mirror of
https://github.com/firestar5683/StarPilot.git
synced 2026-07-13 21:32:14 +08:00
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@@ -60,33 +60,31 @@ class FrogPilotPlanner:
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def update(self, now, time_validated, sm, frogpilot_toggles):
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self.lead_one = sm["radarState"].leadOne
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long_control_active = sm["carControl"].longActive
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controls_enabled = sm["selfdriveState"].enabled
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planner_active = controls_enabled or long_control_active
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v_cruise_kph = sm["carState"].vCruise
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v_cruise_kph = min(sm["carState"].vCruise, V_CRUISE_MAX)
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if 0 < v_cruise_kph < V_CRUISE_UNSET and frogpilot_toggles.set_speed_offset > 0:
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v_cruise_kph += frogpilot_toggles.set_speed_offset
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v_cruise = min(v_cruise_kph, V_CRUISE_MAX) * CV.KPH_TO_MS
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v_cruise = v_cruise_kph * CV.KPH_TO_MS
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v_ego = max(sm["carState"].vEgo, 0)
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if planner_active:
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if controls_enabled:
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self.frogpilot_acceleration.update(v_ego, sm, frogpilot_toggles)
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else:
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self.frogpilot_acceleration.max_accel = 0
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self.frogpilot_acceleration.min_accel = 0
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if planner_active and frogpilot_toggles.conditional_experimental_mode:
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if controls_enabled and frogpilot_toggles.conditional_experimental_mode:
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self.frogpilot_cem.update(v_ego, sm, frogpilot_toggles)
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else:
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self.frogpilot_cem.experimental_mode = False
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self.frogpilot_cem.curve_detected = False
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self.frogpilot_cem.stop_sign_and_light(v_ego, sm, PLANNER_TIME - 2)
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self.driving_in_curve = abs(self.lateral_acceleration) >= MINIMUM_LATERAL_ACCELERATION
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self.frogpilot_events.update(planner_active, v_cruise, sm, frogpilot_toggles)
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self.frogpilot_events.update(controls_enabled, v_cruise, sm, frogpilot_toggles)
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self.frogpilot_following.update(planner_active, v_ego, sm, frogpilot_toggles)
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self.frogpilot_following.update(controls_enabled, v_ego, sm, frogpilot_toggles)
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gps_location = sm[self.gps_location_service]
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self.gps_position = {
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@@ -97,7 +95,8 @@ class FrogPilotPlanner:
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self.gps_valid = self.gps_position["latitude"] != 0 or self.gps_position["longitude"] != 0
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self.params_memory.put("LastGPSPosition", json.dumps(self.gps_position))
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if v_ego >= frogpilot_toggles.minimum_lane_change_speed:
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check_lane_width = frogpilot_toggles.adjacent_paths or frogpilot_toggles.adjacent_path_metrics or frogpilot_toggles.blind_spot_path or frogpilot_toggles.lane_detection
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if check_lane_width and v_ego >= frogpilot_toggles.minimum_lane_change_speed:
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self.lane_width_left = calculate_lane_width(sm["modelV2"].laneLines[0], sm["modelV2"].laneLines[1], sm["modelV2"].roadEdges[0])
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self.lane_width_right = calculate_lane_width(sm["modelV2"].laneLines[3], sm["modelV2"].laneLines[2], sm["modelV2"].roadEdges[1])
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else:
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@@ -123,7 +122,7 @@ class FrogPilotPlanner:
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if not sm["carState"].standstill:
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self.tracking_lead = self.update_lead_status(frogpilot_toggles.stop_distance)
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self.v_cruise = self.frogpilot_vcruise.update(planner_active, now, time_validated, v_cruise, v_ego, sm, frogpilot_toggles)
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self.v_cruise = self.frogpilot_vcruise.update(controls_enabled, now, time_validated, v_cruise, v_ego, sm, frogpilot_toggles)
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if self.gps_valid and time_validated and frogpilot_toggles.weather_presets:
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self.frogpilot_weather.update_weather(now, frogpilot_toggles)
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@@ -540,7 +540,7 @@ class LongitudinalMpc:
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# Update in ACC mode or ACC/e2e blend
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if self.mode == 'acc':
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self.params[:,5] = danger_factor
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self.params[:,5] = LEAD_DANGER_FACTOR
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# Fake an obstacle for cruise, this ensures smooth acceleration to set speed
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# when the leads are no factor.
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@@ -16,8 +16,6 @@ from openpilot.selfdrive.controls.lib.drive_helpers import CONTROL_N
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from openpilot.selfdrive.car.cruise import V_CRUISE_UNSET
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from openpilot.common.swaglog import cloudlog
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from openpilot.frogpilot.common.frogpilot_variables import MINIMUM_LATERAL_ACCELERATION
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LON_MPC_STEP = 0.2 # first step is 0.2s
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A_CRUISE_MIN = -1.0
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A_CRUISE_MAX_BP = [0.0, 5., 10., 15., 20., 25., 40.]
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@@ -51,11 +49,7 @@ def limit_accel_in_turns(v_ego, angle_steers, a_target, CP):
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# The lookup table for turns should also be updated if we do this
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a_total_max = np.interp(v_ego, _A_TOTAL_MAX_BP, _A_TOTAL_MAX_V)
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a_y = v_ego ** 2 * angle_steers * CV.DEG_TO_RAD / (CP.steerRatio * CP.wheelbase)
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if abs(a_y) > MINIMUM_LATERAL_ACCELERATION:
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a_x_allowed = math.sqrt(max(a_total_max ** 2 - a_y ** 2, 0.))
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else:
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a_x_allowed = a_target[1]
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a_x_allowed = math.sqrt(max(a_total_max ** 2 - a_y ** 2, 0.))
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return [a_target[0], min(a_target[1], a_x_allowed)]
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@@ -146,8 +140,11 @@ class LongitudinalPlanner:
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@staticmethod
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def get_model_speed_error(model_msg, v_ego):
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if len(model_msg.temporalPose.trans):
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return float(np.clip(model_msg.temporalPose.trans[0] - v_ego, -5.0, 5.0))
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try:
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if len(model_msg.temporalPose.trans):
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return float(np.clip(model_msg.temporalPose.trans[0] - v_ego, -5.0, 5.0))
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except AttributeError:
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pass
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if len(model_msg.velocity.x) == ModelConstants.IDX_N:
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return float(np.clip(model_msg.velocity.x[0] - v_ego, -5.0, 5.0))
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return 0.0
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@@ -18,7 +18,7 @@ from openpilot.frogpilot.common.frogpilot_variables import THRESHOLD, get_frogpi
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# Default lead acceleration decay set to 50% at 1s
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_LEAD_ACCEL_TAU = 1.5
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_LEAD_ACCEL_TAU = 0.6
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# radar tracks
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SPEED, ACCEL = 0, 1 # Kalman filter states enum
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@@ -37,9 +37,6 @@ class KalmanParams:
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assert dt > .01 and dt < .2, "Radar time step must be between .01s and 0.2s"
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self.A = [[1.0, dt], [0.0, 1.0]]
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self.C = [1.0, 0.0]
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#Q = np.matrix([[10., 0.0], [0.0, 100.]])
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#R = 1e3
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#K = np.matrix([[ 0.05705578], [ 0.03073241]])
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dts = [i * 0.01 for i in range(1, 21)]
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K0 = [0.12287673, 0.14556536, 0.16522756, 0.18281627, 0.1988689, 0.21372394,
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0.22761098, 0.24069424, 0.253096, 0.26491023, 0.27621103, 0.28705801,
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@@ -63,12 +60,8 @@ class Track:
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self.kf = KF1D([[v_lead], [0.0]], self.K_A, self.K_C, self.K_K)
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# FrogPilot variables
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self.leadLeft = False
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self.leadRight = False
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self.leadTrackID = 0
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self.radarfulFilter = FirstOrderFilter(0, 1, self.K_A[0][1])
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self.radarfulFilter = FirstOrderFilter(0, 0.5, self.K_A[0][1])
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def update(self, d_rel: float, y_rel: float, v_rel: float, v_lead: float, measured: float):
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# relative values, copy
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@@ -87,7 +80,7 @@ class Track:
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# Learn if constant acceleration
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if abs(self.aLeadK) < 0.5:
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self.aLeadTau.x = _LEAD_ACCEL_TAU
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self.aLeadTau.x = min(max(self.aLeadTau.x, 1e-2) * 1.1, _LEAD_ACCEL_TAU)
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else:
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self.aLeadTau.update(0.0)
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@@ -109,6 +102,29 @@ class Track:
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"radarTrackId": self.identifier,
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}
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def potential_adjacent_lead(self, left: bool, standstill: bool, model_data: capnp._DynamicStructReader):
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if standstill or self.vLead < 1 or self.leadTrackID == self.identifier:
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return False
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if left:
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left_lane = np.interp(self.dRel, model_data.laneLines[1].x, model_data.laneLines[1].y)
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return -self.yRel < left_lane
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right_lane = np.interp(self.dRel, model_data.laneLines[2].x, model_data.laneLines[2].y)
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return -self.yRel > right_lane
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def potential_far_lead(self, standstill: bool, model_data: capnp._DynamicStructReader):
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if standstill or self.vLead < 1 or abs(self.yRel) > 1:
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return False
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left_lane = np.interp(self.dRel, model_data.laneLines[1].x, model_data.laneLines[1].y)
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right_lane = np.interp(self.dRel, model_data.laneLines[2].x, model_data.laneLines[2].y)
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if left_lane < -self.yRel < right_lane:
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self.radarfulFilter.update(1)
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return True
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self.radarfulFilter.update(0)
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return False
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def potential_low_speed_lead(self, v_ego: float):
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# stop for stuff in front of you and low speed, even without model confirmation
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# Radar points closer than 0.75, are almost always glitches on toyota radars
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@@ -121,35 +137,6 @@ class Track:
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ret = f"x: {self.dRel:4.1f} y: {self.yRel:4.1f} v: {self.vRel:4.1f} a: {self.aLeadK:4.1f}"
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return ret
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# FrogPilot variables
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def potential_adjacent_lead(self, left: bool, model_data: capnp._DynamicStructReader):
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if self.vLeadK < 1 or self.leadTrackID == self.identifier:
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return False
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far_left_lane = np.interp(self.dRel, model_data.laneLines[0].x, model_data.laneLines[0].y)
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left_lane = np.interp(self.dRel, model_data.laneLines[1].x, model_data.laneLines[1].y)
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right_lane = np.interp(self.dRel, model_data.laneLines[2].x, model_data.laneLines[2].y)
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far_right_lane = np.interp(self.dRel, model_data.laneLines[3].x, model_data.laneLines[3].y)
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self.leadLeft = far_left_lane < -self.yRel < left_lane and self.dRel < model_data.position.x[-1]
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self.leadRight = right_lane < -self.yRel < far_right_lane and self.dRel < model_data.position.x[-1]
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if left:
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return self.leadLeft
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else:
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return self.leadRight
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def potential_far_lead(self, lead_msg: capnp._DynamicStructReader, model_data: capnp._DynamicStructReader):
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left_lane = np.interp(self.dRel, model_data.laneLines[1].x, model_data.laneLines[1].y)
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right_lane = np.interp(self.dRel, model_data.laneLines[2].x, model_data.laneLines[2].y)
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if left_lane < -self.yRel < right_lane and self.dRel < model_data.position.x[-1] and self.vLeadK > 1:
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self.radarfulFilter.update(1)
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return True
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else:
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self.radarfulFilter.update(0)
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return False
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def laplacian_pdf(x: float, mu: float, b: float):
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b = max(b, 1e-4)
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@@ -157,19 +144,12 @@ def laplacian_pdf(x: float, mu: float, b: float):
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def match_vision_to_track(v_ego: float, lead: capnp._DynamicStructReader, model_data: capnp._DynamicStructReader, tracks: dict[int, Track], frogpilot_toggles: SimpleNamespace):
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# FrogPilot variables
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if model_data.meta.laneChangeState == LaneChangeState.laneChangeStarting and frogpilot_toggles.human_lane_changes:
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if model_data.meta.laneChangeState == LaneChangeState.laneChangeStarting and getattr(frogpilot_toggles, "human_lane_changes", False):
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direction = model_data.meta.laneChangeDirection
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if direction == LaneChangeDirection.left:
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left_tracks = [track for track in tracks.values() if track.leadLeft]
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if left_tracks:
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return min(left_tracks, key=lambda c: c.dRel)
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tracks = {k: v for k, v in tracks.items() if v.yRel > 0}
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elif direction == LaneChangeDirection.right:
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right_tracks = [track for track in tracks.values() if track.leadRight]
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if right_tracks:
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return min(right_tracks, key=lambda c: c.dRel)
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tracks = {k: v for k, v in tracks.items() if v.yRel < 0}
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offset_vision_dist = lead.x[0] - RADAR_TO_CAMERA
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@@ -177,31 +157,30 @@ def match_vision_to_track(v_ego: float, lead: capnp._DynamicStructReader, model_
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prob_d = laplacian_pdf(c.dRel, offset_vision_dist, lead.xStd[0])
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prob_y = laplacian_pdf(c.yRel, -lead.y[0], lead.yStd[0])
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prob_v = laplacian_pdf(c.vRel + v_ego, lead.v[0], lead.vStd[0])
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# This isn't exactly right, but it's a good heuristic
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return prob_d * prob_y * prob_v
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track = max(tracks.values(), key=prob)
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# if no 'sane' match is found return -1
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# stationary radar points can be false positives
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dist_sane = abs(track.dRel - offset_vision_dist) < max([(offset_vision_dist)*.25, 5.0])
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dist_sane = abs(track.dRel - offset_vision_dist) < max([(offset_vision_dist) * .25, 5.0])
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vel_sane = (abs(track.vRel + v_ego - lead.v[0]) < 10) or (v_ego + track.vRel > 3)
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if dist_sane and vel_sane:
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return track
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else:
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return None
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return None
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def get_RadarState_from_vision(lead_msg: capnp._DynamicStructReader, v_ego: float, model_v_ego: float):
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lead_v_rel_pred = lead_msg.v[0] - model_v_ego
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prev_aLeadK = getattr(get_RadarState_from_vision, "prev_aLeadK", 0.0)
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blended_aLeadK = 0.8 * float(lead_msg.a[0]) + 0.2 * prev_aLeadK
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get_RadarState_from_vision.prev_aLeadK = blended_aLeadK
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return {
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"dRel": float(lead_msg.x[0] - RADAR_TO_CAMERA),
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"yRel": float(-lead_msg.y[0]),
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"vRel": float(lead_v_rel_pred),
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"vLead": float(v_ego + lead_v_rel_pred),
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"vLeadK": float(v_ego + lead_v_rel_pred),
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"aLeadK": float(lead_msg.a[0]),
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"vRel": float(lead_msg.v[0] - model_v_ego),
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"vLead": float(v_ego + (lead_msg.v[0] - model_v_ego)),
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"vLeadK": float(v_ego + (lead_msg.v[0] - model_v_ego)),
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"aLeadK": blended_aLeadK,
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"aLeadTau": 0.3,
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"fcw": False,
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"modelProb": float(lead_msg.prob),
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@@ -212,13 +191,10 @@ def get_RadarState_from_vision(lead_msg: capnp._DynamicStructReader, v_ego: floa
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def get_lead(v_ego: float, ready: bool, tracks: dict[int, Track], lead_msg: capnp._DynamicStructReader,
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model_v_ego: float, model_data: capnp._DynamicStructReader,
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model_v_ego: float, model_data: capnp._DynamicStructReader, standstill: bool,
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frogpilot_plan: capnp._DynamicStructReader, frogpilot_toggles: SimpleNamespace,
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low_speed_override: bool = True) -> dict[str, Any]:
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lead_detection_probability = float(getattr(frogpilot_toggles, "lead_detection_probability", 0.35) or 0.35)
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if lead_detection_probability > 1.0:
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lead_detection_probability *= 0.01
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lead_detection_probability = float(np.clip(lead_detection_probability, 0.25, 0.5))
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lead_detection_probability = float(getattr(frogpilot_toggles, "lead_detection_probability", 0.35))
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# Determine leads, this is where the essential logic happens
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if len(tracks) > 0 and ready and lead_msg.prob > lead_detection_probability:
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@@ -241,11 +217,11 @@ def get_lead(v_ego: float, ready: bool, tracks: dict[int, Track], lead_msg: capn
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if (not lead_dict['status']) or (closest_track.dRel < lead_dict['dRel']):
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lead_dict = closest_track.get_RadarState()
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if low_speed_override and not lead_dict['status'] and len(tracks) > 0:
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far_lead_tracks = [c for c in tracks.values() if c.potential_far_lead(lead_msg, model_data) and c.radarfulFilter.x >= THRESHOLD]
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if len(far_lead_tracks) > 0:
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closest_track = min(far_lead_tracks, key=lambda c: c.dRel)
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lead_dict = closest_track.get_RadarState()
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if not lead_dict['status'] and len(tracks) > 0:
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far_lead_tracks = [c for c in tracks.values() if c.potential_far_lead(standstill, model_data) and c.radarfulFilter.x >= THRESHOLD]
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if len(far_lead_tracks) > 0:
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closest_track = min(far_lead_tracks, key=lambda c: c.dRel)
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lead_dict = closest_track.get_RadarState()
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# FrogPilot variables
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for track in tracks.values():
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@@ -257,11 +233,10 @@ def get_lead(v_ego: float, ready: bool, tracks: dict[int, Track], lead_msg: capn
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return lead_dict
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# FrogPilot variables
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def get_adjacent_lead(tracks: dict[int, Track], model_data: capnp._DynamicStructReader, left: bool = True) -> dict[str, Any]:
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def get_adjacent_lead(tracks: dict[int, Track], standstill: bool, model_data: capnp._DynamicStructReader, left: bool = True) -> dict[str, Any]:
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lead_dict = {'status': False}
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adjacent_tracks = [c for c in tracks.values() if c.potential_adjacent_lead(left, model_data)]
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adjacent_tracks = [c for c in tracks.values() if c.potential_adjacent_lead(left, standstill, model_data)]
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if len(adjacent_tracks) > 0:
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closest_track = min(adjacent_tracks, key=lambda c: c.dRel)
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lead_dict = closest_track.get_RadarState()
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@@ -277,7 +252,7 @@ class RadarD:
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self.kalman_params = KalmanParams(DT_MDL)
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self.v_ego = 0.0
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self.v_ego_hist = deque([0.0], maxlen=int(round(delay / DT_MDL))+1)
|
||||
self.v_ego_hist = deque([0.0], maxlen=int(round(delay / DT_MDL)) + 1)
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||||
self.last_v_ego_frame = -1
|
||||
|
||||
self.radar_state: capnp._DynamicStructBuilder | None = None
|
||||
@@ -287,12 +262,11 @@ class RadarD:
|
||||
|
||||
# FrogPilot variables
|
||||
self.frogpilot_radar_state = custom.FrogPilotRadarState.new_message()
|
||||
|
||||
self.frogpilot_toggles = get_frogpilot_toggles()
|
||||
|
||||
def update(self, sm: messaging.SubMaster, rr: car.RadarData):
|
||||
self.ready = sm.seen['modelV2']
|
||||
self.current_time = 1e-9*max(sm.logMonoTime.values())
|
||||
self.current_time = 1e-9 * max(sm.logMonoTime.values())
|
||||
|
||||
if sm.recv_frame['carState'] != self.last_v_ego_frame:
|
||||
self.v_ego = sm['carState'].vEgo
|
||||
@@ -307,9 +281,7 @@ class RadarD:
|
||||
self.tracks.pop(ids, None)
|
||||
|
||||
# *** compute the tracks ***
|
||||
for ids in ar_pts:
|
||||
rpt = ar_pts[ids]
|
||||
|
||||
for ids, rpt in ar_pts.items():
|
||||
# align v_ego by a fixed time to align it with the radar measurement
|
||||
v_lead = rpt[2] + self.v_ego_hist[0]
|
||||
|
||||
@@ -325,19 +297,24 @@ class RadarD:
|
||||
self.radar_state.radarErrors = rr.errors
|
||||
self.radar_state.carStateMonoTime = sm.logMonoTime['carState']
|
||||
|
||||
self.frogpilot_radar_state = custom.FrogPilotRadarState.new_message()
|
||||
|
||||
if len(sm['modelV2'].velocity.x):
|
||||
model_v_ego = sm['modelV2'].velocity.x[0]
|
||||
else:
|
||||
model_v_ego = self.v_ego
|
||||
|
||||
leads_v3 = sm['modelV2'].leadsV3
|
||||
if len(leads_v3) > 1:
|
||||
self.radar_state.leadOne = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[0], model_v_ego, sm['modelV2'], sm['frogpilotPlan'], self.frogpilot_toggles, low_speed_override=True)
|
||||
self.radar_state.leadTwo = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[1], model_v_ego, sm['modelV2'], sm['frogpilotPlan'], self.frogpilot_toggles, low_speed_override=False)
|
||||
self.radar_state.leadOne = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[0], model_v_ego, sm['modelV2'],
|
||||
sm['carState'].standstill, sm['frogpilotPlan'], self.frogpilot_toggles, low_speed_override=True)
|
||||
self.radar_state.leadTwo = get_lead(self.v_ego, self.ready, self.tracks, leads_v3[1], model_v_ego, sm['modelV2'],
|
||||
sm['carState'].standstill, sm['frogpilotPlan'], self.frogpilot_toggles, low_speed_override=False)
|
||||
|
||||
# FrogPilot variables
|
||||
if self.ready and (self.frogpilot_toggles.adjacent_lead_tracking or self.frogpilot_toggles.human_lane_changes):
|
||||
self.frogpilot_radar_state.leadLeft = get_adjacent_lead(self.tracks, sm['modelV2'], left=True)
|
||||
self.frogpilot_radar_state.leadRight = get_adjacent_lead(self.tracks, sm['modelV2'], left=False)
|
||||
self.frogpilot_radar_state.leadLeft = get_adjacent_lead(self.tracks, sm['carState'].standstill, sm['modelV2'], left=True)
|
||||
self.frogpilot_radar_state.leadRight = get_adjacent_lead(self.tracks, sm['carState'].standstill, sm['modelV2'], left=False)
|
||||
|
||||
self.frogpilot_toggles = get_frogpilot_toggles(sm)
|
||||
|
||||
|
||||
Reference in New Issue
Block a user