/**********************************************************************
CoreXY PLOTTER
Code by lingib
Last update 6 October 2017
This program controls the stepping motors in a CoreXY or H-Bot plotter.
----------
COPYRIGHT
----------
This code is free software: you can redistribute it and/or
modify it under the terms of the GNU General Public License as published
by the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This software is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License. If
not, see .
***************************************************************************/
// -------------------------------
// GLOBALS
// -------------------------------
// ----- constants
#define PI 3.1415926535897932384626433832795
#define HALF_PI 1.5707963267948966192313216916398
#define TWO_PI 6.283185307179586476925286766559
#define DEG_TO_RAD 0.017453292519943295769236907684886
#define RAD_TO_DEG 57.295779513082320876798154814105
// ----- Bit set/clear/check/toggle macros
#define SET(x,y) (x |=(1< <- ->"));
Serial.println(F(" Exit = 'E'"));
// ----- flush the buffer
while (Serial.available() > 0) Serial.read();
// ----- control motors with 'A', 'S', 'K', and 'L' keys
char keystroke = ' ';
while (keystroke != 'E') { //press 'E' key to exit
// ----- check for keypress
if (Serial.available() > 0) {
keystroke = (char) Serial.read();
}
// ----- select task
switch (keystroke) {
case 'a':
case 'A': {
// ----- rotate motor1 CW
for (step = 0; step < steps; step++) {
left();
}
keystroke = ' '; //otherwise motor will continue to rotate
break;
}
case 's':
case 'S': {
// ------ rotate motor1 CCW
for (step = 0; step < steps; step++) {
right();
}
keystroke = ' ';
break;
}
case 'k':
case 'K': {
// ----- rotate motor2 CW
for (step = 0; step < steps; step++) {
up();
}
keystroke = ' ';
break;
}
case 'l':
case 'L': {
// ----- rotate motor2 CCW
for (step = 0; step < steps; step++) {
down();
}
keystroke = ' ';
break;
}
case 'e':
case 'E': {
// ----- exit
Serial.println(F(" "));
Serial.println(F(" Calibration complete ..."));
keystroke = 'E';
break;
}
// ----- default for keystroke
default: {
break;
}
}
}
// ----- initialise counters for co-ordinate (0,0)
THIS_X = 0; //current X co-ordinate
THIS_Y = 0; //current Y co-ordinate
LAST_X = 0; //previous X co-ordinate
LAST_Y = 0; //previous Y-co-ordinate
}
// ----------------------------------
// T2 set scale factor //⭐️もう全くわからん。。。
// ----------------------------------
if (INPUT_STRING.startsWith("T2")) {
Serial.println("T2");
START = INPUT_STRING.indexOf('S');
if (!(START < 0)) {
FINISH = START + 6;
SUB_STRING = INPUT_STRING.substring(START + 1, FINISH);
SCALE_FACTOR = SUB_STRING.toFloat();
Serial.print(F("Drawing now ")); Serial.print(SCALE_FACTOR * 100); Serial.println(F("%"));
}
else {
Serial.println(F("Invalid scale factor ... try again. (1 = 100%)"));
}
}
// ----------------------------------
// T3 pen up
// ----------------------------------
if (INPUT_STRING.startsWith("T3")) {
pen_up();
}
// ----------------------------------
// T4 pen down
// ----------------------------------
if (INPUT_STRING.startsWith("T4")) {
pen_down();
}
// ----------------------------------
// T5 ABC test pattern
// ----------------------------------
if (INPUT_STRING.startsWith("T5")) {
abc();
}
// ----------------------------------
// T6 target test pattern
// ----------------------------------
if (INPUT_STRING.startsWith("T6")) {
target();
}
// ----------------------------------
// T7 radial line test pattern
// ----------------------------------
if (INPUT_STRING.startsWith("T7")) {
radials();
}
}
// -------------------------------
// MOVE_TO
// -------------------------------
/*
Assume that our sheet of paper has been
"scaled" to match the stepping motors.
*/
void move_to(float x, float y) { //x,y are absolute co-ordinates
// ----- apply scale factor
THIS_X = round(x * STEPS_PER_MM * SCALE_FACTOR); //⭐️scale x and y
THIS_Y = round(y * STEPS_PER_MM * SCALE_FACTOR);
// ----- draw a line between these "scaled" co-ordinates
draw_line(LAST_X, LAST_Y, THIS_X, THIS_Y);
// ----- remember last "scaled" co-ordinate
LAST_X = THIS_X;
LAST_Y = THIS_Y;
}
// ------------------------------------------------------------------------
// DRAW LINE
// ------------------------------------------------------------------------
/*
This routine assumes that motor1 controls the x-axis and that motor2 controls
the y-axis.
The algorithm automatically maps all "octants" to "octant 0" and
automatically swaps the XY coordinates if dY is greater than dX. A swap
flag determines which motor moves for any combination X,Y inputs. The swap
algorithm is further optimised by realising that dY is always positive
in quadrants 0,1 and that dX is always positive in "quadrants" 0,3.
Each intermediate XY co-ordinate is plotted which results in a straight line
*/
void draw_line(int x1, int y1, int x2, int y2) { //⭐️these are "scaled" co-ordinates
// ----- locals
int
x = x1, //current "scaled" X-axis position
y = y1, //current "scaled" Y-axis position
dy, //line slope
dx,
slope,
longest, //axis lengths
shortest,
maximum,
error, //bresenham thresholds
threshold;
// ----- find longest and shortest axis
dy = y2 - y1; //vertical distance
dx = x2 - x1; //horizontal distance
longest = max(abs(dy), abs(dx)); //longest axis
shortest = min(abs(dy), abs(dx)); //shortest axis
// ----- scale Bresenham values by 2*longest
error = -longest; //add offset to so we can test at zero
threshold = 0; //test now done at zero
maximum = (longest << 1); //multiply by two
slope = (shortest << 1); //multiply by two ... slope equals (shortest*2/longest*2)
// ----- initialise the swap flag
/*
The XY axes are automatically swapped by using "longest" in
the "for loop". XYswap is used to decode the motors.
*/
bool XYswap = true; //used for motor decoding
if (abs(dx) >= abs(dy)) XYswap = false;
// ----- pretend we are always in octant 0
/*
The current X-axis and Y-axis positions will now be incremented (decremented) each time
through the loop. These intermediate steps are parsed to the plot(x,y) function which calculates
the number of steps required to reach each of these intermediate co-ordinates. This effectively
linearises the plotter and eliminates unwanted curves.
*/
for (int i = 0; i < longest; i++) {
// ----- move left/right along X axis
if (XYswap) { //swap
if (dy < 0) {
y--;
down(); //move pen 1 step down
} else {
y++;
up(); //move pen 1 step up
}
} else { //no swap
if (dx < 0) {
x--;
left(); //move pen 1 step left
} else {
x++;
right(); //move pen 1 step right
}
}
// ----- move up/down Y axis
error += slope;
if (error > threshold) {
error -= maximum;
// ----- move up/down along Y axis
if (XYswap) { //swap
if (dx < 0) {
x--;
left(); //move pen 1 step left
} else {
x++;
right(); //move pen 1 step right
}
} else { //no swap
if (dy < 0) {
y--;
down(); //move pen 1 step down
} else {
y++;
up(); //move pen 1 step up
}
}
}
}
}
//--------------------------------------------------------------------
// LEFT() (move the pen 1 step left)
//--------- -----------------------------------------------------------
void left() {
DIRECTION1 = CCW;
DIRECTION2 = CCW;
step_motors();
}
//--------------------------------------------------------------------
// RIGHT() (move the pen 1 step right)
//--------- -----------------------------------------------------------
void right() {
DIRECTION1 = CW;
DIRECTION2 = CW;
step_motors();
}
//--------------------------------------------------------------------
// UP() (move the pen 1 step up)
//--------- -----------------------------------------------------------
void up() {
DIRECTION1 = CW;
DIRECTION2 = CCW;
step_motors();
}
//--------------------------------------------------------------------
// DOWN() (move the pen 1 step down)
//--------- -----------------------------------------------------------
void down() {
DIRECTION1 = CCW;
DIRECTION2 = CW;
step_motors();
}
//----------------------------------------------------------------------------------------
// STEP MOTORS
//----------------------------------------------------------------------------------------
void step_motors() {
// ----- locals
enum {dir1, step1, dir2, step2}; //define bit positions
byte pattern = PORTB; //read current state PORTB
// ----- set motor directions
//(DIRECTION1 == CW) ? SET(pattern, dir1) : CLR(pattern, dir1); //normal motor direction
//(DIRECTION2 == CW) ? SET(pattern, dir2) : CLR(pattern, dir2); //normal motor direction
(DIRECTION1 == CCW) ? SET(pattern, dir1) : CLR(pattern, dir1); //motor windings reversed
(DIRECTION2 == CCW) ? SET(pattern, dir2) : CLR(pattern, dir2); //motor windings reversed
PORTB = pattern;
delayMicroseconds(PULSE_WIDTH); //wait for direction lines to stabilise
// ----- create leading edge of step pulse(s)
pattern = SET(pattern, step1); //prepare step pulse
pattern = SET(pattern, step2);
PORTB = pattern; //step the motors
delayMicroseconds(PULSE_WIDTH); //mandatory delay
// ----- create trailing-edge of step-pulse(s)
pattern = CLR(pattern, step1);
pattern = CLR(pattern, step2);
PORTB = pattern;
// ----- determines plotting speed
delayMicroseconds(DELAY);
}
//----------------------------------------------------------------------------
// DRAW ARC CLOCKWISE (G02)
//----------------------------------------------------------------------------
void draw_arc_cw(float x, float y, float i, float j) {
// ----- inkscape sometimes produces some crazy values for i,j
if ((i < -100) || (i > 100) || (j < -100) || (j > 100)) {
move_to(x, y);
} else {
// ----- variables
float
thisX = LAST_X / (STEPS_PER_MM * SCALE_FACTOR), //current unscaled X co-ordinate
thisY = LAST_Y / (STEPS_PER_MM * SCALE_FACTOR), //current unscaled Y co-ordinate
nextX = x, //next X co-ordinate
nextY = y, //next Y co-ordinate
newX, //interpolated X co-ordinate
newY, //interpolated Y co-ordinate
I = i, //horizontal distance thisX from circle center
J = j, //vertical distance thisY from circle center
circleX = thisX + I, //circle X co-ordinate
circleY = thisY + J, //circle Y co-ordinate
delta_x, //horizontal distance between thisX and nextX
delta_y, //vertical distance between thisY and nextY
chord, //line_length between lastXY and nextXY
radius, //circle radius
alpha, //interior angle of arc
beta, //fraction of alpha
arc, //subtended by alpha
current_angle, //measured CCW from 3 o'clock
next_angle; //measured CCW from 3 o'clock
// ----- calculate arc
delta_x = thisX - nextX;
delta_y = thisY - nextY;
chord = sqrt(delta_x * delta_x + delta_y * delta_y);
radius = sqrt(I * I + J * J);
alpha = 2 * asin(chord / (2 * radius)); //see construction lines
arc = alpha * radius; //radians
// ----- sub-divide alpha
int segments = 1;
if (arc > ARC_MAX) {
segments = (int)(arc / ARC_MAX);
beta = alpha / segments;
} else {
beta = alpha;
}
// ----- calculate current angle
/*
atan2() angles between 0 and PI are CCW +ve from 3 o'clock.
atan2() angles between 2*PI and PI are CW -ve relative to 3 o'clock
*/
current_angle = atan2(-J, -I);
if (current_angle <= 0) current_angle += 2 * PI; //angles now 360..0 degrees CW
// ----- plot intermediate CW co-ordinates
next_angle = current_angle; //initialise angle
for (int segment = 1; segment < segments; segment++) {
next_angle -= beta; //move CW around circle
if (next_angle < 0) next_angle += 2 * PI; //check if angle crosses zero
newX = circleX + radius * cos(next_angle); //standard circle formula
newY = circleY + radius * sin(next_angle);
move_to(newX, newY);
}
// ----- draw final line
move_to(nextX, nextY);
}
}
//----------------------------------------------------------------------------
// DRAW ARC COUNTER-CLOCKWISE (G03)
//----------------------------------------------------------------------------
/*
We know the start and finish co-ordinates which allows us to calculate the
chord length. We can also calculate the radius using the biarc I,J values.
If we bisect the chord the center angle becomes 2*asin(chord/(2*radius)).
The arc length may now be calculated using the formula arc_length = radius*angle.
*/
void draw_arc_ccw(float x, float y, float i, float j) {
// ----- inkscape sometimes produces some crazy values for i,j
if ((i < -100) || (i > 100) || (j < -100) || (j > 100)) {
move_to(x, y);
} else {
// ----- variables
float
thisX = LAST_X / SCALE_FACTOR, //current unscaled X co-ordinate
thisY = LAST_Y / SCALE_FACTOR, //current unscaled Y co-ordinate
nextX = x, //next X co-ordinate
nextY = y, //next Y co-ordinate
newX, //interpolated X co-ordinate
newY, //interpolated Y co-ordinate
I = i, //horizontal distance thisX from circle center
J = j, //vertical distance thisY from circle center
circleX = thisX + I, //circle X co-ordinate
circleY = thisY + J, //circle Y co-ordinate
delta_x, //horizontal distance between thisX and nextX
delta_y, //vertical distance between thisY and nextY
chord, //line_length between lastXY and nextXY
radius, //circle radius
alpha, //interior angle of arc
beta, //fraction of alpha
arc, //subtended by alpha
current_angle, //measured CCW from 3 o'clock
next_angle; //measured CCW from 3 o'clock
// ----- calculate arc
delta_x = thisX - nextX;
delta_y = thisY - nextY;
chord = sqrt(delta_x * delta_x + delta_y * delta_y);
radius = sqrt(I * I + J * J);
alpha = 2 * asin(chord / (2 * radius)); //see construction lines
arc = alpha * radius; //radians
// ----- sub-divide alpha
int segments = 1;
if (arc > ARC_MAX) {
segments = (int)(arc / ARC_MAX);
beta = alpha / segments;
} else {
beta = alpha;
}
// ----- calculate current angle
/*
tan2() angles between 0 and PI are CCW +ve from 3 o'clock.
atan2() angles between 2*PI and PI are CW -ve relative to 3 o'clock
*/
current_angle = atan2(-J, -I);
if (current_angle <= 0) current_angle += 2 * PI; //angles now 360..0 degrees CW
// ----- plot intermediate CCW co-ordinates
next_angle = current_angle; //initialise angle
for (int segment = 1; segment < segments; segment++) {
next_angle += beta; //move CCW around circle
if (next_angle > 2 * PI) next_angle -= 2 * PI; //check if angle crosses zero
newX = circleX + radius * cos(next_angle); //standard circle formula
newY = circleY + radius * sin(next_angle);
move_to(newX, newY);
}
// ----- draw final line
move_to(nextX, nextY);
}
}
//---------------------------------------------------------------------------
// PEN_UP
// Raise the pen
// Changing the value in OCR2B changes the pulse-width to the SG-90 servo
//---------------------------------------------------------------------------
void pen_up() {
OCR2B = 148; //1mS pulse
delay(250); //give pen-lift time to respond
}
//---------------------------------------------------------------------------
// PEN_DOWN
// Lower the pen
// Changing the value in OCR2B changes the pulse-width to the SG-90 servo
//---------------------------------------------------------------------------
void pen_down() {
OCR2B = 140; //2mS pulse
delay(250); //give pen-lift time to respond
}
// ----------------------------------------
// ABC
// ----------------------------------------
void abc() {
process(F("T2 S3"));
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process(F("G03 X47.727663 Y21.168894 I0.000000 J6.006005"));
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process(F("G02 X36.379807 Y25.321353 I-2.380949 J-2.479122"));
process(F("G02 X36.618935 Y24.227336 I-2.383015 J-1.094017"));
process(F("G02 X36.026166 Y22.197076 I-3.773251 J0.000000"));
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process(F("G02 X25.486301 Y22.117485 I35.898712 J-5.609165"));
process(F("G01 X26.857219 Y29.010969"));
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process(F("G02 X28.587881 Y31.295831 I0.503083 J-1.861405"));
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process(F("G01 X27.596154 Y22.506398"));
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process(F("G03 X27.382252 Y21.057695 I2.288700 J-0.337928"));
process(F("G03 X27.843772 Y20.294140 I0.862387 J0.000000"));
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process(F("G03 X34.363240 Y23.585630 I-2.682024 J1.385220"));
process(F("G03 X34.148489 Y24.695436 I-2.975045 J-0.000000"));
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process(F("G03 X31.076926 Y26.521924 I-3.621282 J-8.717909"));
process(F("G02 X30.432077 Y26.335937 I-1.252000 J3.130013"));
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process(F("G02 X29.764344 Y27.756722 I1.202868 J-0.601434"));
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process(F("G02 X31.135261 Y28.116468 I0.900744 J-3.432550"));
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process(F("G03 X27.293198 Y31.874110 I-0.000000 J-8.193950"));
process(F("G03 X23.454230 Y28.699836 I6.012387 J-11.179941"));
process(F("G01 X23.454230 Y28.699836"));
process(F("G00 X12.370209 Y25.345461"));
process(F("G01 X14.334220 Y25.296848"));
process(F("G03 X16.344033 Y25.341207 I0.000000 J45.552596"));
process(F("G03 X17.416355 Y25.432967 I-0.576039 J13.043259"));
process(F("G02 X17.057498 Y28.851447 I66.264688 J8.684258"));
process(F("G02 X16.969105 Y31.091652 I28.343468 J2.240205"));
process(F("G01 X16.978828 Y31.820863"));
process(F("G02 X16.654582 Y31.415231 I-24.362686 J19.142120"));
process(F("G02 X15.539850 Y30.051310 I-276.590024 J224.919481"));
process(F("G03 X13.629409 Y27.498969 I29.639011 J-24.176118"));
process(F("G03 X12.574388 Y25.724652 I13.226843 J-9.065587"));
process(F("G01 X12.370209 Y25.345461"));
process(F("G00 X11.670166 Y24.198168"));
process(F("G01 X11.475709 Y23.828703"));
process(F("G03 X10.453024 Y21.493002 I14.155155 J-7.589567"));
process(F("G03 X10.250633 Y20.289593 I3.476515 J-1.203409"));
process(F("G03 X10.316083 Y19.943208 I0.949331 J-0.000000"));
process(F("G03 X10.532595 Y19.570105 I1.323570 J0.518696"));
process(F("G03 X10.300257 Y19.489445 I3.137841 J-9.413445"));
process(F("G03 X9.482530 Y19.190914 I42.222649 J-116.924015"));
process(F("G02 X9.097875 Y19.086190 I-0.855158 J2.382242"));
process(F("G02 X8.763041 Y19.054795 I-0.334835 J1.769854"));
process(F("G02 X8.277401 Y19.249753 I0.000000 J0.702344"));
process(F("G02 X8.082443 Y19.706223 I0.436907 J0.456470"));
process(F("G02 X8.333756 Y20.987389 I3.391281 J0.000000"));
process(F("G02 X9.764492 Y23.828703 I18.642339 J-7.606424"));
process(F("G01 X10.065899 Y24.324564"));
process(F("G01 X9.570035 Y24.324564"));
process(F("G03 X8.016212 Y24.170112 I-0.000000 J-7.893143"));
process(F("G03 X7.100438 Y23.828703 I0.608728 J-3.031721"));
process(F("G02 X7.932520 Y24.978194 I1.964955 J-0.546467"));
process(F("G02 X9.560313 Y25.471860 I1.627793 J-2.436874"));
process(F("G01 X10.765943 Y25.442689"));
process(F("G01 X11.028459 Y25.831603"));
process(F("G02 X12.621837 Y28.077029 I38.056380 J-25.317154"));
process(F("G02 X15.695415 Y32.005598 I119.673321 J-90.461712"));
process(F("G02 X16.806236 Y33.260000 I14.322595 J-11.564166"));
process(F("G02 X17.280236 Y33.639032 I1.733405 J-1.681816"));
process(F("G02 X17.834414 Y33.882572 I1.177026 J-1.926044"));
process(F("G02 X19.312306 Y34.222402 I3.908941 J-13.616125"));
process(F("G03 X19.095228 Y32.467101 I23.799291 J-3.834329"));
process(F("G03 X19.030344 Y30.965256 I17.348913 J-1.501845"));
process(F("G03 X19.256050 Y26.994264 I35.045048 J-0.000000"));
process(F("G03 X19.954013 Y22.866141 I38.580488 J4.399934"));
process(F("G03 X20.720782 Y20.795305 I8.056900 J1.805858"));
process(F("G03 X21.499942 Y19.959018 I1.953184 J1.038650"));
process(F("G02 X20.521336 Y19.212088 I-3.388359 J3.424790"));
process(F("G02 X19.934567 Y19.054795 I-0.586769 J1.015804"));
process(F("G02 X18.944735 Y19.694699 I-0.000000 J1.085511"));
process(F("G02 X17.562198 Y24.324564 I16.634711 J7.488692"));
process(F("G02 X15.955536 Y24.193605 I-3.198664 J29.321420"));
process(F("G02 X14.324497 Y24.149555 I-1.631039 J30.174575"));
process(F("G01 X11.670166 Y24.198168"));
process(F("G00 X0.0000 Y0.0000"));
process(F("T2 S1"));
}
//----------------------------------------------------------------------------
// TARGET test pattern
//----------------------------------------------------------------------------
void target() {
process(F("T2 S3"));
process(F("G00 X51.309849 Y6.933768"));
process(F("G01 X7.893822 Y50.349788"));
process(F("G00 X7.893823 Y50.349788"));
process(F("G01 X51.309852 Y50.349788"));
process(F("G01 X51.309852 Y6.933760"));
process(F("G01 X7.893823 Y6.933760"));
process(F("G01 X7.893823 Y50.349788"));
process(F("G00 X43.948985 Y28.588440"));
process(F("G02 X39.778044 Y18.518899 I-14.240483 J0.000001"));
process(F("G02 X29.708503 Y14.347958 I-10.069542 J10.069542"));
process(F("G02 X19.638962 Y18.518898 I-0.000000 J14.240483"));
process(F("G02 X15.468020 Y28.588440 I10.069542 J10.069543"));
process(F("G02 X16.552012 Y34.038037 I14.240483 J0.000001"));
process(F("G02 X19.638961 Y38.657983 I13.156491 J-5.449596"));
process(F("G02 X24.258906 Y41.744932 I10.069543 J-10.069542"));
process(F("G02 X29.708503 Y42.828924 I5.449597 J-13.156491"));
process(F("G02 X39.778045 Y38.657982 I-0.000001 J-14.240483"));
process(F("G02 X43.948985 Y28.588440 I-10.069543 J-10.069541"));
process(F("G01 X43.948985 Y28.588440"));
process(F("G00 X51.309849 Y50.349788"));
process(F("G01 X7.893822 Y6.933768"));
process(F("G00 X0.0000 Y0.0000"));
process(F("T2 S1"));
}
//----------------------------------------------------------------------------
// RADIALS test pattern
//----------------------------------------------------------------------------
void radials() {
// ----- move to the centre of the square
pen_up();
move_to(100, 100);
// ----- draw octant 0 radials
pen_down();
move_to(150, 100);
pen_up();
move_to(100, 100);
pen_down();
move_to(150, 125);
pen_up();
move_to(100, 100);
pen_down();
move_to(150, 150);
pen_up();
move_to(100, 100);
// ----- draw octant 1 radials
pen_down();
move_to(125, 150);
pen_up();
move_to(100, 100);
pen_down();
move_to(100, 150);
pen_up();
move_to(100, 100);
// ----- draw octant 2 radials
pen_down();
move_to(75, 150);
pen_up();
move_to(100, 100);
pen_down();
move_to(50, 150);
pen_up();
move_to(100, 100);
// ----- draw octant 3 radials
pen_down();
move_to(50, 125);
pen_up();
move_to(100, 100);
pen_down();
move_to(50, 100);
pen_up();
move_to(100, 100);
// ----- draw octant 4 radials
pen_down();
move_to(50, 75);
pen_up();
move_to(100, 100);
pen_down();
move_to(50, 50);
pen_up();
move_to(100, 100);
// ----- draw octant 5 radials
pen_down();
move_to(75, 50);
pen_up();
move_to(100, 100);
pen_down();
move_to(100, 50);
pen_up();
move_to(100, 100);
// ----- draw octant 6 radials
pen_down();
move_to(125, 50);
pen_up();
move_to(100, 100);
pen_down();
move_to(150, 50);
pen_up();
move_to(100, 100);
// ----- draw octant 7 radials
pen_down();
move_to(150, 75);
pen_up();
move_to(100, 100);
pen_up();
// ----- draw box
move_to(50, 50);
pen_down();
move_to(50, 150);
move_to(150, 150);
move_to(150, 50);
move_to(50, 50);
pen_up();
// home --------------
move_to(0.0000, 0.0000);
}