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jyoung/selfdrive/controls/radard.py

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#!/usr/bin/env python3
import importlib
import math
from collections import defaultdict, deque
import cereal.messaging as messaging
from cereal import car
from common.numpy_fast import interp
from common.params import Params
from common.realtime import Ratekeeper, Priority, config_realtime_process
from system.swaglog import cloudlog
from common.kalman.simple_kalman import KF1D
# Default lead acceleration decay set to 50% at 1s
_LEAD_ACCEL_TAU = 1.5
# radar tracks
SPEED, ACCEL = 0, 1 # Kalman filter states enum
# stationary qualification parameters
v_ego_stationary = 4. # no stationary object flag below this speed
RADAR_TO_CENTER = 2.7 # (deprecated) RADAR is ~ 2.7m ahead from center of car
RADAR_TO_CAMERA = 1.52 # RADAR is ~ 1.5m ahead from center of mesh frame
def get_RadarState_from_vision(lead_msg, v_ego, model_v_ego):
lead_v_rel_pred = lead_msg.v[0] - model_v_ego
return {
"dRel": float(lead_msg.x[0] - RADAR_TO_CAMERA),
"yRel": float(-lead_msg.y[0]),
"vRel": float(lead_v_rel_pred),
"vLead": float(v_ego + lead_v_rel_pred),
"vLeadK": float(v_ego + lead_v_rel_pred),
"aLeadK": 0.0,
"aLeadTau": 0.3,
"fcw": False,
"modelProb": float(lead_msg.prob),
"radar": False,
"status": True
}
class Track():
def __init__(self, v_lead, kalman_params):
self.cnt = 0
self.aLeadTau = _LEAD_ACCEL_TAU
self.K_A = kalman_params.A
self.K_C = kalman_params.C
self.K_K = kalman_params.K
self.kf = KF1D([[v_lead], [0.0]], self.K_A, self.K_C, self.K_K)
def update(self, d_rel, y_rel, v_rel, v_lead, measured):
# relative values, copy
self.dRel = d_rel # LONG_DIST
self.yRel = y_rel # -LAT_DIST
self.vRel = v_rel # REL_SPEED
self.vLead = v_lead
self.measured = measured # measured or estimate
# computed velocity and accelerations
if self.cnt > 0:
self.kf.update(self.vLead)
self.vLeadK = float(self.kf.x[SPEED][0])
self.aLeadK = float(self.kf.x[ACCEL][0])
# Learn if constant acceleration
if abs(self.aLeadK) < 0.5:
self.aLeadTau = _LEAD_ACCEL_TAU
else:
self.aLeadTau *= 0.9
self.cnt += 1
def get_key_for_cluster(self):
# Weigh y higher since radar is inaccurate in this dimension
return [self.dRel, self.yRel*2, self.vRel]
def reset_a_lead(self, aLeadK, aLeadTau):
self.kf = KF1D([[self.vLead], [aLeadK]], self.K_A, self.K_C, self.K_K)
self.aLeadK = aLeadK
self.aLeadTau = aLeadTau
def get_RadarState(self, model_prob=0.0):
return {
"dRel": float(self.dRel),
"yRel": float(self.yRel),
"vRel": float(self.vRel),
"vLead": float(self.vLead),
"vLeadK": float(self.vLeadK),
"aLeadK": float(self.aLeadK),
"status": True,
"fcw": self.is_potential_fcw(model_prob),
"modelProb": model_prob,
"radar": True,
"aLeadTau": float(self.aLeadTau)
}
def __str__(self):
ret = f"x: {self.dRel:4.1f} y: {self.yRel:4.1f} v: {self.vRel:4.1f} a: {self.aLeadK:4.1f}"
return ret
def potential_low_speed_lead(self, v_ego):
# stop for stuff in front of you and low speed, even without model confirmation
# Radar points closer than 0.75, are almost always glitches on toyota radars
return abs(self.yRel) < 1.0 and (v_ego < v_ego_stationary) and (0.75 < self.dRel < 25)
def is_potential_fcw(self, model_prob):
return model_prob > .9
class KalmanParams():
def __init__(self, dt):
# Lead Kalman Filter params, calculating K from A, C, Q, R requires the control library.
# hardcoding a lookup table to compute K for values of radar_ts between 0.01s and 0.2s
assert dt > .01 and dt < .2, "Radar time step must be between .01s and 0.2s"
self.A = [[1.0, dt], [0.0, 1.0]]
self.C = [1.0, 0.0]
#Q = np.matrix([[10., 0.0], [0.0, 100.]])
#R = 1e3
#K = np.matrix([[ 0.05705578], [ 0.03073241]])
dts = [dt * 0.01 for dt in range(1, 21)]
K0 = [0.12287673, 0.14556536, 0.16522756, 0.18281627, 0.1988689, 0.21372394,
0.22761098, 0.24069424, 0.253096, 0.26491023, 0.27621103, 0.28705801,
0.29750003, 0.30757767, 0.31732515, 0.32677158, 0.33594201, 0.34485814,
0.35353899, 0.36200124]
K1 = [0.29666309, 0.29330885, 0.29042818, 0.28787125, 0.28555364, 0.28342219,
0.28144091, 0.27958406, 0.27783249, 0.27617149, 0.27458948, 0.27307714,
0.27162685, 0.27023228, 0.26888809, 0.26758976, 0.26633338, 0.26511557,
0.26393339, 0.26278425]
self.K = [[interp(dt, dts, K0)], [interp(dt, dts, K1)]]
def laplacian_pdf(x, mu, b):
b = max(b, 1e-4)
return math.exp(-abs(x-mu)/b)
def match_vision_to_track(v_ego, lead, tracks):
offset_vision_dist = lead.x[0] - RADAR_TO_CAMERA
def prob(c):
prob_d = laplacian_pdf(c.dRel, offset_vision_dist, lead.xStd[0])
prob_y = laplacian_pdf(c.yRel, -lead.y[0], lead.yStd[0])
prob_v = laplacian_pdf(c.vRel + v_ego, lead.v[0], lead.vStd[0])
# This is isn't exactly right, but good heuristic
return prob_d * prob_y * prob_v
track = max(tracks.values(), key=prob)
# if no 'sane' match is found return -1
# stationary radar points can be false positives
dist_sane = abs(track.dRel - offset_vision_dist) < max([(offset_vision_dist)*.25, 5.0])
vel_sane = (abs(track.vRel + v_ego - lead.v[0]) < 10) or (v_ego + track.vRel > 3)
if dist_sane and vel_sane:
return track
else:
return None
def get_lead(v_ego, ready, tracks, lead_msg, model_v_ego, low_speed_override=True):
# Determine leads, this is where the essential logic happens
if len(tracks) > 0 and ready and lead_msg.prob > .5:
track = match_vision_to_track(v_ego, lead_msg, tracks)
else:
track = None
lead_dict = {'status': False}
if track is not None:
lead_dict = track.get_RadarState(lead_msg.prob)
elif (track is None) and ready and (lead_msg.prob > .5):
lead_dict = get_RadarState_from_vision(lead_msg, v_ego, model_v_ego)
if low_speed_override:
low_speed_tracks = [c for c in tracks.values() if c.potential_low_speed_lead(v_ego)]
if len(low_speed_tracks) > 0:
closest_track = min(low_speed_tracks, key=lambda c: c.dRel)
# Only choose new track if it is actually closer than the previous one
if (not lead_dict['status']) or (closest_track.dRel < lead_dict['dRel']):
lead_dict = closest_track.get_RadarState()
return lead_dict
class RadarD():
def __init__(self, radar_ts, delay=0):
self.current_time = 0
self.tracks = defaultdict(dict)
self.kalman_params = KalmanParams(radar_ts)
# v_ego
self.v_ego = 0.
self.v_ego_hist = deque([0], maxlen=delay+1)
self.ready = False
def update(self, sm, rr):
self.current_time = 1e-9*max(sm.logMonoTime.values())
if sm.updated['carState']:
self.v_ego = sm['carState'].vEgo
self.v_ego_hist.append(self.v_ego)
if sm.updated['modelV2']:
self.ready = True
ar_pts = {}
for pt in rr.points:
ar_pts[pt.trackId] = [pt.dRel, pt.yRel, pt.vRel, pt.measured]
# *** remove missing points from meta data ***
for ids in list(self.tracks.keys()):
if ids not in ar_pts:
self.tracks.pop(ids, None)
# *** compute the tracks ***
for ids in ar_pts:
rpt = ar_pts[ids]
# align v_ego by a fixed time to align it with the radar measurement
v_lead = rpt[2] + self.v_ego_hist[0]
# create the track if it doesn't exist or it's a new track
if ids not in self.tracks:
self.tracks[ids] = Track(v_lead, self.kalman_params)
self.tracks[ids].update(rpt[0], rpt[1], rpt[2], v_lead, rpt[3])
# *** publish radarState ***
dat = messaging.new_message('radarState')
dat.valid = sm.all_checks() and len(rr.errors) == 0
radarState = dat.radarState
radarState.mdMonoTime = sm.logMonoTime['modelV2']
radarState.radarErrors = list(rr.errors)
radarState.carStateMonoTime = sm.logMonoTime['carState']
if len(sm['modelV2'].temporalPose.trans):
model_v_ego = sm['modelV2'].temporalPose.trans[0]
else:
model_v_ego = self.v_ego
leads_v3 = sm['modelV2'].leadsV3
if len(leads_v3) > 1:
radarState.leadOne = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[0], model_v_ego, low_speed_override=True)
radarState.leadTwo = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[1], model_v_ego, low_speed_override=False)
return dat
# fuses camera and radar data for best lead detection
def radard_thread(sm=None, pm=None, can_sock=None):
config_realtime_process(5, Priority.CTRL_LOW)
# wait for stats about the car to come in from controls
cloudlog.info("radard is waiting for CarParams")
CP = car.CarParams.from_bytes(Params().get("CarParams", block=True))
cloudlog.info("radard got CarParams")
# import the radar from the fingerprint
cloudlog.info("radard is importing %s", CP.carName)
RadarInterface = importlib.import_module(f'selfdrive.car.{CP.carName}.radar_interface').RadarInterface
# *** setup messaging
if can_sock is None:
can_sock = messaging.sub_sock('can')
if sm is None:
sm = messaging.SubMaster(['modelV2', 'carState'], ignore_avg_freq=['modelV2', 'carState']) # Can't check average frequency, since radar determines timing
if pm is None:
pm = messaging.PubMaster(['radarState', 'liveTracks'])
RI = RadarInterface(CP)
rk = Ratekeeper(1.0 / CP.radarTimeStep, print_delay_threshold=None)
RD = RadarD(CP.radarTimeStep, RI.delay)
while 1:
can_strings = messaging.drain_sock_raw(can_sock, wait_for_one=True)
rr = RI.update(can_strings)
if rr is None:
continue
sm.update(0)
dat = RD.update(sm, rr)
dat.radarState.cumLagMs = -rk.remaining*1000.
pm.send('radarState', dat)
# *** publish tracks for UI debugging (keep last) ***
tracks = RD.tracks
dat = messaging.new_message('liveTracks', len(tracks))
for cnt, ids in enumerate(sorted(tracks.keys())):
dat.liveTracks[cnt] = {
"trackId": ids,
"dRel": float(tracks[ids].dRel),
"yRel": float(tracks[ids].yRel),
"vRel": float(tracks[ids].vRel),
}
pm.send('liveTracks', dat)
rk.monitor_time()
def main(sm=None, pm=None, can_sock=None):
radard_thread(sm, pm, can_sock)
if __name__ == "__main__":
main()