Files
ESP/visualise.py
Brunsmeier fd286e6a9e Add episode recording functionality and enhance serial communication handling
- Introduced record_episode.py for capturing ESP32 IMU data and RealSense images.
- Added SwitchChangeDetector and SwitchLevelController for managing recording triggers.
- Enhanced ESP32Bridge with new methods for reading samples and latest packets.
- Updated verify.py and visualise.py to improve serial communication stability.
- Modified .gitignore to include dataset, csv, and png directories.
2026-07-03 10:53:49 +08:00

544 lines
15 KiB
Python

import argparse
import ast
import csv
import os
import re
import sys
import time
from datetime import datetime
os.environ.setdefault("MPLCONFIGDIR", "/tmp/matplotlib")
import matplotlib.pyplot as plt
import numpy as np
import serial
from pc_reader import PACKET_SIZE, SYNC, decode_packet
TEXT_LINE_RE = re.compile(
r"#?\s*(?P<count>\d+)\s+"
r"(?P<freq>[-+]?\d+(?:\.\d+)?)Hz\s+"
r"DIN=(?P<din>\[[^\]]+\])\s+"
r"DOUT=(?P<dout>\[[^\]]+\])\s+"
r"ACC=(?P<acc>\[[^\]]+\])\s+"
r"GYRO=(?P<gyro>\[[^\]]+\])\s+"
r"ANGLE=(?P<angle>\[[^\]]+\])"
)
FIELD_NAMES = (
"acc_x_g",
"acc_y_g",
"acc_z_g",
"gyro_x_dps",
"gyro_y_dps",
"gyro_z_dps",
"angle_x_deg",
"angle_y_deg",
"angle_z_deg",
"temp_c",
"freq_hz",
)
def read_serial_samples(port, baud, seconds=None, max_samples=None, max_gap_ms=1000):
samples = []
buffer = bytearray()
last_t_ms = None
elapsed_s = 0.0
bad_delta_count = 0
ser = serial.Serial()
ser.port = port
ser.baudrate = baud
ser.timeout = 0.05
ser.write_timeout = 0.05
# 关键:避免 ESP32 因 DTR/RTS 被 pyserial 拉动而自动 reset / 进入 boot mode
ser.dtr = False
ser.rts = False
ser.open()
try:
ser.dtr = False
ser.rts = False
ser.reset_input_buffer()
ser.reset_output_buffer()
print("Reading {} at {} baud...".format(port, baud), file=sys.stderr)
print("Waiting for ESP32 main.py startup...", file=sys.stderr)
time.sleep(4.0)
start = time.monotonic()
while True:
if seconds is not None and time.monotonic() - start >= seconds:
break
if max_samples is not None and len(samples) >= max_samples:
break
chunk = ser.read(ser.in_waiting or 1)
if chunk:
buffer.extend(chunk)
while len(buffer) >= PACKET_SIZE:
sync_index = buffer.find(SYNC)
if sync_index < 0:
del buffer[:-1]
break
if sync_index:
del buffer[:sync_index]
if len(buffer) < PACKET_SIZE:
break
packet = bytes(buffer[:PACKET_SIZE])
if (sum(packet[:-1]) & 0xFF) != packet[-1]:
del buffer[0]
continue
del buffer[:PACKET_SIZE]
data = decode_packet(packet)
if last_t_ms is None:
freq_hz = 0.0
else:
delta = (data["t_ms"] - last_t_ms) & 0xFFFFFFFF
if 0 < delta <= max_gap_ms:
elapsed_s += delta / 1000.0
freq_hz = 1000.0 / delta
else:
bad_delta_count += 1
freq_hz = 0.0
last_t_ms = data["t_ms"]
samples.append(flatten_packet(data, elapsed_s, freq_hz))
if max_samples is not None and len(samples) >= max_samples:
break
finally:
ser.close()
if bad_delta_count:
print(
"Ignored {} abnormal packet time delta(s).".format(bad_delta_count),
file=sys.stderr,
)
return samples
def flatten_packet(data, t_s, freq_hz):
return {
"t_s": t_s,
"acc_x_g": data["acc_g"][0],
"acc_y_g": data["acc_g"][1],
"acc_z_g": data["acc_g"][2],
"gyro_x_dps": data["gyro_dps"][0],
"gyro_y_dps": data["gyro_dps"][1],
"gyro_z_dps": data["gyro_dps"][2],
"angle_x_deg": data["angle_deg"][0],
"angle_y_deg": data["angle_deg"][1],
"angle_z_deg": data["angle_deg"][2],
"temp_c": data["temp_c"],
"freq_hz": freq_hz,
"din0": data["din"][0],
"din1": data["din"][1],
"din2": data["din"][2],
"din3": data["din"][3],
"dout0": data["dout"][0],
"dout1": data["dout"][1],
}
def read_text_log(path):
samples = []
t_s = 0.0
with open(path, "r", encoding="utf-8") as f:
for line in f:
match = TEXT_LINE_RE.search(line)
if not match:
continue
freq_hz = float(match.group("freq"))
din = ast.literal_eval(match.group("din"))
dout = ast.literal_eval(match.group("dout"))
acc = ast.literal_eval(match.group("acc"))
gyro = ast.literal_eval(match.group("gyro"))
angle = ast.literal_eval(match.group("angle"))
if samples and freq_hz > 0:
t_s += 1.0 / freq_hz
samples.append(
{
"t_s": t_s,
"acc_x_g": acc[0],
"acc_y_g": acc[1],
"acc_z_g": acc[2],
"gyro_x_dps": gyro[0],
"gyro_y_dps": gyro[1],
"gyro_z_dps": gyro[2],
"angle_x_deg": angle[0],
"angle_y_deg": angle[1],
"angle_z_deg": angle[2],
"temp_c": np.nan,
"freq_hz": freq_hz,
"din0": din[0],
"din1": din[1],
"din2": din[2],
"din3": din[3],
"dout0": dout[0],
"dout1": dout[1],
}
)
return samples
def write_csv(samples, path):
if not samples:
return
columns = list(samples[0].keys())
with open(path, "w", newline="", encoding="utf-8") as f:
writer = csv.DictWriter(f, fieldnames=columns)
writer.writeheader()
writer.writerows(samples)
def euler_to_rot_matrix(roll_deg, pitch_deg, yaw_deg):
"""
Convert IMU Euler angles to body->world rotation matrix.
Assumption:
angle_x = roll
angle_y = pitch
angle_z = yaw
Rotation order:
R = Rz(yaw) @ Ry(pitch) @ Rx(roll)
注意:这个顺序要和 IWT603 官方定义确认。
如果发现补偿后静止时 linear_acc 不接近 0.需要调整欧拉角顺序或正负号。
"""
roll = np.deg2rad(roll_deg)
pitch = np.deg2rad(pitch_deg)
yaw = np.deg2rad(yaw_deg)
cr, sr = np.cos(roll), np.sin(roll)
cp, sp = np.cos(pitch), np.sin(pitch)
cy, sy = np.cos(yaw), np.sin(yaw)
Rx = np.array([
[1, 0, 0],
[0, cr, -sr],
[0, sr, cr],
])
Ry = np.array([
[cp, 0, sp],
[0, 1, 0],
[-sp, 0, cp],
])
Rz = np.array([
[cy, -sy, 0],
[sy, cy, 0],
[0, 0, 1],
])
return Rz @ Ry @ Rx
def add_linear_velocity(samples, gravity_sign=1.0, acc_deadband=0.15, vel_decay=0.995, bias_seconds=1.0):
if not samples:
return samples
# 先计算每一帧的重力补偿线加速度
raw_linear_acc_list = []
for sample in samples:
acc_body_g = np.array([
sample["acc_x_g"],
sample["acc_y_g"],
sample["acc_z_g"],
], dtype=float)
R = euler_to_rot_matrix(
sample["angle_x_deg"],
sample["angle_y_deg"],
sample["angle_z_deg"],
)
acc_world_g = R @ acc_body_g
linear_acc_world_g = acc_world_g - np.array([0.0, 0.0, gravity_sign])
linear_acc_world = linear_acc_world_g * 9.81
raw_linear_acc_list.append(linear_acc_world)
raw_linear_acc_arr = np.array(raw_linear_acc_list)
# 用前 bias_seconds 秒估计静止零偏
t0 = samples[0]["t_s"]
bias_indices = [
i for i, s in enumerate(samples)
if s["t_s"] - t0 <= bias_seconds
]
if bias_indices:
acc_bias = np.mean(raw_linear_acc_arr[bias_indices], axis=0)
else:
acc_bias = np.zeros(3)
print("Estimated linear acc bias m/s^2:", acc_bias)
v = np.zeros(3, dtype=float)
last_t = samples[0]["t_s"]
for i, sample in enumerate(samples):
t = sample["t_s"]
dt = t - last_t
last_t = t
if dt <= 0 or dt > 0.2:
dt = 0.0
linear_acc_world = raw_linear_acc_arr[i] - acc_bias
if np.linalg.norm(linear_acc_world) < acc_deadband:
linear_acc_world[:] = 0.0
v = v * vel_decay + linear_acc_world * dt
sample["lin_acc_x_ms2"] = linear_acc_world[0]
sample["lin_acc_y_ms2"] = linear_acc_world[1]
sample["lin_acc_z_ms2"] = linear_acc_world[2]
sample["vel_x_ms"] = v[0]
sample["vel_y_ms"] = v[1]
sample["vel_z_ms"] = v[2]
return samples
def unique_path(path):
"""
Automatically save CSV into ./csv/
Automatically save PNG into ./png/
Create folders if they do not exist.
"""
if not path:
return path
root, ext = os.path.splitext(os.path.basename(path))
ext = ext.lower()
if ext == ".csv":
folder = "csv"
elif ext == ".png":
folder = "png"
else:
folder = "output"
os.makedirs(folder, exist_ok=True)
new_path = os.path.join(folder, root + ext)
if not os.path.exists(new_path):
return new_path
timestamp = datetime.now().strftime("%Y%m%d_%H%M%S")
return os.path.join(folder, "{}_{}{}".format(root, timestamp, ext))
def print_stats(samples):
if not samples:
print("No samples parsed.")
return
print("Samples: {}".format(len(samples)))
print("Duration: {:.3f}s".format(samples[-1]["t_s"] - samples[0]["t_s"]))
for group_name, fields in (
("ACC g", ("acc_x_g", "acc_y_g", "acc_z_g")),
("GYRO dps", ("gyro_x_dps", "gyro_y_dps", "gyro_z_dps")),
("ANGLE deg", ("angle_x_deg", "angle_y_deg", "angle_z_deg")),
):
print("\n{}".format(group_name))
for field in fields:
values = np.array([sample[field] for sample in samples], dtype=float)
diffs = np.diff(values)
diff_std = float(np.std(diffs)) if len(diffs) else 0.0
print(
" {:12s} mean={: .6f} std={:.6f} ptp={:.6f} diff_std={:.6f}".format(
field,
float(np.mean(values)),
float(np.std(values)),
float(np.ptp(values)),
diff_std,
)
)
freq = np.array([sample["freq_hz"] for sample in samples[1:]], dtype=float)
if len(freq):
print(
"\nFrequency Hz mean={:.3f} std={:.3f} min={:.3f} max={:.3f}".format(
float(np.mean(freq)),
float(np.std(freq)),
float(np.min(freq)),
float(np.max(freq)),
)
)
if "lin_acc_x_ms2" in samples[0]:
print("\nLINEAR ACC m/s^2")
for field in ("lin_acc_x_ms2", "lin_acc_y_ms2", "lin_acc_z_ms2"):
values = np.array([sample[field] for sample in samples], dtype=float)
diffs = np.diff(values)
diff_std = float(np.std(diffs)) if len(diffs) else 0.0
print(
" {:16s} mean={: .6f} std={:.6f} ptp={:.6f} diff_std={:.6f}".format(
field,
float(np.mean(values)),
float(np.std(values)),
float(np.ptp(values)),
diff_std,
)
)
if "vel_x_ms" in samples[0]:
print("\nVELOCITY m/s")
for field in ("vel_x_ms", "vel_y_ms", "vel_z_ms"):
values = np.array([sample[field] for sample in samples], dtype=float)
print(
" {:16s} mean={: .6f} std={:.6f} ptp={:.6f} final={: .6f}".format(
field,
float(np.mean(values)),
float(np.std(values)),
float(np.ptp(values)),
float(values[-1]),
)
)
def plot_samples(samples, output=None, show=True):
if not samples:
raise ValueError("No samples to plot.")
t = np.array([sample["t_s"] for sample in samples], dtype=float)
fig, axes = plt.subplots(6, 1, sharex=True, figsize=(13, 13))
plot_group(
axes[0],
t,
samples,
("acc_x_g", "acc_y_g", "acc_z_g"),
"Raw Acc (g)",
)
plot_group(
axes[1],
t,
samples,
("lin_acc_x_ms2", "lin_acc_y_ms2", "lin_acc_z_ms2"),
"Linear Acc (m/s²)",
)
plot_group(
axes[2],
t,
samples,
("vel_x_ms", "vel_y_ms", "vel_z_ms"),
"Velocity (m/s)",
)
plot_group(
axes[3],
t,
samples,
("gyro_x_dps", "gyro_y_dps", "gyro_z_dps"),
"Gyro (deg/s)",
)
plot_group(
axes[4],
t,
samples,
("angle_x_deg", "angle_y_deg", "angle_z_deg"),
"Angle (deg)",
)
freq = np.array([sample["freq_hz"] for sample in samples], dtype=float)
axes[5].plot(t, freq, label="freq_hz", linewidth=1.0)
axes[5].set_ylabel("Hz")
axes[5].set_xlabel("Time (s)")
axes[5].grid(True, alpha=0.3)
axes[5].legend(loc="upper right")
fig.suptitle("IMU Data Quality Overview")
fig.tight_layout()
if output:
fig.savefig(output, dpi=160)
print("Saved plot to {}".format(output))
if show:
plt.show()
def plot_group(axis, t, samples, fields, ylabel):
for field in fields:
values = np.array([sample[field] for sample in samples], dtype=float)
axis.plot(t, values, label=field, linewidth=1.0)
axis.set_ylabel(ylabel)
axis.grid(True, alpha=0.3)
axis.legend(loc="upper right", ncol=3)
def main():
parser = argparse.ArgumentParser(
description="Read ESP IMU data and visualise signal quality/noise."
)
source = parser.add_mutually_exclusive_group(required=True)
source.add_argument("--file", help="pc_reader text log, for example rcd.txt")
source.add_argument("--port", help="ESP32 serial port, for example /dev/ttyUSB0")
parser.add_argument("--baud", type=int, default=115200)
parser.add_argument("--seconds", type=float, default=10.0)
parser.add_argument("--samples", type=int)
parser.add_argument(
"--max-gap-ms",
type=int,
default=1000,
help="Ignore packet timestamp jumps larger than this.",
)
parser.add_argument("--output", default="imu_quality.png")
parser.add_argument("--csv", help="Optional CSV export path.")
parser.add_argument("--no-show", action="store_true", help="Save only; do not open a window.")
args = parser.parse_args()
if args.file:
samples = read_text_log(args.file)
else:
samples = read_serial_samples(
args.port,
args.baud,
args.seconds,
args.samples,
args.max_gap_ms,
)
# 关键:没有样本就直接退出,避免后面 CSV/plot 误报或报错
if not samples:
print("No samples parsed. Check input mode, serial port, baudrate, or log file format.")
return
samples = add_linear_velocity(samples, gravity_sign=1.0)
print_stats(samples)
if args.csv:
csv_path = unique_path(args.csv)
write_csv(samples, csv_path)
print("Saved CSV to {}".format(csv_path))
output_path = unique_path(args.output)
plot_samples(samples, output=output_path, show=not args.no_show)
if __name__ == "__main__":
main()
# python3 visualise.py --port /dev/ttyUSB0 --baud 115200 --seconds 10 --csv imu_data.csv