camera pid testing
parent
e0c7c569f6
commit
3c34a71676
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@ -1,7 +1,15 @@
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#include "PID_v2.h"
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#include "systems.h"
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#define CAMERA_CENTER_X 3
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#define CAMERA_CENTER_Y 6
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#define CAMERA_CENTER_Y 3
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#define Kpx 1
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#define Kix 0
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#define Kdx 0
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#define Kpy 1
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#define Kiy 0
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#define Kdy 0
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class PositionSysCamera : public PositionSystem{
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@ -10,5 +18,12 @@ class PositionSysCamera : public PositionSystem{
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void goCenter();
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void update() override;
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void test() override;
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void setCameraPID();
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void CameraPID();
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double Inputx, Outputx, Setpointx, Inputy, Outputy, Setpointy;
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PID* X;
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PID* Y;
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};
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@ -0,0 +1 @@
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Subproject commit 9b4ca0e5b6d7bab9c6ac023e249d6af2446d99bb
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@ -47,7 +47,7 @@ DriveController::DriveController(Motor* m1_, Motor* m2_, Motor* m3_, Motor* m4_)
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vyn = 0;
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}
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void DriveController::prepareDrive(int dir, int speed, int tilt=0){
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void DriveController::prepareDrive(int dir, int speed, int tilt){
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pDir = dir;
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pSpeed = speed;
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pTilt = tilt;
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@ -25,6 +25,7 @@ void loop() {
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// Last thing to do: movement and update status vector
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// drive->prepareDrive(0,0, CURRENT_DATA_READ.angleAtkFix);
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drive->drivePrepared();
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updateStatusVector();
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}
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@ -3,7 +3,9 @@
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#include "vars.h"
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#include "sensors.h"
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PositionSysCamera::PositionSysCamera() {}
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PositionSysCamera::PositionSysCamera() {
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setCameraPID();
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}
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void PositionSysCamera::update(){
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}
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@ -14,26 +16,70 @@ void PositionSysCamera::test(){
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void PositionSysCamera::goCenter(){
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/*WORKS BUT CAN BE BETTER*/
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//Y
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if((CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy) > CAMERA_CENTER_Y) drive->prepareDrive(180, 75, 0);
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/* if((CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy) > CAMERA_CENTER_Y) drive->prepareDrive(180, 75, 0);
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else if ((CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy) < -CAMERA_CENTER_Y) drive->prepareDrive(0, 75, 0);
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//X
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else if(CURRENT_DATA_READ.cam_xb < -CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xy < -CAMERA_CENTER_X) drive->prepareDrive(90, 75, 0);
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else if(CURRENT_DATA_READ.cam_xb > CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xy > CAMERA_CENTER_X) drive->prepareDrive(270, 75, 0);
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else drive->prepareDrive(0, 0, 0);
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else drive->prepareDrive(0, 0, 0); */
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/*MAKING A SINGLE LINE HERE, DOESN'T WORK FOR NOW*/
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// int x = 1;
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// int y = 1;
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/* int x = 1;
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int y = 1;
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// //Trying using an angle
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// if((CURRENT_DATA_READ.cam_yy) > CAMERA_CENTER_Y || (CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy) < -CAMERA_CENTER_Y)
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// y = CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy;
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// if(CURRENT_DATA_READ.bSeen && (CURRENT_DATA_READ.cam_xb < -CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xb > -CAMERA_CENTER_X) ) x = CURRENT_DATA_READ.cam_xb;
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// if(CURRENT_DATA_READ.ySeen && (CURRENT_DATA_READ.cam_xy < -CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xy > -CAMERA_CENTER_X) ) x = CURRENT_DATA_READ.cam_xy;
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// int dir = -90-(atan2(y*1.5,x)*180/3.14);
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// dir = (dir+360) % 360;
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// drive->prepareDrive(dir, 100, 0);
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//Trying using an angle
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if(CURRENT_DATA_READ.bSeen == true && CURRENT_DATA_READ.ySeen == true){
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if((CURRENT_DATA_READ.cam_yy) > CAMERA_CENTER_Y || (CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy) < -CAMERA_CENTER_Y)
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y = CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy;
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if(CURRENT_DATA_READ.bSeen && (CURRENT_DATA_READ.cam_xb < -CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xb > -CAMERA_CENTER_X) ) x = CURRENT_DATA_READ.cam_xb;
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if(CURRENT_DATA_READ.ySeen && (CURRENT_DATA_READ.cam_xy < -CAMERA_CENTER_X || CURRENT_DATA_READ.cam_xy > -CAMERA_CENTER_X) ) x = CURRENT_DATA_READ.cam_xy;
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int dir = -90-(atan2(y*1.5,x)*180/3.14);
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dir = (dir+360) % 360;
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drive->prepareDrive(dir, 100, 0);
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} */
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CameraPID();
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}
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//using a pid controller for the movement, or trying at least
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void PositionSysCamera :: setCameraPID(){
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X = new PID(&Inputx, &Outputx, &Setpointx, Kpx, Kix, Kdx, REVERSE);
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X->SetOutputLimits(-50,50);
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X->SetMode(AUTOMATIC);
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X->SetDerivativeLag(1);
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X->SetControllerDirection(DIRECT);
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X->SetSampleTime(1.5);
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Y = new PID(&Inputy, &Outputy, &Setpointy, Kpy, Kiy, Kdy, REVERSE);
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Y->SetOutputLimits(-50,50);
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Y->SetMode(AUTOMATIC);
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Y->SetDerivativeLag(1);
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Y->SetControllerDirection(DIRECT);
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Y->SetSampleTime(1.5);
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}
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void PositionSysCamera :: CameraPID(){
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if(CURRENT_DATA_READ.bSeen == true && CURRENT_DATA_READ.ySeen == true){
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Inputx = (CURRENT_DATA_READ.cam_xy + CURRENT_DATA_READ.cam_xb) / 2;
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Inputy = CURRENT_DATA_READ.cam_yb + CURRENT_DATA_READ.cam_yy;
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Setpointx = 0;
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Setpointy = 0;
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}
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if (CURRENT_DATA_READ.bSeen == true && CURRENT_DATA_READ.ySeen == false){
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Inputx = CURRENT_DATA_READ.cam_xb;
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Inputy = CURRENT_DATA_READ.cam_yb;
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}
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if (CURRENT_DATA_READ.bSeen == false && CURRENT_DATA_READ.ySeen == true){
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Inputx = CURRENT_DATA_READ.cam_xy;
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Inputy = CURRENT_DATA_READ.cam_yy;
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//Setpointy todo
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}
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//TODO: no goal seen
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X->Compute();
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Y->Compute();
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int dir = -90-(atan2(Outputy*1.5,Outputx)*180/3.14);
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dir = (dir+360) % 360;
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if(Outputx > 0) drive->prepareDrive(90, 100, 0);
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else drive->prepareDrive(270, 100, 0);
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}
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@ -38,8 +38,8 @@ blue_led.on()
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##############################################################################
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thresholds = [ (72, 100, -18, 11, 12, 65) , # thresholds yellow goal
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(39, 61, -18, 11, -47, -16)] # thresholds blue goal (6, 31, -15, 4, -35, 0)
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thresholds = [ (45, 71, 0, 20, 56, 84) , # thresholds yellow goal
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(16, 27, -29, -7, -10, 11)] # thresholds blue goal (6, 31, -15, 4, -35, 0)
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roi = (0, 6, 318, 152)
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@ -60,10 +60,11 @@ sensor.reset()
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sensor.set_pixformat(sensor.RGB565)
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sensor.set_framesize(sensor.QQVGA)
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sensor.set_contrast(+3)
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sensor.set_saturation(0)
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sensor.set_brightness(-2)
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sensor.set_saturation(2)
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sensor.set_brightness(0)
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sensor.set_quality(0)
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sensor.set_auto_exposure(False, 6000)
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sensor.set_auto_whitebal(False)
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sensor.set_auto_exposure(False, 2000)
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sensor.set_auto_gain(True)
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sensor.skip_frames(time = 300)
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@ -0,0 +1,149 @@
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# color tracking with conic mirror - By: EmaMaker - wed 15 jan 2020
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# Based on:
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# color tracking - By: paolix - ven mag 18 2018
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# Automatic RGB565 Color Tracking Example
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#
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import sensor, image, time, pyb, math
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from pyb import UART
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uart = UART(3,19200, timeout_char = 1000)
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START_BYTE = chr(105) #'i'
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END_BYTE = chr(115) #'s'
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BYTE_UNKNOWN = chr(116) #'t'
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y_found = False
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b_found = False
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#From Arduino Documentation at: https://www.arduino.cc/reference/en/language/functions/math/map/
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def val_map(x, in_min, in_max, out_min, out_max):
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x = int(x)
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in_min = int(in_min)
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in_max = int(in_max)
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out_min = int(out_min)
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out_max = int(out_max)
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return int((x - in_min) * (out_max - out_min) / (in_max - in_min) + out_min)
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# LED Setup ##################################################################
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red_led = pyb.LED(1)
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green_led = pyb.LED(2)
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blue_led = pyb.LED(3)
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red_led.off()
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green_led.off()
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blue_led.on()
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##############################################################################
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thresholds = [ (40, 98, -26, 2, 68, 110) , # thresholds yellow goal
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(26, 100, -38, -4, -20, 16)] # thresholds blue goal (6, 31, -15, 4, -35, 0)
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roi = (0, 6, 318, 152)
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# Camera Setup ###############################################################
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'''sensor.reset()
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sensor.set_pixformat(sensor.RGB565)
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sensor.set_framesize(sensor.QVGA)
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sensor.skip_frames(time = 2000)
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sensor.set_auto_gain(False) # must be turned off for color tracking
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sensor.set_auto_whitebal(False) # must be turned off for color tracking
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sensor.set_auto_exposure(False, 10000) vbc
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#sensor.set_backlight(1)
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#sensor.set_brightness(+2)
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#sensor.set_windowing(roi)
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clock = time.clock()'''
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sensor.reset()
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sensor.set_pixformat(sensor.RGB565)
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sensor.set_framesize(sensor.QQVGA)
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sensor.set_contrast(+3)
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sensor.set_saturation(2)
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sensor.set_brightness(0)
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sensor.set_quality(0)
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sensor.set_auto_whitebal(False)
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sensor.set_auto_exposure(False, 6000)
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sensor.set_auto_gain(True)
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sensor.skip_frames(time = 300)
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clock = time.clock()
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##############################################################################
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while(True):
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clock.tick()
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blue_led.off()
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y_found = False
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b_found = False
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tt_yellow = [(0,999,0,1)] ## creo una lista di tuple per il giallo, valore x = 999 : non trovata
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tt_blue = [(0,999,0,2)] ## creo una lista di tuple per il blue, valore x = 999 : non trovata
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img = sensor.snapshot()
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for blob in img.find_blobs(thresholds, pixels_threshold=50, area_threshold=80, merge = True):
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img.draw_rectangle(blob.rect())
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img.draw_cross(blob.cx(), blob.cy())
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if (blob.code() == 1):
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tt_yellow = tt_yellow + [ (blob.area(),blob.cx(),blob.cy(),blob.code() ) ]
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y_found = True
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if (blob.code() == 2):
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tt_blue = tt_blue + [ (blob.area(),blob.cx(),blob.cy(),blob.code() ) ]
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b_found = True
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tt_yellow.sort(key=lambda tup: tup[0]) ## ordino le liste
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tt_blue.sort(key=lambda tup: tup[0]) ## ordino le liste
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ny = len(tt_yellow)
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nb = len(tt_blue)
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y_area, y1_cx, y1_cy, y_code = tt_yellow[ny-1]
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b_area, b1_cx, b1_cy, b_code = tt_blue[nb-1]
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y_cx = int(img.width() / 2 - y1_cx)
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y_cy = int(img.height() / 2 - y1_cy)
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b_cx = int(img.width() / 2 - b1_cx)
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b_cy = int(img.height() / 2 - b1_cy)
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#Normalize data between 0 and 100
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if y_found == True:
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y_cx = val_map(y_cx, -img.width() / 2, img.width() / 2, 100, 0)
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y_cy = val_map(y_cy, -img.height() / 2, img.height() / 2, 0, 100)
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#Prepare for send as a list of characters
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s_ycx = chr(y_cx)
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s_ycy = chr(y_cy)
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else:
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y_cx = BYTE_UNKNOWN
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y_cy = BYTE_UNKNOWN
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#Prepare for send as a list of characters
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s_ycx = y_cx
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s_ycy = y_cy
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if b_found == True:
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b_cx = val_map(b_cx, -img.width() / 2, img.width() / 2, 100, 0)
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b_cy = val_map(b_cy, -img.height() / 2, img.height() / 2, 0, 100)
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#Prepare for send as a list of characters
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s_bcx = chr(b_cx)
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s_bcy = chr(b_cy)
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else:
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b_cx = BYTE_UNKNOWN
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b_cy = BYTE_UNKNOWN
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#Prepare for send as a list of characters
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s_bcx = b_cx
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s_bcy = b_cy
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print(str(y_cx) + " | " + str(y_cy) + " --- " + str(b_cx) + " | " + str(b_cy))
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uart.write(START_BYTE)
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uart.write(s_bcx)
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uart.write(s_bcy)
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uart.write(s_ycx)
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uart.write(s_ycy)
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uart.write(END_BYTE)
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