/* * ADC.cpp - Analog Digital Converter Base Class for Ardupilot Mega * Code by James Goppert. DIYDrones.com * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. */ #include "AP_OpticalFlow.h" #define FORTYFIVE_DEGREES 0.78539816 AP_OpticalFlow* AP_OpticalFlow::_sensor = NULL; // pointer to the last instantiated optical flow sensor. Will be turned into a table if we ever add support for more than one sensor uint8_t AP_OpticalFlow::_num_calls; // number of times we have been called by 1khz timer process. We use this to throttle read down to 20hz // init - initCommAPI parameter controls whether I2C/SPI interface is initialised (set to false if other devices are on the I2C/SPI bus and have already initialised the interface) bool AP_OpticalFlow::init(bool initCommAPI, AP_PeriodicProcess *scheduler, AP_Semaphore* spi_semaphore, AP_Semaphore* spi3_semaphore) { _orientation = ROTATION_NONE; update_conversion_factors(); return true; // just return true by default } // set_orientation - Rotation vector to transform sensor readings to the body frame. void AP_OpticalFlow::set_orientation(enum Rotation rotation) { _orientation = rotation; } // parent method called at 1khz by periodic process // this is slowed down to 20hz and each instance's update function is called (only one instance is supported at the moment) void AP_OpticalFlow::read(uint32_t now) { _num_calls++; if( _num_calls >= AP_OPTICALFLOW_NUM_CALLS_FOR_20HZ ) { _num_calls = 0; // call to update all attached sensors if( _sensor != NULL ) { _sensor->update(now); } } }; // read value from the sensor. Should be overridden by derived class void AP_OpticalFlow::update(uint32_t now) { } // reads a value from the sensor (will be sensor specific) byte AP_OpticalFlow::read_register(byte address) { return 0; } // writes a value to one of the sensor's register (will be sensor specific) void AP_OpticalFlow::write_register(byte address, byte value) { } // rotate raw values to arrive at final x,y,dx and dy values void AP_OpticalFlow::apply_orientation_matrix() { Vector3f rot_vector; rot_vector(raw_dx, raw_dy, 0); // next rotate dx and dy rot_vector.rotate(_orientation); dx = rot_vector.x; dy = rot_vector.y; // add rotated values to totals (perhaps this is pointless as we need to take into account yaw, roll, pitch) x += dx; y += dy; } // updatse conversion factors that are dependent upon field_of_view void AP_OpticalFlow::update_conversion_factors() { conv_factor = (1.0 / (float)(num_pixels * scaler)) * 2.0 * tan(field_of_view / 2.0); // multiply this number by altitude and pixel change to get horizontal move (in same units as altitude) // 0.00615 radians_to_pixels = (num_pixels * scaler) / field_of_view; // 162.99 } // updates internal lon and lat with estimation based on optical flow void AP_OpticalFlow::update_position(float roll, float pitch, float cos_yaw_x, float sin_yaw_y, float altitude) { float diff_roll = roll - _last_roll; float diff_pitch = pitch - _last_pitch; // only update position if surface quality is good and angle is not over 45 degrees if( surface_quality >= 10 && fabs(roll) <= FORTYFIVE_DEGREES && fabs(pitch) <= FORTYFIVE_DEGREES ) { altitude = max(altitude, 0); // calculate expected x,y diff due to roll and pitch change exp_change_x = diff_roll * radians_to_pixels; exp_change_y = -diff_pitch * radians_to_pixels; // real estimated raw change from mouse change_x = dx - exp_change_x; change_y = dy - exp_change_y; float avg_altitude = (altitude + _last_altitude)*0.5; // convert raw change to horizontal movement in cm x_cm = -change_x * avg_altitude * conv_factor; // perhaps this altitude should actually be the distance to the ground? i.e. if we are very rolled over it should be longer? y_cm = -change_y * avg_altitude * conv_factor; // for example if you are leaned over at 45 deg the ground will appear farther away and motion from opt flow sensor will be less // convert x/y movements into lon/lat movement vlon = x_cm * sin_yaw_y + y_cm * cos_yaw_x; vlat = y_cm * sin_yaw_y - x_cm * cos_yaw_x; } _last_altitude = altitude; _last_roll = roll; _last_pitch = pitch; }