lower, upper
def _normalize_sweep_projector(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
"""Нормировка через проекцию между огибающими калибровки в диапазон [-1, +1]."""
w = min(raw.size, calib.size)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
raw_seg = np.asarray(raw[:w], dtype=np.float32)
lower, upper = _build_calib_envelopes(np.asarray(calib[:w], dtype=np.float32))
span = upper - lower
finite_span = span[np.isfinite(span) & (span > 0)]
if finite_span.size > 0:
eps = max(float(np.median(finite_span)) * 1e-6, 1e-9)
else:
eps = 1e-9
valid = (
np.isfinite(raw_seg)
& np.isfinite(lower)
& np.isfinite(upper)
& (span > eps)
)
if np.any(valid):
proj = np.empty_like(raw_seg, dtype=np.float32)
proj[valid] = ((2.0 * (raw_seg[valid] - lower[valid]) / span[valid]) - 1.0) * 1000.0
proj[valid] = np.clip(proj[valid], -1000.0, 1000.0)
proj[~valid] = np.nan
out[:w] = proj
return out
def _normalize_by_calib(raw: np.ndarray, calib: np.ndarray, norm_type: str) -> np.ndarray:
"""Нормировка свипа по выбранному алгоритму."""
nt = str(norm_type).strip().lower()
if nt == "simple":
return _normalize_sweep_simple(raw, calib)
return _normalize_sweep_projector(raw, calib)
def try_open_pyserial(path: str, baud: int, timeout: float): def try_open_pyserial(path: str, baud: int, timeout: float):
try: try:
import serial # type: ignore import serial # type: ignore
@ -274,6 +427,8 @@ class SweepReader(threading.Thread):
out_queue: Queue[SweepPacket], out_queue: Queue[SweepPacket],
stop_event: threading.Event, stop_event: threading.Event,
fancy: bool = False, fancy: bool = False,
bin_mode: bool = False,
logscale: bool = False,
): ):
super().__init__(daemon=True) super().__init__(daemon=True)
self._port_path = port_path self._port_path = port_path
@ -282,12 +437,26 @@ class SweepReader(threading.Thread):
self._stop = stop_event self._stop = stop_event
self._src: Optional[SerialLineSource] = None self._src: Optional[SerialLineSource] = None
self._fancy = bool(fancy) self._fancy = bool(fancy)
self._bin_mode = bool(bin_mode)
self._logscale = bool(logscale)
self._max_width: int = 0 self._max_width: int = 0
self._sweep_idx: int = 0 self._sweep_idx: int = 0
self._last_sweep_ts: Optional[float] = None self._last_sweep_ts: Optional[float] = None
self._n_valid_hist = deque() self._n_valid_hist = deque()
def _finalize_current(self, xs, ys, channels: Optional[set[int]]): @staticmethod
def _u32_to_i32(v: int) -> int:
"""Преобразование 32-bit слова в знаковое значение."""
return v - 0x1_0000_0000 if (v & 0x8000_0000) else v
def _finalize_current(
self,
xs,
ys,
channels: Optional[set[int]],
raw_curves: Optional[Tuple[list[int], list[int]]] = None,
apply_inversion: bool = True,
):
if not xs: if not xs:
return return
ch_list = sorted(channels) if channels else [0] ch_list = sorted(channels) if channels else [0]
@ -296,17 +465,43 @@ class SweepReader(threading.Thread):
width = max_x + 1 width = max_x + 1
self._max_width = max(self._max_width, width) self._max_width = max(self._max_width, width)
target_width = self._max_width if self._fancy else width target_width = self._max_width if self._fancy else width
# Быстрый векторизованный путь
sweep = np.full((target_width,), np.nan, dtype=np.float32) def _scatter(values, dtype) -> np.ndarray:
series = np.full((target_width,), np.nan, dtype=dtype)
try: try:
idx = np.asarray(xs, dtype=np.int64) idx = np.asarray(xs, dtype=np.int64)
vals = np.asarray(ys, dtype=np.float32) vals = np.asarray(values, dtype=dtype)
sweep[idx] = vals series[idx] = vals
except Exception: except Exception:
# Запасной путь for x, y in zip(xs, values):
for x, y in zip(xs, ys):
if 0 <= x < target_width: if 0 <= x < target_width:
sweep[x] = float(y) series[x] = y
return series
def _fill_missing(series: np.ndarray):
known = ~np.isnan(series)
if not np.any(known):
return
known_idx = np.nonzero(known)[0]
for i0, i1 in zip(known_idx[:-1], known_idx[1:]):
if i1 - i0 > 1:
avg = (series[i0] + series[i1]) * 0.5
series[i0 + 1 : i1] = avg
first_idx = int(known_idx[0])
last_idx = int(known_idx[-1])
if first_idx > 0:
series[:first_idx] = series[first_idx]
if last_idx < series.size - 1:
series[last_idx + 1 :] = series[last_idx]
# Быстрый векторизованный путь
sweep = _scatter(ys, np.float32)
aux_curves: SweepAuxCurves = None
if raw_curves is not None:
aux_curves = (
_scatter(raw_curves[0], np.float32),
_scatter(raw_curves[1], np.float32),
)
# Метрики валидных точек до заполнения пропусков # Метрики валидных точек до заполнения пропусков
finite_pre = np.isfinite(sweep) finite_pre = np.isfinite(sweep)
n_valid_cur = int(np.count_nonzero(finite_pre)) n_valid_cur = int(np.count_nonzero(finite_pre))
@ -314,30 +509,22 @@ class SweepReader(threading.Thread):
# Дополнительная обработка пропусков: при --fancy заполняем внутренние разрывы, края и дотягиваем до максимальной длины # Дополнительная обработка пропусков: при --fancy заполняем внутренние разрывы, края и дотягиваем до максимальной длины
if self._fancy: if self._fancy:
try: try:
known = ~np.isnan(sweep) _fill_missing(sweep)
if np.any(known): if aux_curves is not None:
known_idx = np.nonzero(known)[0] _fill_missing(aux_curves[0])
# Для каждой пары соседних известных индексов заполним промежуток средним значением _fill_missing(aux_curves[1])
for i0, i1 in zip(known_idx[:-1], known_idx[1:]):
if i1 - i0 > 1:
avg = (sweep[i0] + sweep[i1]) * 0.5
sweep[i0 + 1 : i1] = avg
first_idx = int(known_idx[0])
last_idx = int(known_idx[-1])
if first_idx > 0:
sweep[:first_idx] = sweep[first_idx]
if last_idx < sweep.size - 1:
sweep[last_idx + 1 :] = sweep[last_idx]
except Exception: except Exception:
# В случае ошибки просто оставляем как есть # В случае ошибки просто оставляем как есть
pass pass
# Инверсия данных при «отрицательном» уровне (среднее ниже порога) # Инверсия данных при «отрицательном» уровне (среднее ниже порога)
if apply_inversion:
try: try:
m = float(np.nanmean(sweep)) m = float(np.nanmean(sweep))
if np.isfinite(m) and m < DATA_INVERSION_THRASHOLD: if np.isfinite(m) and m < DATA_INVERSION_THRASHOLD:
sweep *= -1.0 sweep *= -1.0
except Exception: except Exception:
pass pass
#sweep = np.abs(sweep)
#sweep -= float(np.nanmean(sweep)) #sweep -= float(np.nanmean(sweep))
# Метрики для статусной строки (вид словаря: переменная -> значение) # Метрики для статусной строки (вид словаря: переменная -> значение)
@ -381,45 +568,31 @@ class SweepReader(threading.Thread):
# Кладём готовый свип (если очередь полна — выбрасываем самый старый) # Кладём готовый свип (если очередь полна — выбрасываем самый старый)
try: try:
self._q.put_nowait((sweep, info)) self._q.put_nowait((sweep, info, aux_curves))
except Full: except Full:
try: try:
_ = self._q.get_nowait() _ = self._q.get_nowait()
except Exception: except Exception:
pass pass
try: try:
self._q.put_nowait((sweep, info)) self._q.put_nowait((sweep, info, aux_curves))
except Exception: except Exception:
pass pass
def run(self): def _run_ascii_stream(self, chunk_reader: SerialChunkReader):
# Состояние текущего свипа
xs: list[int] = [] xs: list[int] = []
ys: list[int] = [] ys: list[int] = []
cur_channel: Optional[int] = None cur_channel: Optional[int] = None
cur_channels: set[int] = set() cur_channels: set[int] = set()
try:
self._src = SerialLineSource(self._port_path, self._baud, timeout=1.0)
sys.stderr.write(f"[info] Открыл порт {self._port_path} ({self._src._using})\n")
except Exception as e:
sys.stderr.write(f"[error] {e}\n")
return
try:
# Быстрый неблокирующий дренаж порта с разбором по байтам
chunk_reader = SerialChunkReader(self._src)
buf = bytearray() buf = bytearray()
while not self._stop.is_set(): while not self._stop.is_set():
data = chunk_reader.read_available() data = chunk_reader.read_available()
if data: if data:
buf += data buf += data
else: else:
# Короткая уступка CPU, если нет новых данных
time.sleep(0.0005) time.sleep(0.0005)
continue continue
# Обрабатываем все полные строки
while True: while True:
nl = buf.find(b"\n") nl = buf.find(b"\n")
if nl == -1: if nl == -1:
@ -466,15 +639,198 @@ class SweepReader(threading.Thread):
xs.append(x) xs.append(x)
ys.append(y) ys.append(y)
# Защита от переполнения буфера при отсутствии переводов строки
if len(buf) > 1_000_000: if len(buf) > 1_000_000:
del buf[:-262144] del buf[:-262144]
finally:
try:
# Завершаем оставшийся свип
self._finalize_current(xs, ys, cur_channels) self._finalize_current(xs, ys, cur_channels)
except Exception:
pass def _run_binary_stream(self, chunk_reader: SerialChunkReader):
xs: list[int] = []
ys: list[int] = []
cur_channel: Optional[int] = None
cur_channels: set[int] = set()
words = deque()
buf = bytearray()
while not self._stop.is_set():
data = chunk_reader.read_available()
if data:
buf += data
else:
time.sleep(0.0005)
continue
usable = len(buf) & ~1
if usable == 0:
continue
i = 0
while i < usable:
w = int(buf[i]) | (int(buf[i + 1]) << 8)
words.append(w)
i += 2
# Бинарный протокол:
# старт свипа (актуальный): 0xFFFF, 0xFFFF, 0xFFFF, (ch<<8)|0x0A
# старт свипа (legacy): 0xFFFF, 0xFFFF, channel, 0x0A0A
# точка: step, value_hi, value_lo, 0x000A
while len(words) >= 4:
w0 = int(words[0])
w1 = int(words[1])
w2 = int(words[2])
w3 = int(words[3])
if w0 == 0xFFFF and w1 == 0xFFFF and w2 == 0xFFFF and (w3 & 0x00FF) == 0x000A:
self._finalize_current(xs, ys, cur_channels)
xs.clear()
ys.clear()
cur_channels.clear()
cur_channel = (w3 >> 8) & 0x00FF
cur_channels.add(cur_channel)
for _ in range(4):
words.popleft()
continue
if w0 == 0xFFFF and w1 == 0xFFFF and w3 == 0x0A0A:
self._finalize_current(xs, ys, cur_channels)
xs.clear()
ys.clear()
cur_channels.clear()
cur_channel = w2
cur_channels.add(cur_channel)
for _ in range(4):
words.popleft()
continue
if w3 == 0x000A:
if cur_channel is not None:
cur_channels.add(cur_channel)
xs.append(w0)
value_u32 = (w1 << 16) | w2
ys.append(self._u32_to_i32(value_u32))
for _ in range(4):
words.popleft()
continue
# Поток может начаться с середины пакета; сдвигаемся по слову до ресинхронизации.
words.popleft()
del buf[:usable]
if len(buf) > 1_000_000:
del buf[:-262144]
self._finalize_current(xs, ys, cur_channels)
def _run_logscale_binary_stream(self, chunk_reader: SerialChunkReader):
xs: list[int] = []
ys: list[float] = []
avg_1_vals: list[int] = []
avg_2_vals: list[int] = []
cur_channel: Optional[int] = None
cur_channels: set[int] = set()
words = deque()
buf = bytearray()
while not self._stop.is_set():
data = chunk_reader.read_available()
if data:
buf += data
else:
time.sleep(0.0005)
continue
usable = len(buf) & ~1
if usable == 0:
continue
i = 0
while i < usable:
w = int(buf[i]) | (int(buf[i + 1]) << 8)
words.append(w)
i += 2
# Бинарный logscale-протокол:
# старт свипа: 0xFFFF x5, затем (ch<<8)|0x0A
# точка: step, avg1_hi, avg1_lo, avg2_hi, avg2_lo, 0x000A
while len(words) >= 6:
w0 = int(words[0])
w1 = int(words[1])
w2 = int(words[2])
w3 = int(words[3])
w4 = int(words[4])
w5 = int(words[5])
if (
w0 == 0xFFFF
and w1 == 0xFFFF
and w2 == 0xFFFF
and w3 == 0xFFFF
and w4 == 0xFFFF
and (w5 & 0x00FF) == 0x000A
):
self._finalize_current(
xs,
ys,
cur_channels,
raw_curves=(avg_1_vals, avg_2_vals),
apply_inversion=False,
)
xs.clear()
ys.clear()
avg_1_vals.clear()
avg_2_vals.clear()
cur_channels.clear()
cur_channel = (w5 >> 8) & 0x00FF
cur_channels.add(cur_channel)
for _ in range(6):
words.popleft()
continue
if w5 == 0x000A:
if cur_channel is not None:
cur_channels.add(cur_channel)
avg_1 = self._u32_to_i32((w1 << 16) | w2)
avg_2 = self._u32_to_i32((w3 << 16) | w4)
xs.append(w0)
avg_1_vals.append(avg_1)
avg_2_vals.append(avg_2)
ys.append(_log_pair_to_sweep(avg_1, avg_2))
#ys.append(LOG_BASE**(avg_1/LOG_SCALER) - LOG_BASE**(avg_2/LOG_SCALER))
for _ in range(6):
words.popleft()
continue
words.popleft()
del buf[:usable]
if len(buf) > 1_000_000:
del buf[:-262144]
self._finalize_current(
xs,
ys,
cur_channels,
raw_curves=(avg_1_vals, avg_2_vals),
apply_inversion=False,
)
def run(self):
try:
self._src = SerialLineSource(self._port_path, self._baud, timeout=1.0)
sys.stderr.write(f"[info] Открыл порт {self._port_path} ({self._src._using})\n")
except Exception as e:
sys.stderr.write(f"[error] {e}\n")
return
try:
chunk_reader = SerialChunkReader(self._src)
if self._logscale:
self._run_logscale_binary_stream(chunk_reader)
elif self._bin_mode:
self._run_binary_stream(chunk_reader)
else:
self._run_ascii_stream(chunk_reader)
finally:
try: try:
if self._src is not None: if self._src is not None:
self._src.close() self._src.close()
@ -532,6 +888,30 @@ def main():
default="auto", default="auto",
help="Графический бэкенд: pyqtgraph (pg) — быстрее; matplotlib (mpl) — совместимый. По умолчанию auto", help="Графический бэкенд: pyqtgraph (pg) — быстрее; matplotlib (mpl) — совместимый. По умолчанию auto",
) )
parser.add_argument(
"--norm-type",
choices=["projector", "simple"],
default="projector",
help="Тип нормировки: projector (по огибающим в [-1,+1]) или simple (raw/calib)",
)
parser.add_argument(
"--bin",
dest="bin_mode",
action="store_true",
help=(
"Бинарный протокол: старт свипа 0xFFFF,0xFFFF,0xFFFF,(CH<<8)|0x0A; "
"точки step,uint32(hi16,lo16),0x000A"
),
)
parser.add_argument(
"--logscale",
action="store_true",
default=True,
help=(
"Новый бинарный протокол: точка несёт пару int32 (avg_1, avg_2), "
"а свип считается как 10**(avg_1*0.001) - 10**(avg_2*0.001)"
),
)
args = parser.parse_args() args = parser.parse_args()
@ -557,7 +937,15 @@ def main():
# Очередь завершённых свипов и поток чтения # Очередь завершённых свипов и поток чтения
q: Queue[SweepPacket] = Queue(maxsize=1000) q: Queue[SweepPacket] = Queue(maxsize=1000)
stop_event = threading.Event() stop_event = threading.Event()
reader = SweepReader(args.port, args.baud, q, stop_event, fancy=bool(args.fancy)) reader = SweepReader(
args.port,
args.baud,
q,
stop_event,
fancy=bool(args.fancy),
bin_mode=bool(args.bin_mode),
logscale=bool(args.logscale),
)
reader.start() reader.start()
# Графика # Графика
@ -569,6 +957,7 @@ def main():
# Состояние для отображения # Состояние для отображения
current_sweep_raw: Optional[np.ndarray] = None current_sweep_raw: Optional[np.ndarray] = None
current_aux_curves: SweepAuxCurves = None
current_sweep_norm: Optional[np.ndarray] = None current_sweep_norm: Optional[np.ndarray] = None
last_calib_sweep: Optional[np.ndarray] = None last_calib_sweep: Optional[np.ndarray] = None
current_info: Optional[SweepInfo] = None current_info: Optional[SweepInfo] = None
@ -592,6 +981,7 @@ def main():
ymax_slider = None ymax_slider = None
contrast_slider = None contrast_slider = None
calib_enabled = False calib_enabled = False
norm_type = str(getattr(args, "norm_type", "projector")).strip().lower()
cb = None cb = None
# Статусная строка (внизу окна) # Статусная строка (внизу окна)
@ -606,11 +996,13 @@ def main():
) )
# Линейный график последнего свипа # Линейный график последнего свипа
line_avg1_obj, = ax_line.plot([], [], lw=1, color="0.65")
line_avg2_obj, = ax_line.plot([], [], lw=1, color="0.45")
line_obj, = ax_line.plot([], [], lw=1, color="tab:blue") line_obj, = ax_line.plot([], [], lw=1, color="tab:blue")
line_calib_obj, = ax_line.plot([], [], lw=1, color="tab:red") line_calib_obj, = ax_line.plot([], [], lw=1, color="tab:red")
line_norm_obj, = ax_line.plot([], [], lw=1, color="tab:green") line_norm_obj, = ax_line.plot([], [], lw=1, color="tab:green")
ax_line.set_title("Сырые данные", pad=1) ax_line.set_title("Сырые данные", pad=1)
ax_line.set_xlabel("F") ax_line.set_xlabel("ГГц")
ax_line.set_ylabel("") ax_line.set_ylabel("")
channel_text = ax_line.text( channel_text = ax_line.text(
0.98, 0.98,
@ -626,8 +1018,8 @@ def main():
# Линейный график спектра текущего свипа # Линейный график спектра текущего свипа
fft_line_obj, = ax_fft.plot([], [], lw=1) fft_line_obj, = ax_fft.plot([], [], lw=1)
ax_fft.set_title("FFT", pad=1) ax_fft.set_title("FFT", pad=1)
ax_fft.set_xlabel("X") ax_fft.set_xlabel("Время")
ax_fft.set_ylabel("Амплитуда, дБ") ax_fft.set_ylabel("дБ")
# Диапазон по Y для последнего свипа: авто по умолчанию (поддерживает отрицательные значения) # Диапазон по Y для последнего свипа: авто по умолчанию (поддерживает отрицательные значения)
fixed_ylim: Optional[Tuple[float, float]] = None fixed_ylim: Optional[Tuple[float, float]] = None
@ -651,7 +1043,7 @@ def main():
) )
ax_img.set_title("Сырые данные", pad=12) ax_img.set_title("Сырые данные", pad=12)
ax_img.set_xlabel("") ax_img.set_xlabel("")
ax_img.set_ylabel("частота") ax_img.set_ylabel("ГГц")
# Не показываем численные значения по времени на водопаде сырых данных # Не показываем численные значения по времени на водопаде сырых данных
try: try:
ax_img.tick_params(axis="x", labelbottom=False) ax_img.tick_params(axis="x", labelbottom=False)
@ -674,15 +1066,9 @@ def main():
ax_spec.tick_params(axis="x", labelbottom=False) ax_spec.tick_params(axis="x", labelbottom=False)
except Exception: except Exception:
pass pass
def _normalize_sweep(raw: np.ndarray, calib: np.ndarray) -> np.ndarray: def _normalize_sweep(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
w = min(raw.size, calib.size) return _normalize_by_calib(raw, calib, norm_type=norm_type)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
with np.errstate(divide="ignore", invalid="ignore"):
out[:w] = raw[:w] / calib[:w]
out = np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
return out
def _set_calib_enabled(): def _set_calib_enabled():
nonlocal calib_enabled, current_sweep_norm nonlocal calib_enabled, current_sweep_norm
@ -734,15 +1120,15 @@ def main():
if ring is not None: if ring is not None:
return return
width = WF_WIDTH width = WF_WIDTH
x_shared = np.arange(width, dtype=np.int32) x_shared = np.linspace(3.3, 14.3, width, dtype=np.float32)
ring = np.full((max_sweeps, width), np.nan, dtype=np.float32) ring = np.full((max_sweeps, width), np.nan, dtype=np.float32)
ring_time = np.full((max_sweeps,), np.nan, dtype=np.float64) ring_time = np.full((max_sweeps,), np.nan, dtype=np.float64)
head = 0 head = 0
# Обновляем изображение под новые размеры: время по X (горизонталь), X по Y # Обновляем изображение под новые размеры: время по X (горизонталь), X по Y
img_obj.set_data(np.zeros((width, max_sweeps), dtype=np.float32)) img_obj.set_data(np.zeros((width, max_sweeps), dtype=np.float32))
img_obj.set_extent((0, max_sweeps - 1, 0, width - 1 if width > 0 else 1)) img_obj.set_extent((0, max_sweeps - 1, 3.3, 14.3))
ax_img.set_xlim(0, max_sweeps - 1) ax_img.set_xlim(0, max_sweeps - 1)
ax_img.set_ylim(0, max(1, width - 1)) ax_img.set_ylim(3.3, 14.3)
# FFT буферы: время по X, бин по Y # FFT буферы: время по X, бин по Y
ring_fft = np.full((max_sweeps, fft_bins), np.nan, dtype=np.float32) ring_fft = np.full((max_sweeps, fft_bins), np.nan, dtype=np.float32)
img_fft_obj.set_data(np.zeros((fft_bins, max_sweeps), dtype=np.float32)) img_fft_obj.set_data(np.zeros((fft_bins, max_sweeps), dtype=np.float32))
@ -752,7 +1138,7 @@ def main():
freq_shared = np.arange(fft_bins, dtype=np.int32) freq_shared = np.arange(fft_bins, dtype=np.int32)
def _visible_levels_matplotlib(data: np.ndarray, axis) -> Optional[Tuple[float, float]]: def _visible_levels_matplotlib(data: np.ndarray, axis) -> Optional[Tuple[float, float]]:
"""(vmin, vmax) по текущей видимой области imshow (без накопления по времени).""" """(vmin, vmax) по центральным 90% значений в видимой области imshow."""
if data.size == 0: if data.size == 0:
return None return None
ny, nx = data.shape[0], data.shape[1] ny, nx = data.shape[0], data.shape[1]
@ -777,8 +1163,8 @@ def main():
if not finite.any(): if not finite.any():
return None return None
vals = sub[finite] vals = sub[finite]
vmin = float(np.min(vals)) vmin = float(np.nanpercentile(vals, 5))
vmax = float(np.max(vals)) vmax = float(np.nanpercentile(vals, 95))
if not (np.isfinite(vmin) and np.isfinite(vmax)) or vmin == vmax: if not (np.isfinite(vmin) and np.isfinite(vmax)) or vmin == vmax:
return None return None
return (vmin, vmax) return (vmin, vmax)
@ -814,7 +1200,7 @@ def main():
# Окно Хэннинга # Окно Хэннинга
win = np.hanning(take_fft).astype(np.float32) win = np.hanning(take_fft).astype(np.float32)
fft_in[:take_fft] = seg * win fft_in[:take_fft] = seg * win
spec = np.fft.rfft(fft_in) spec = np.fft.ifft(fft_in)
mag = np.abs(spec).astype(np.float32) mag = np.abs(spec).astype(np.float32)
fft_row = 20.0 * np.log10(mag + 1e-9) fft_row = 20.0 * np.log10(mag + 1e-9)
if fft_row.shape[0] != bins: if fft_row.shape[0] != bins:
@ -831,15 +1217,16 @@ def main():
y_max_fft = float(fr_max) y_max_fft = float(fr_max)
def drain_queue(): def drain_queue():
nonlocal current_sweep_raw, current_sweep_norm, current_info, last_calib_sweep nonlocal current_sweep_raw, current_aux_curves, current_sweep_norm, current_info, last_calib_sweep
drained = 0 drained = 0
while True: while True:
try: try:
s, info = q.get_nowait() s, info, aux_curves = q.get_nowait()
except Empty: except Empty:
break break
drained += 1 drained += 1
current_sweep_raw = s current_sweep_raw = s
current_aux_curves = aux_curves
current_info = info current_info = info
ch = 0 ch = 0
try: try:
@ -909,6 +1296,13 @@ def main():
else: else:
xs = np.arange(current_sweep_raw.size, dtype=np.int32) xs = np.arange(current_sweep_raw.size, dtype=np.int32)
line_obj.set_data(xs, current_sweep_raw) line_obj.set_data(xs, current_sweep_raw)
if current_aux_curves is not None:
avg_1_curve, avg_2_curve = current_aux_curves
line_avg1_obj.set_data(xs[: avg_1_curve.size], avg_1_curve)
line_avg2_obj.set_data(xs[: avg_2_curve.size], avg_2_curve)
else:
line_avg1_obj.set_data([], [])
line_avg2_obj.set_data([], [])
if last_calib_sweep is not None: if last_calib_sweep is not None:
line_calib_obj.set_data(xs[: last_calib_sweep.size], last_calib_sweep) line_calib_obj.set_data(xs[: last_calib_sweep.size], last_calib_sweep)
else: else:
@ -917,22 +1311,16 @@ def main():
line_norm_obj.set_data(xs[: current_sweep_norm.size], current_sweep_norm) line_norm_obj.set_data(xs[: current_sweep_norm.size], current_sweep_norm)
else: else:
line_norm_obj.set_data([], []) line_norm_obj.set_data([], [])
# Лимиты по X постоянные под текущую ширину # Лимиты по X: 3.3 ГГц .. 14.3 ГГц
ax_line.set_xlim(0, max(1, current_sweep_raw.size - 1)) ax_line.set_xlim(3.3, 14.3)
# Адаптивные Y-лимиты (если не задан --ylim) # Адаптивные Y-лимиты (если не задан --ylim)
if fixed_ylim is None: if fixed_ylim is None:
y0 = float(np.nanmin(current_sweep_raw)) y_series = [current_sweep_raw, last_calib_sweep, current_sweep_norm]
y1 = float(np.nanmax(current_sweep_raw)) if current_aux_curves is not None:
if np.isfinite(y0) and np.isfinite(y1): y_series.extend(current_aux_curves)
if y0 == y1: y_limits = _compute_auto_ylim(*y_series)
pad = max(1.0, abs(y0) * 0.05) if y_limits is not None:
y0 -= pad ax_line.set_ylim(y_limits[0], y_limits[1])
y1 += pad
else:
pad = 0.05 * (y1 - y0)
y0 -= pad
y1 += pad
ax_line.set_ylim(y0, y1)
# Обновление спектра текущего свипа # Обновление спектра текущего свипа
sweep_for_fft = current_sweep_norm if current_sweep_norm is not None else current_sweep_raw sweep_for_fft = current_sweep_norm if current_sweep_norm is not None else current_sweep_raw
@ -942,7 +1330,7 @@ def main():
seg = np.nan_to_num(sweep_for_fft[:take_fft], nan=0.0).astype(np.float32, copy=False) seg = np.nan_to_num(sweep_for_fft[:take_fft], nan=0.0).astype(np.float32, copy=False)
win = np.hanning(take_fft).astype(np.float32) win = np.hanning(take_fft).astype(np.float32)
fft_in[:take_fft] = seg * win fft_in[:take_fft] = seg * win
spec = np.fft.rfft(fft_in) spec = np.fft.ifft(fft_in)
mag = np.abs(spec).astype(np.float32) mag = np.abs(spec).astype(np.float32)
fft_vals = 20.0 * np.log10(mag + 1e-9) fft_vals = 20.0 * np.log10(mag + 1e-9)
xs_fft = freq_shared xs_fft = freq_shared
@ -951,7 +1339,7 @@ def main():
fft_line_obj.set_data(xs_fft[: fft_vals.size], fft_vals) fft_line_obj.set_data(xs_fft[: fft_vals.size], fft_vals)
# Авто-диапазон по Y для спектра # Авто-диапазон по Y для спектра
if np.isfinite(np.nanmin(fft_vals)) and np.isfinite(np.nanmax(fft_vals)): if np.isfinite(np.nanmin(fft_vals)) and np.isfinite(np.nanmax(fft_vals)):
ax_fft.set_xlim(0, max(1, xs_fft.size - 1)) ax_fft.set_xlim(0, max(1, xs_fft.size - 1) * 1.5)
ax_fft.set_ylim(float(np.nanmin(fft_vals)), float(np.nanmax(fft_vals))) ax_fft.set_ylim(float(np.nanmin(fft_vals)), float(np.nanmax(fft_vals)))
# Обновление водопада # Обновление водопада
@ -1022,6 +1410,8 @@ def main():
# Возвращаем обновлённые артисты # Возвращаем обновлённые артисты
return ( return (
line_obj, line_obj,
line_avg1_obj,
line_avg2_obj,
line_calib_obj, line_calib_obj,
line_norm_obj, line_norm_obj,
img_obj, img_obj,
@ -1057,7 +1447,15 @@ def run_pyqtgraph(args):
# Очередь завершённых свипов и поток чтения # Очередь завершённых свипов и поток чтения
q: Queue[SweepPacket] = Queue(maxsize=1000) q: Queue[SweepPacket] = Queue(maxsize=1000)
stop_event = threading.Event() stop_event = threading.Event()
reader = SweepReader(args.port, args.baud, q, stop_event, fancy=bool(args.fancy)) reader = SweepReader(
args.port,
args.baud,
q,
stop_event,
fancy=bool(args.fancy),
bin_mode=bool(args.bin_mode),
logscale=bool(args.logscale),
)
reader.start() reader.start()
# Настройки скорости # Настройки скорости
@ -1074,10 +1472,12 @@ def run_pyqtgraph(args):
# Плот последнего свипа (слева-сверху) # Плот последнего свипа (слева-сверху)
p_line = win.addPlot(row=0, col=0, title="Сырые данные") p_line = win.addPlot(row=0, col=0, title="Сырые данные")
p_line.showGrid(x=True, y=True, alpha=0.3) p_line.showGrid(x=True, y=True, alpha=0.3)
curve_avg1 = p_line.plot(pen=pg.mkPen((170, 170, 170), width=1))
curve_avg2 = p_line.plot(pen=pg.mkPen((110, 110, 110), width=1))
curve = p_line.plot(pen=pg.mkPen((80, 120, 255), width=1)) curve = p_line.plot(pen=pg.mkPen((80, 120, 255), width=1))
curve_calib = p_line.plot(pen=pg.mkPen((220, 60, 60), width=1)) curve_calib = p_line.plot(pen=pg.mkPen((220, 60, 60), width=1))
curve_norm = p_line.plot(pen=pg.mkPen((60, 180, 90), width=1)) curve_norm = p_line.plot(pen=pg.mkPen((60, 180, 90), width=1))
p_line.setLabel("bottom", "X") p_line.setLabel("bottom", "ГГц")
p_line.setLabel("left", "Y") p_line.setLabel("left", "Y")
ch_text = pg.TextItem("", anchor=(1, 1)) ch_text = pg.TextItem("", anchor=(1, 1))
ch_text.setZValue(10) ch_text.setZValue(10)
@ -1092,7 +1492,7 @@ def run_pyqtgraph(args):
p_img.getAxis("bottom").setStyle(showValues=False) p_img.getAxis("bottom").setStyle(showValues=False)
except Exception: except Exception:
pass pass
p_img.setLabel("left", "X (0 снизу)") p_img.setLabel("left", "ГГц")
img = pg.ImageItem() img = pg.ImageItem()
p_img.addItem(img) p_img.addItem(img)
@ -1100,8 +1500,8 @@ def run_pyqtgraph(args):
p_fft = win.addPlot(row=1, col=0, title="FFT") p_fft = win.addPlot(row=1, col=0, title="FFT")
p_fft.showGrid(x=True, y=True, alpha=0.3) p_fft.showGrid(x=True, y=True, alpha=0.3)
curve_fft = p_fft.plot(pen=pg.mkPen((255, 120, 80), width=1)) curve_fft = p_fft.plot(pen=pg.mkPen((255, 120, 80), width=1))
p_fft.setLabel("bottom", "Бин") p_fft.setLabel("bottom", "Время")
p_fft.setLabel("left", "Амплитуда, дБ") p_fft.setLabel("left", "дБ")
# Водопад спектров (справа-снизу) # Водопад спектров (справа-снизу)
p_spec = win.addPlot(row=1, col=1, title="B-scan (дБ)") p_spec = win.addPlot(row=1, col=1, title="B-scan (дБ)")
@ -1133,6 +1533,7 @@ def run_pyqtgraph(args):
width: Optional[int] = None width: Optional[int] = None
x_shared: Optional[np.ndarray] = None x_shared: Optional[np.ndarray] = None
current_sweep_raw: Optional[np.ndarray] = None current_sweep_raw: Optional[np.ndarray] = None
current_aux_curves: SweepAuxCurves = None
current_sweep_norm: Optional[np.ndarray] = None current_sweep_norm: Optional[np.ndarray] = None
last_calib_sweep: Optional[np.ndarray] = None last_calib_sweep: Optional[np.ndarray] = None
current_info: Optional[SweepInfo] = None current_info: Optional[SweepInfo] = None
@ -1146,6 +1547,7 @@ def run_pyqtgraph(args):
spec_clip = _parse_spec_clip(getattr(args, "spec_clip", None)) spec_clip = _parse_spec_clip(getattr(args, "spec_clip", None))
spec_mean_sec = float(getattr(args, "spec_mean_sec", 0.0)) spec_mean_sec = float(getattr(args, "spec_mean_sec", 0.0))
calib_enabled = False calib_enabled = False
norm_type = str(getattr(args, "norm_type", "projector")).strip().lower()
# Диапазон по Y: авто по умолчанию (поддерживает отрицательные значения) # Диапазон по Y: авто по умолчанию (поддерживает отрицательные значения)
fixed_ylim: Optional[Tuple[float, float]] = None fixed_ylim: Optional[Tuple[float, float]] = None
if args.ylim: if args.ylim:
@ -1158,14 +1560,7 @@ def run_pyqtgraph(args):
p_line.setYRange(fixed_ylim[0], fixed_ylim[1], padding=0) p_line.setYRange(fixed_ylim[0], fixed_ylim[1], padding=0)
def _normalize_sweep(raw: np.ndarray, calib: np.ndarray) -> np.ndarray: def _normalize_sweep(raw: np.ndarray, calib: np.ndarray) -> np.ndarray:
w = min(raw.size, calib.size) return _normalize_by_calib(raw, calib, norm_type=norm_type)
if w <= 0:
return raw
out = np.full_like(raw, np.nan, dtype=np.float32)
with np.errstate(divide="ignore", invalid="ignore"):
out[:w] = raw[:w] / calib[:w]
out = np.nan_to_num(out, nan=np.nan, posinf=np.nan, neginf=np.nan)
return out
def _set_calib_enabled(): def _set_calib_enabled():
nonlocal calib_enabled, current_sweep_norm nonlocal calib_enabled, current_sweep_norm
@ -1188,14 +1583,15 @@ def run_pyqtgraph(args):
if ring is not None: if ring is not None:
return return
width = WF_WIDTH width = WF_WIDTH
x_shared = np.arange(width, dtype=np.int32) x_shared = np.linspace(3.3, 14.3, width, dtype=np.float32)
ring = np.full((max_sweeps, width), np.nan, dtype=np.float32) ring = np.full((max_sweeps, width), np.nan, dtype=np.float32)
ring_time = np.full((max_sweeps,), np.nan, dtype=np.float64) ring_time = np.full((max_sweeps,), np.nan, dtype=np.float64)
head = 0 head = 0
# Водопад: время по оси X, X по оси Y # Водопад: время по оси X, X по оси Y (ось Y: 3.3..14.3 ГГц)
img.setImage(ring.T, autoLevels=False) img.setImage(ring.T, autoLevels=False)
p_img.setRange(xRange=(0, max_sweeps - 1), yRange=(0, max(1, width - 1)), padding=0) img.setRect(0, 3.3, max_sweeps, 14.3 - 3.3)
p_line.setXRange(0, max(1, width - 1), padding=0) p_img.setRange(xRange=(0, max_sweeps - 1), yRange=(3.3, 14.3), padding=0)
p_line.setXRange(3.3, 14.3, padding=0)
# FFT: время по оси X, бин по оси Y # FFT: время по оси X, бин по оси Y
ring_fft = np.full((max_sweeps, fft_bins), np.nan, dtype=np.float32) ring_fft = np.full((max_sweeps, fft_bins), np.nan, dtype=np.float32)
img_fft.setImage(ring_fft.T, autoLevels=False) img_fft.setImage(ring_fft.T, autoLevels=False)
@ -1204,7 +1600,7 @@ def run_pyqtgraph(args):
freq_shared = np.arange(fft_bins, dtype=np.int32) freq_shared = np.arange(fft_bins, dtype=np.int32)
def _visible_levels_pyqtgraph(data: np.ndarray) -> Optional[Tuple[float, float]]: def _visible_levels_pyqtgraph(data: np.ndarray) -> Optional[Tuple[float, float]]:
"""(vmin, vmax) по текущей видимой области ImageItem (без накопления по времени).""" """(vmin, vmax) по центральным 90% значений в видимой области ImageItem."""
if data.size == 0: if data.size == 0:
return None return None
ny, nx = data.shape[0], data.shape[1] ny, nx = data.shape[0], data.shape[1]
@ -1228,8 +1624,8 @@ def run_pyqtgraph(args):
if not finite.any(): if not finite.any():
return None return None
vals = sub[finite] vals = sub[finite]
vmin = float(np.min(vals)) vmin = float(np.nanpercentile(vals, 5))
vmax = float(np.max(vals)) vmax = float(np.nanpercentile(vals, 95))
if not (np.isfinite(vmin) and np.isfinite(vmax)) or vmin == vmax: if not (np.isfinite(vmin) and np.isfinite(vmax)) or vmin == vmax:
return None return None
return (vmin, vmax) return (vmin, vmax)
@ -1255,7 +1651,7 @@ def run_pyqtgraph(args):
seg = np.nan_to_num(s[:take_fft], nan=0.0).astype(np.float32, copy=False) seg = np.nan_to_num(s[:take_fft], nan=0.0).astype(np.float32, copy=False)
win = np.hanning(take_fft).astype(np.float32) win = np.hanning(take_fft).astype(np.float32)
fft_in[:take_fft] = seg * win fft_in[:take_fft] = seg * win
spec = np.fft.rfft(fft_in) spec = np.fft.ifft(fft_in)
mag = np.abs(spec).astype(np.float32) mag = np.abs(spec).astype(np.float32)
fft_row = 20.0 * np.log10(mag + 1e-9) fft_row = 20.0 * np.log10(mag + 1e-9)
if fft_row.shape[0] != bins: if fft_row.shape[0] != bins:
@ -1271,15 +1667,16 @@ def run_pyqtgraph(args):
y_max_fft = float(fr_max) y_max_fft = float(fr_max)
def drain_queue(): def drain_queue():
nonlocal current_sweep_raw, current_sweep_norm, current_info, last_calib_sweep nonlocal current_sweep_raw, current_aux_curves, current_sweep_norm, current_info, last_calib_sweep
drained = 0 drained = 0
while True: while True:
try: try:
s, info = q.get_nowait() s, info, aux_curves = q.get_nowait()
except Empty: except Empty:
break break
drained += 1 drained += 1
current_sweep_raw = s current_sweep_raw = s
current_aux_curves = aux_curves
current_info = info current_info = info
ch = 0 ch = 0
try: try:
@ -1318,6 +1715,13 @@ def run_pyqtgraph(args):
else: else:
xs = np.arange(current_sweep_raw.size) xs = np.arange(current_sweep_raw.size)
curve.setData(xs, current_sweep_raw, autoDownsample=True) curve.setData(xs, current_sweep_raw, autoDownsample=True)
if current_aux_curves is not None:
avg_1_curve, avg_2_curve = current_aux_curves
curve_avg1.setData(xs[: avg_1_curve.size], avg_1_curve, autoDownsample=True)
curve_avg2.setData(xs[: avg_2_curve.size], avg_2_curve, autoDownsample=True)
else:
curve_avg1.setData([], [])
curve_avg2.setData([], [])
if last_calib_sweep is not None: if last_calib_sweep is not None:
curve_calib.setData(xs[: last_calib_sweep.size], last_calib_sweep, autoDownsample=True) curve_calib.setData(xs[: last_calib_sweep.size], last_calib_sweep, autoDownsample=True)
else: else:
@ -1327,11 +1731,12 @@ def run_pyqtgraph(args):
else: else:
curve_norm.setData([], []) curve_norm.setData([], [])
if fixed_ylim is None: if fixed_ylim is None:
y0 = float(np.nanmin(current_sweep_raw)) y_series = [current_sweep_raw, last_calib_sweep, current_sweep_norm]
y1 = float(np.nanmax(current_sweep_raw)) if current_aux_curves is not None:
if np.isfinite(y0) and np.isfinite(y1): y_series.extend(current_aux_curves)
margin = 0.05 * max(1.0, (y1 - y0)) y_limits = _compute_auto_ylim(*y_series)
p_line.setYRange(y0 - margin, y1 + margin, padding=0) if y_limits is not None:
p_line.setYRange(y_limits[0], y_limits[1], padding=0)
# Обновим спектр # Обновим спектр
sweep_for_fft = current_sweep_norm if current_sweep_norm is not None else current_sweep_raw sweep_for_fft = current_sweep_norm if current_sweep_norm is not None else current_sweep_raw
@ -1341,13 +1746,14 @@ def run_pyqtgraph(args):
seg = np.nan_to_num(sweep_for_fft[:take_fft], nan=0.0).astype(np.float32, copy=False) seg = np.nan_to_num(sweep_for_fft[:take_fft], nan=0.0).astype(np.float32, copy=False)
win = np.hanning(take_fft).astype(np.float32) win = np.hanning(take_fft).astype(np.float32)
fft_in[:take_fft] = seg * win fft_in[:take_fft] = seg * win
spec = np.fft.rfft(fft_in) spec = np.fft.ifft(fft_in)
mag = np.abs(spec).astype(np.float32) mag = np.abs(spec).astype(np.float32)
fft_vals = 20.0 * np.log10(mag + 1e-9) fft_vals = 20.0 * np.log10(mag + 1e-9)
xs_fft = freq_shared xs_fft = freq_shared
if fft_vals.size > xs_fft.size: if fft_vals.size > xs_fft.size:
fft_vals = fft_vals[: xs_fft.size] fft_vals = fft_vals[: xs_fft.size]
curve_fft.setData(xs_fft[: fft_vals.size], fft_vals) curve_fft.setData(xs_fft[: fft_vals.size], fft_vals)
p_fft.setXRange(0, max(1, xs_fft.size - 1) * 1.5, padding=0)
p_fft.setYRange(float(np.nanmin(fft_vals)), float(np.nanmax(fft_vals)), padding=0) p_fft.setYRange(float(np.nanmin(fft_vals)), float(np.nanmax(fft_vals)), padding=0)
if changed and ring is not None: if changed and ring is not None: