2022-06-17 00:28:26 -03:00
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/*
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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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* ArduPilot device driver for Inno-Maker LD06 LiDAR
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*
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* ALL INFORMATION REGARDING PROTOCOL WAS DERIVED FROM InnoMaker DATASHEET:
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*
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* http://wiki.inno-maker.com/display/HOMEPAGE/LD06?preview=/6949506/6949511/LDROBOT_LD06_Development%20manual_v1.0_en.pdf
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*
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* Author: Adithya Patil, Georgia Institute of Technology
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* Based on the SLAMTEC RPLiDAR code written by Steven Josefs, IAV GmbH and CYGBOT D1 LiDAR code
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*
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*/
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2023-08-13 23:57:48 -03:00
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#include "AP_Proximity_config.h"
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#if AP_PROXIMITY_LD06_ENABLED
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#include "AP_Proximity_LD06.h"
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#define LD_START_CHAR 0x54
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#define PROXIMITY_LD06_TIMEOUT_MS 50
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// Indices in data array where each value starts being recorded
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// See comment below about data payload for more info about formatting
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#define START_BEGIN_CHARACTER 0
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#define START_DATA_LENGTH 1
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#define START_RADAR_SPEED 2
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#define START_BEGIN_ANGLE 4
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#define START_PAYLOAD 6
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#define START_END_ANGLE 42
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#define START_CHECK_SUM 46
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#define MEASUREMENT_PAYLOAD_LENGTH 3
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#define PAYLOAD_COUNT 12
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/* ------------------------------------------
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Data Packet Structure:
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Start Character : 1 Byte
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Data Length : 1 Byte
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Radar Speed : 2 Bytes
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Start Angle : 2 Bytes
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Data Measurements : 36 Bytes
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Contains 12 measurements of 3 Bytes each
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Each measurement has 2 Bytes for distance to closest object
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Each measurement has the 3rd Byte as measurement Confidence
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End Angle : 2 Bytes
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Timestamp : 2 Bytes
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Checksum : 1 Byte
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------------------------------------------ */
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// ----> 47 data bytes in total for one packet
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// Update the sensor readings
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void AP_Proximity_LD06::update(void)
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{
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// Escape if no connection detected/supported while running
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if (_uart == nullptr) {
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return;
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}
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// Begin getting sensor readings
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// Calls method that repeatedly reads through UART channel
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get_readings();
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// Check if the data is being received correctly and sets Proximity Status
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if (_last_distance_received_ms == 0 || (AP_HAL::millis() - _last_distance_received_ms > PROXIMITY_LD06_TIMEOUT_MS)) {
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set_status(AP_Proximity::Status::NoData);
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} else {
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set_status(AP_Proximity::Status::Good);
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}
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}
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// Called repeatedly to get the readings at the current instant
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void AP_Proximity_LD06::get_readings()
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{
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if (_uart == nullptr) {
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return;
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}
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// Store the number of bytes available on the UART input
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uint32_t nbytes = MIN((uint16_t) 4000, _uart->available());
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// Loops through all bytes that were received
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while (nbytes-- > 0) {
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// Gets and logs the current byte being read
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const uint8_t c = _uart->read();
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// Stores the byte in an array if the byte is a start byte or we have already read a start byte
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if (c == LD_START_CHAR || _response_data) {
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// Sets to true if a start byte has been read, default false otherwise
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_response_data = true;
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// Stores the next byte in an array
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_response[_byte_count] = c;
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_byte_count++;
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if (_byte_count == _response[START_DATA_LENGTH] + 3) {
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const uint32_t current_ms = AP_HAL::millis();
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// Stores the last distance taken, used to reduce number of readings taken
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if (_last_distance_received_ms != current_ms) {
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_last_distance_received_ms = current_ms;
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}
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// Updates the temporary boundary and passes off the completed data
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parse_response_data();
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_temp_boundary.update_3D_boundary(state.instance, frontend.boundary);
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_temp_boundary.reset();
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// Resets the bytes read and whether or not we are reading data to accept a new payload
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_byte_count = 0;
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_response_data = false;
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}
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}
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}
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}
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// Parses the data packet received from the LiDAR
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void AP_Proximity_LD06::parse_response_data()
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{
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// Data interpretation based on:
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// http://wiki.inno-maker.com/display/HOMEPAGE/LD06?preview=/6949506/6949511/LDROBOT_LD06_Development%20manual_v1.0_en.pdf
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// Second byte in array stores length of data - not used but stored for debugging
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// const uint8_t data_length = _response[START_DATA_LENGTH];
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// Respective bits store the radar speed, start/end angles
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// Use bitwise operations to correctly obtain correct angles
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// Divide angles by 100 as per manual
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const float start_angle = float(UINT16_VALUE(_response[START_BEGIN_ANGLE + 1], _response[START_BEGIN_ANGLE])) * 0.01;
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const float end_angle = float(UINT16_VALUE(_response[START_END_ANGLE + 1], _response[START_END_ANGLE])) * 0.01;
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// Verify the checksum that is stored in the last element of the response array
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// Return if checksum is incorrect - i.e. bad data, bad readings, etc.
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const uint8_t check_sum = _response[START_CHECK_SUM];
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if (check_sum != crc8_generic(&_response[0], sizeof(_response) / sizeof(_response[0]) - 1, 0x4D)) {
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return;
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}
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// Calculates the angle that this point was sampled at
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float sampled_counts = 0;
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const float angle_step = (end_angle - start_angle) / (PAYLOAD_COUNT - 1);
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float uncorrected_angle = start_angle + (end_angle - start_angle) * 0.5;
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// Handles the case that the angles read went from 360 to 0 (jumped)
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if (angle_step < 0) {
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uncorrected_angle = wrap_360(start_angle + (end_angle + 360 - start_angle) * 0.5);
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}
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// Takes the angle in the middle of the readings to be pushed to the database
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const float push_angle = correct_angle_for_orientation(uncorrected_angle);
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float distance_avg = 0.0;
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// Each recording point is three bytes long, goes through all of that and updates database
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for (uint16_t i = START_PAYLOAD; i < START_PAYLOAD + MEASUREMENT_PAYLOAD_LENGTH * PAYLOAD_COUNT; i += MEASUREMENT_PAYLOAD_LENGTH) {
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// Gets the distance recorded and converts to meters
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const float distance_meas = UINT16_VALUE(_response[i + 1], _response[i]) * 0.001;
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// Validates data and checks if it should be included
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if (distance_meas > distance_min() && distance_meas < distance_max()) {
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if (ignore_reading(push_angle, distance_meas)) {
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continue;
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}
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sampled_counts ++;
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distance_avg += distance_meas;
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}
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}
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// Convert angle to appropriate face and adds to database
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// Since angle increments are only about 3 degrees, ignore readings if there were only 1 or 2 measurements
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// (likely outliers) recorded in the range
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if (sampled_counts > 2) {
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// Gets the average distance read
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distance_avg /= sampled_counts;
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// Pushes the average distance and angle to the obstacle avoidance database
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const AP_Proximity_Boundary_3D::Face face = frontend.boundary.get_face(push_angle);
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_temp_boundary.add_distance(face, push_angle, distance_avg);
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database_push(push_angle, distance_avg);
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}
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}
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#endif // AP_PROXIMITY_LD06_ENABLED
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