mirror of https://github.com/ArduPilot/ardupilot
537 lines
20 KiB
C++
537 lines
20 KiB
C++
/*
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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/*
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helicopter simulator class
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*/
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#include "SIM_Helicopter.h"
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#include <stdio.h>
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#include <GCS_MAVLink/GCS.h>
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namespace SITL {
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Helicopter::Helicopter(const char *frame_str) :
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Aircraft(frame_str)
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{
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mass = 4.54f;
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if (strstr(frame_str, "-dual")) {
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frame_type = HELI_FRAME_DUAL;
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_time_delay = 30;
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nominal_rpm = 1300;
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mass = 9.08f;
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iyy = 0.2f;
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} else if (strstr(frame_str, "-compound")) {
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frame_type = HELI_FRAME_COMPOUND;
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_time_delay = 50;
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nominal_rpm = 1500;
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} else if (strstr(frame_str, "-blade360")) {
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frame_type = HELI_FRAME_BLADE360;
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_time_delay = 40;
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nominal_rpm = 2100;
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} else {
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frame_type = HELI_FRAME_CONVENTIONAL;
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_time_delay = 50;
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nominal_rpm = 1500;
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}
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/*
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For conventional and compound
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scaling from motor power to Newtons. Allows the copter
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to hover against gravity when the motor is at hover_throttle
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normalized to hover at 1500RPM at 5 deg collective.
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*/
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thrust_scale = (mass * GRAVITY_MSS) / (hover_coll * sq(nominal_rpm * 2.0f * M_PI / 60.0f));
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// torque with zero collective pitch. Percentage of total +hover torque is based on full scale helicopters.
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torque_mpog = 1.08f / sq(nominal_rpm * 2.0f * M_PI / 60.0f); // based on separate calculation
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// torque_max based on power being weight^3/2. Assuming thrust is linear with collective, it can be
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// determined that max torque would be 3 times hover torque. Then dividing by 1-MPOG_torq to get total torque.
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torque_max = ((mass * GRAVITY_MSS * sinf(radians(hover_lean)) * tr_dist - torque_mpog * sq(nominal_rpm * 2.0f * M_PI / 60.0f)) * powf(2.0f,1.5f) + torque_mpog * sq(nominal_rpm * 2.0f * M_PI / 60.0f)) / sq(nominal_rpm * 2.0f * M_PI / 60.0f);
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// calculates tail rotor thrust to overcome rotor torque using the lean angle in a hover
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torque_scale = (torque_max - torque_mpog) / powf(10.0f,1.5f);
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frame_height = 0.1;
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gas_heli = (strstr(frame_str, "-gas") != nullptr);
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ground_behavior = GROUND_BEHAVIOR_NO_MOVEMENT;
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lock_step_scheduled = true;
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motor_mask |= (1U<<0);
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}
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/*
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update the helicopter simulation by one time step
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*/
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void Helicopter::update(const struct sitl_input &input)
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{
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const float dt = frame_time_us * 1.0e-6f;
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// get wind vector setup
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update_wind(input);
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motor_interlock = input.servos[7] > 1400;
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float rsc = constrain_float((input.servos[7]-1000) / 1000.0f, 0, 1);
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float thrust = 0;
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float thrust_1 = 0;
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float thrust_2 = 0;
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float eng_torque = 0;
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float lateral_x_thrust = 0;
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float lateral_y_thrust = 0;
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if (_time_delay == 0) {
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for (uint8_t i = 0; i < 6; i++) {
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_servos_delayed[i] = input.servos[i];
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}
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} else if (servos_stored_buffer == nullptr) {
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uint16_t buffer_size = constrain_int16(_time_delay, 1, 100) * 0.001f / dt;
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servos_stored_buffer = new ObjectBuffer<servos_stored>(buffer_size);
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while (servos_stored_buffer->space() != 0) {
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push_to_buffer(input.servos);
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}
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for (uint8_t i = 0; i < 6; i++) {
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_servos_delayed[i] = input.servos[i];
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}
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} else {
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pull_from_buffer(_servos_delayed);
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push_to_buffer(input.servos);
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}
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float swash1 = (_servos_delayed[0]-1000) / 1000.0f;
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float swash2 = (_servos_delayed[1]-1000) / 1000.0f;
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float swash3 = (_servos_delayed[2]-1000) / 1000.0f;
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Vector3f rot_accel;
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switch (frame_type) {
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case HELI_FRAME_CONVENTIONAL: {
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// simulate a traditional helicopter
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float Ma1s = 617.5f;
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float Lb1s = 3588.6f;
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float Mu = 0.003f;
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float Lv = -0.006;
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float Xu = -0.125;
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float Yv = -0.375;
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float Zw = -2.25;
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float tail_rotor = (_servos_delayed[3]-1000) / 1000.0f;
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// thrust calculated based on 5 deg hover collective for 10lb aircraft at 1500RPM
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float coll = 50.0f * (swash1+swash2+swash3) / 3.0f - 25.0f;
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thrust = (rpm[0] / nominal_rpm) * thrust_scale * sq(nominal_rpm * 0.104667f) * coll;
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// determine RPM
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rpm[0] = update_rpm(rpm[0], rsc, eng_torque, coll, dt);
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// Calculate rotor tip path plane angle
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float roll_cyclic = 1.283 * (swash1 - swash2) / cyclic_scalar;
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float pitch_cyclic = 1.48 * ((swash1+swash2) / 2.0f - swash3) / cyclic_scalar;
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Vector2f ctrl_pos = Vector2f(roll_cyclic, pitch_cyclic);
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update_rotor_dynamics(gyro, ctrl_pos, _tpp_angle, dt);
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float yaw_cmd = 2.0f * tail_rotor - 1.0f; // convert range to -1 to 1
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float tail_rotor_torque = (21.6f * 2.96f * yaw_cmd - 2.96f * gyro.z) * sq(rpm[0]/nominal_rpm);
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float tail_rotor_thrust = -1.0f * tail_rotor_torque * izz / tr_dist; //right pedal produces left body accel
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// rotational acceleration, in rad/s/s, in body frame
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rot_accel.x = _tpp_angle.x * Lb1s + Lv * velocity_air_bf.y;
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rot_accel.y = _tpp_angle.y * Ma1s + Mu * velocity_air_bf.x;
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rot_accel.z = tail_rotor_torque - eng_torque;
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lateral_y_thrust = tail_rotor_thrust / mass + GRAVITY_MSS * _tpp_angle.x + Yv * velocity_air_bf.y;
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lateral_x_thrust = -1.0f * GRAVITY_MSS * _tpp_angle.y + Xu * velocity_air_bf.x;
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accel_body = Vector3f(lateral_x_thrust, lateral_y_thrust, -thrust / mass + velocity_air_bf.z * Zw);
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break;
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}
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case HELI_FRAME_BLADE360: {
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// simulate a Blade 360 helicopter. This model was taken from the following reference.
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// Walker, J, Tishler, M, "Identification and Control Design of a Sub-Scale Flybarless Helicopter",
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// Vertical Flight Society’s 77th Annual Forum & Technology Display, Virtual, May 10-14, 2021.
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float Ma1s = 796.7f;
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float Lb1s = 5115.2f;
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float Mu = 2.7501f;
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float Mv = -2.3039f;
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float Lu = -28.7796f;
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float Lv = -5.5376f;
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float Xu = -0.2270f;
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float Yv = -0.1852f;
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float Yp = 0.2303f;
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float Zw = -0.5910f;
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float Nr = -2.0131f;
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float Nw = 5.7574f;
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float Nv = 1.7258f;
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float Ncol = -32.4616f;
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float Nped = 63.0040f;
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float Zcol = -22.3239f;
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float tail_rotor = (_servos_delayed[3]-1000) / 1000.0f;
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// collective adjusted for coll_min(1460) to coll_max(1740) as 0 to 1 with 1500 being zero thrust
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float coll = 3.51 * ((swash1+swash2+swash3) / 3.0f - 0.5f);
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// determine RPM
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rpm[0] = update_rpm(rpm[0], rsc, eng_torque, coll, dt);
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// Calculate rotor tip path plane angle
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float roll_cyclic = 1.283f * (swash1 - swash2);
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float pitch_cyclic = 1.48f * ((swash1+swash2) / 2.0f - swash3);
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Vector2f ctrl_pos = Vector2f(roll_cyclic, pitch_cyclic);
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update_rotor_dynamics(gyro, ctrl_pos, _tpp_angle, dt);
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float yaw_cmd = 1.45f * (2.0f * tail_rotor - 1.0f); // convert range to -1 to 1
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// rotational acceleration, in rad/s/s, in body frame
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rot_accel.x = _tpp_angle.x * Lb1s + Lu * velocity_air_bf.x + Lv * velocity_air_bf.y;
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rot_accel.y = _tpp_angle.y * Ma1s + Mu * velocity_air_bf.x + Mv * velocity_air_bf.y;
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rot_accel.z = Nv * velocity_air_bf.y + Nr * gyro.z + sq(rpm[0]/nominal_rpm) * Nped * yaw_cmd + Nw * velocity_air_bf.z + sq(rpm[0]/nominal_rpm) * Ncol * (coll - 0.5f);
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lateral_y_thrust = GRAVITY_MSS * _tpp_angle.x + Yv * velocity_air_bf.y + Yp * gyro.x - 3.2 * 0.01745 * GRAVITY_MSS;
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lateral_x_thrust = -1.0f * GRAVITY_MSS * _tpp_angle.y + Xu * velocity_air_bf.x;
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float vertical_thrust = Zcol * coll * sq(rpm[0]/nominal_rpm) + velocity_air_bf.z * Zw;
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accel_body = Vector3f(lateral_x_thrust, lateral_y_thrust, vertical_thrust);
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break;
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}
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case HELI_FRAME_DUAL: {
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float Ma1s = 617.5f;
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float Lb1s = 3588.6f;
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float Mu = 0.003f;
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float Lv = -0.006f;
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float Xu = -0.125f;
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float Yv = -0.375f;
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float Zw = -2.25f;
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float hub_dist = 1.8f; //meters
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float swash4 = (_servos_delayed[3]-1000) / 1000.0f;
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float swash5 = (_servos_delayed[4]-1000) / 1000.0f;
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float swash6 = (_servos_delayed[5]-1000) / 1000.0f;
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// Forward rotor is number 1
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// thrust calculated based on 5 deg hover collective for 10lb aircraft at 1500RPM
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float coll_1 = 50.0f * (swash1+swash2+swash3) / 3.0f - 25.0f;
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// Calculate rotor tip path plane angle
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float roll_cyclic_1 = 1.283 * (swash1 - swash2) / cyclic_scalar;
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float pitch_cyclic_1 = 1.48 * ((swash1+swash2) / 2.0f - swash3) / cyclic_scalar;
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Vector2f ctrl_pos_1 = Vector2f(roll_cyclic_1, pitch_cyclic_1);
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update_rotor_dynamics(gyro, ctrl_pos_1, _tpp_angle_1, dt);
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// Aft rotor is number 2
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// thrust calculated based on 5 deg hover collective for 10lb aircraft at 1500RPM
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float coll_2 = 50.0f * (swash4+swash5+swash6) / 3.0f - 25.0f;
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// Calculate rotor tip path plane angle
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float roll_cyclic_2 = 1.283 * (swash4 - swash5) / cyclic_scalar;
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float pitch_cyclic_2 = 1.48 * ((swash4+swash5) / 2.0f - swash6) / cyclic_scalar;
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Vector2f ctrl_pos_2 = Vector2f(roll_cyclic_2, pitch_cyclic_2);
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update_rotor_dynamics(gyro, ctrl_pos_2, _tpp_angle_2, dt);
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// determine RPM
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rpm[0] = update_rpm(rpm[0], rsc, eng_torque, (coll_1 + coll_2) * 0.5f, dt);
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thrust_1 = 0.5f * thrust_scale * sq(rpm[0] * 0.104667f) * coll_1;
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thrust_2 = 0.5f * thrust_scale * sq(rpm[0] * 0.104667f) * coll_2;
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// rotational acceleration, in rad/s/s, in body frame
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rot_accel.x = (_tpp_angle_1.x + _tpp_angle_2.x) * Lb1s + Lv * velocity_air_bf.y;
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rot_accel.y = (_tpp_angle_1.y + _tpp_angle_2.y) * Ma1s + (thrust_1 - thrust_2) * hub_dist / iyy + Mu * velocity_air_bf.x + hub_dist * gyro.y * Zw;
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rot_accel.z = (_tpp_angle_1.x * thrust_1 - _tpp_angle_2.x * thrust_2) * hub_dist / (iyy * 2.0f) - 0.5f * gyro.z;
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lateral_y_thrust = GRAVITY_MSS * (_tpp_angle_1.x + _tpp_angle_2.x) + Yv * velocity_air_bf.y;
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lateral_x_thrust = -1.0f * GRAVITY_MSS * (_tpp_angle_1.y + _tpp_angle_2.y) + Xu * velocity_air_bf.x;
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accel_body = Vector3f(lateral_x_thrust, lateral_y_thrust, -(thrust_1 + thrust_2) / mass + velocity_air_bf.z * Zw);
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break;
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}
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case HELI_FRAME_COMPOUND: {
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// simulate a compound helicopter
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float Ma1s = 617.5f;
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float Lb1s = 3588.6f;
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float Mu = 0.003f;
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float Lv = -0.006;
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float Xu = -0.125;
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float Yv = -0.375;
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float Zw = -2.25;
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// thrust calculated based on 5 deg hover collective for 10lb aircraft at 1500RPM
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float coll = 50.0f * (swash1+swash2+swash3) / 3.0f - 25.0f;
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thrust = thrust_scale * sq(rpm[0] * 0.104667f) * coll;
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// determine RPM
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rpm[0] = update_rpm(rpm[0], rsc, eng_torque, coll, dt);
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// Calculate rotor tip path plane angle
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float roll_cyclic = 1.283 * (swash1 - swash2) / cyclic_scalar;
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float pitch_cyclic = 1.48 * ((swash1+swash2) / 2.0f - swash3) / cyclic_scalar;
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Vector2f ctrl_pos = Vector2f(roll_cyclic, pitch_cyclic);
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update_rotor_dynamics(gyro, ctrl_pos, _tpp_angle, dt);
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// Calculate thruster yaw and forward thrust effects
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// Thruster command range -1 to 1. Positive is forward thrust for both
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float right_thruster_cmd = 2.0f * (_servos_delayed[3]-1000) / 1000.0f - 1.0f;
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float left_thruster_cmd = 2.0f * (_servos_delayed[4]-1000) / 1000.0f - 1.0f;
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// assume torque from each thruster only half of normal tailrotor since thrusters 1/2 distance from cg
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float right_thruster_torque = (-0.5f * 21.6f * 2.96f * right_thruster_cmd - 2.96f * gyro.z) * sq(rpm[0] / nominal_rpm);
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float left_thruster_torque = (0.5f * 21.6f * 2.96f * left_thruster_cmd - 2.96f * gyro.z) * sq(rpm[0] / nominal_rpm);
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float right_thruster_force = -1.0f * right_thruster_torque * izz / (0.5f * tr_dist);
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float left_thruster_force = left_thruster_torque * izz / (0.5f * tr_dist);
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// rotational acceleration, in rad/s/s, in body frame
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rot_accel.x = _tpp_angle.x * Lb1s + Lv * velocity_air_bf.y;
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rot_accel.y = _tpp_angle.y * Ma1s + Mu * velocity_air_bf.x;
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rot_accel.z = right_thruster_torque + left_thruster_torque - eng_torque;
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lateral_y_thrust = GRAVITY_MSS * _tpp_angle.x + Yv * velocity_air_bf.y;
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lateral_x_thrust = (right_thruster_force + left_thruster_force) / mass - GRAVITY_MSS * _tpp_angle.y + Xu * velocity_air_bf.x;
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accel_body = Vector3f(lateral_x_thrust, lateral_y_thrust, -thrust / mass + velocity_air_bf.z * Zw);
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break;
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}
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}
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update_dynamics(rot_accel);
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update_external_payload(input);
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// update lat/lon/altitude
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update_position();
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time_advance();
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// update magnetic field
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update_mag_field_bf();
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}
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void Helicopter::update_rotor_dynamics(Vector3f gyros, Vector2f ctrl_pos, Vector2f &tpp_angle, float dt)
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{
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float tf_inv;
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float Lfa1s;
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float Mfb1s;
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float Lflt;
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float Lflg;
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float Mflt;
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float Mflg;
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if (frame_type == HELI_FRAME_BLADE360) {
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tf_inv = 1.0f / 0.0353f;
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Lfa1s = 1.0477f;
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Mfb1s = -1.0057f;
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Lflt = 0.2375f;
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Lflg = -0.0286f;
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Mflt = 0.0344f;
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Mflg = 0.2292f;
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} else if (frame_type == HELI_FRAME_DUAL) { // remove coupling in rotor
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tf_inv = 1.0f / 0.068232f;
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Lfa1s = 0.0f;
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Mfb1s = 0.0f;
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Lflt = 1.7635f;
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Lflg = 0.0f;
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Mflt = 0.0f;
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Mflg = 1.9432f;
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} else {
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tf_inv = 1.0f / 0.068232f;
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Lfa1s = 1.2963f;
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Mfb1s = -1.3402f;
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Lflt = 1.7635f;
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Lflg = -0.61171f;
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Mflt = 0.52454f;
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Mflg = 1.9432f;
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}
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float b1s_dot = -1 * gyro.x - tf_inv * tpp_angle.x + tf_inv * (Lfa1s * tpp_angle.y + Lflt * ctrl_pos.x + Lflg * ctrl_pos.y);
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float a1s_dot = -1 * gyro.y - tf_inv * tpp_angle.y + tf_inv * (Mfb1s * tpp_angle.x + Mflt * ctrl_pos.x + Mflg * ctrl_pos.y);
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tpp_angle.x += b1s_dot * dt;
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tpp_angle.y += a1s_dot * dt;
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}
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float Helicopter::update_rpm(float curr_rpm, float throttle, float &engine_torque, float collective, float dt)
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{
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static float rotor_runup_output;
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static uint8_t motor_status;
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float accel_scale;
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float input_torque;
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float auto_ss_torque;
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float descent_torque;
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float rotor_torque;
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float rpm_dot;
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float rpm_engine;
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//use this to make rpm model more realistic
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accel_scale = 100.0f;
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input_torque = 0.0f;
|
||
|
||
// calculate aerodynamic rotor drag torque
|
||
rotor_torque = (sq(curr_rpm * 0.104667f) * (torque_mpog + torque_scale * powf(fabsf(collective),1.5f))) / izz;
|
||
|
||
// Calculate autorotation effect on rotor
|
||
auto_ss_torque = sq(nominal_rpm * 0.104667f) * (torque_mpog + torque_scale * powf(fabsf(-1.0f),1.5f)) / izz;
|
||
if (is_positive(velocity_air_bf.z)) {
|
||
descent_torque = (velocity_air_bf.z - 5.3) * auto_ss_torque / 5.3f + auto_ss_torque;
|
||
} else {
|
||
descent_torque = 0.0f;
|
||
}
|
||
|
||
// calculate max engine torque
|
||
float engine_torque_max = sq(nominal_rpm * 0.104667f) * torque_max / izz;
|
||
|
||
if (gas_heli) {
|
||
|
||
// calculate engine RPM. Based off of throttle and it matches rotor RPM at 30% throttle
|
||
rpm_engine = nominal_rpm * throttle / 0.3f;
|
||
|
||
// calculate engine torque. extra 20% given to have a little extra power
|
||
engine_torque = 1.20f * throttle * engine_torque_max;
|
||
|
||
// model clutch on gas heli
|
||
if (throttle >= 0.15f && rpm_engine > curr_rpm) {
|
||
input_torque = engine_torque;
|
||
} else {
|
||
input_torque = 0.0f;
|
||
}
|
||
|
||
rpm_dot = 0.0f;
|
||
// help spool down quickly go to zero
|
||
if (throttle <= 0.15f && curr_rpm < 300) {
|
||
rpm_dot = - 40.0f;
|
||
if (curr_rpm <= 0.0f) {
|
||
rpm_dot = 0.0f;
|
||
curr_rpm = 0.0f;
|
||
}
|
||
} else {
|
||
rpm_dot = accel_scale * (input_torque + descent_torque - rotor_torque);
|
||
if (curr_rpm <= 0.0 && !is_positive(rpm_dot)) {
|
||
rpm_dot = 0.0f;
|
||
curr_rpm = 0.0f;
|
||
}
|
||
}
|
||
} else {
|
||
if (throttle > 0.25) {
|
||
motor_status = 3; // throttle unlimited
|
||
} else if (motor_status == 3 && throttle <= 0.25 && throttle > 0.15) {
|
||
motor_status = 2; // autorotational window
|
||
} else if (throttle <= 0.15) {
|
||
motor_status = 1; // idle
|
||
}
|
||
|
||
float runup_time = 8.0f;
|
||
if (motor_status == 2) {
|
||
runup_time = 2.0f;
|
||
}
|
||
|
||
// ramp speed estimate towards control out
|
||
float runup_increment = dt / runup_time;
|
||
if (motor_status > 2) {
|
||
if (rotor_runup_output < 1.0f) {
|
||
rotor_runup_output += runup_increment;
|
||
} else {
|
||
rotor_runup_output = 1.0f;
|
||
}
|
||
if (curr_rpm < nominal_rpm - 25.0f) {
|
||
accel_scale = 2000.0f / runup_time;
|
||
}
|
||
}else{
|
||
if (rotor_runup_output > 0.0f) {
|
||
rotor_runup_output -= runup_increment * 10.0f; // make ramp down 10 times faster
|
||
} else {
|
||
rotor_runup_output = 0.0f;
|
||
}
|
||
}
|
||
|
||
// calculate engine torque just for start up and shutdown of rotor
|
||
engine_torque = 0.333f * rotor_runup_output * engine_torque_max;
|
||
|
||
// manage input torque so descent torque combined with engine torque doesn't allow rotor to overspeed
|
||
if (rotor_runup_output >= 1.0f && curr_rpm > nominal_rpm - 100.0f) {
|
||
// want the rpm to seek the nominal rpm so set the input torque to only be that for nominal RPM
|
||
input_torque = rotor_torque * sq(nominal_rpm / curr_rpm);
|
||
} else if (rotor_runup_output <= 0.0f) {
|
||
input_torque = descent_torque;
|
||
} else {
|
||
input_torque = engine_torque + descent_torque;
|
||
}
|
||
|
||
rpm_dot = 0.0f;
|
||
// Help spool down quickly got to zero
|
||
if (rotor_runup_output <= 0.0f && curr_rpm < 300) {
|
||
rpm_dot = - 40.0f;
|
||
if (curr_rpm <= 0.0f) {
|
||
rpm_dot = 0.0f;
|
||
curr_rpm = 0.0f;
|
||
}
|
||
} else {
|
||
rpm_dot = accel_scale * (input_torque - rotor_torque);
|
||
}
|
||
engine_torque = input_torque;
|
||
}
|
||
|
||
curr_rpm += rpm_dot * dt;
|
||
|
||
return curr_rpm;
|
||
|
||
}
|
||
|
||
// push servo input to buffer
|
||
void Helicopter::push_to_buffer(const uint16_t servos_input[16])
|
||
{
|
||
servos_stored sample;
|
||
sample.servo1 = servos_input[0];
|
||
sample.servo2 = servos_input[1];
|
||
sample.servo3 = servos_input[2];
|
||
sample.servo4 = servos_input[3];
|
||
sample.servo5 = servos_input[4];
|
||
sample.servo6 = servos_input[5];
|
||
servos_stored_buffer->push(sample);
|
||
|
||
}
|
||
|
||
// pull servo delay from buffer
|
||
void Helicopter::pull_from_buffer(uint16_t servos_delayed[6])
|
||
{
|
||
servos_stored sample;
|
||
if (!servos_stored_buffer->pop(sample)) {
|
||
// no sample
|
||
return;
|
||
}
|
||
servos_delayed[0] = sample.servo1;
|
||
servos_delayed[1] = sample.servo2;
|
||
servos_delayed[2] = sample.servo3;
|
||
servos_delayed[3] = sample.servo4;
|
||
servos_delayed[4] = sample.servo5;
|
||
servos_delayed[5] = sample.servo6;
|
||
|
||
}
|
||
|
||
} // namespace SITL
|