AcidDropUI/AcidDrop UI PIO/lib/TFT_eSPI/examples/Sprite/Orrery/Orrery.ino

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Arduino
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2024-06-06 05:12:19 +00:00
// Display an Orrery
// Works for all display sizes but 320x480 minimum size recommended
// Whole planet orbits only visible in 480 x 800 display
// Flicker free sprite example for TFT_eSPI:
// https://github.com/Bodmer/TFT_eSPI
// Sketch coded by Bodmer
// Uses astronomy engine created by Don Cross
#include <TFT_eSPI.h> // Hardware-specific library
TFT_eSPI tft = TFT_eSPI(); // Invoke library
TFT_eSprite img = TFT_eSprite(&tft); // Sprite class
#define sunX tft.width()/2
#define sunY tft.height()/2
uint16_t orb_inc;
uint16_t planet_r;
#include <stdio.h>
#include "astronomy.h"
#define TIME_TEXT_BYTES 25
astro_time_t astro_time;
uint16_t grey;
static const astro_body_t body[] = {
BODY_SUN, BODY_MERCURY, BODY_VENUS, BODY_EARTH, BODY_MARS,
BODY_JUPITER, BODY_SATURN, BODY_URANUS, BODY_NEPTUNE
};
static const uint16_t bodyColour[] = {
TFT_YELLOW, TFT_DARKGREY, TFT_ORANGE, TFT_BLUE, TFT_RED,
TFT_GOLD, TFT_BROWN, TFT_DARKCYAN, TFT_CYAN
};
// =========================================================================
// Setup
// =========================================================================
void setup() {
Serial.begin(115200);
tft.begin();
tft.setRotation(1);
tft.fillScreen(TFT_BLACK);
// Test with smaller display sizes
//tft.setViewport(10,10,160,128);
//tft.setViewport(10,10,320,240);
//tft.setViewport(10,10,480,320);
//tft.frameViewport(TFT_GREEN, -1);
img.createSprite(19, 19);
grey = tft.color565(30, 30, 30);
astro_time = Astronomy_MakeTime(2020, 10, 16, 19, 31, 0) ;
tft.fillCircle(sunX, sunY, 10, TFT_YELLOW);
// i initialised to 1 so Sun is skipped
for (int i = 1; i < sizeof(body) / sizeof(body[0]); ++i)
{
tft.drawCircle(sunX, sunY, i * 28, grey);
}
}
// =========================================================================
// Loop
// =========================================================================
void loop() {
uint32_t dt = millis();
plot_planets();
showTime(astro_time);
// Add time increment (more than 0.6 days will lead to stray pixel on screen
// due to the way previous object images are erased)
astro_time = Astronomy_AddDays(astro_time, 0.25); // 0.25 day (6 hour) increment
dt = millis()-dt;
//Serial.println(dt);
//delay(1000);
}
// =========================================================================
// Get coordinates of end of a vector, pivot at x,y, length r, angle a
// =========================================================================
// Coordinates are returned to caller via the xp and yp pointers
#define DEG2RAD 0.0174532925
void getCoord(int x, int y, int *xp, int *yp, int r, float a)
{
float sx1 = cos( -a * DEG2RAD );
float sy1 = sin( -a * DEG2RAD );
*xp = sx1 * r + x;
*yp = sy1 * r + y;
}
// =========================================================================
// Convert astronomical time to UTC and display
// =========================================================================
void showTime(astro_time_t time)
{
astro_status_t status;
char text[TIME_TEXT_BYTES];
status = Astronomy_FormatTime(time, TIME_FORMAT_SECOND, text, sizeof(text));
if (status != ASTRO_SUCCESS)
{
fprintf(stderr, "\nFATAL(PrintTime): status %d\n", status);
exit(1);
}
tft.drawString(text, 0, 0, 2);
}
// =========================================================================
// Plot planet positions as an Orrery
// =========================================================================
int plot_planets(void)
{
astro_angle_result_t ang;
int i;
int num_bodies = sizeof(body) / sizeof(body[0]);
// i initialised to 1 so Sun is skipped
for (i = 1; i < num_bodies; ++i)
{
ang = Astronomy_EclipticLongitude(body[i], astro_time);
int x1 = 0; // getCoord() will update these
int y1 = 0;
getCoord(0, 0, &x1, &y1, i * 28, ang.angle); // Get x1 ,y1
img.fillSprite(TFT_TRANSPARENT);
img.fillCircle(9, 9, 9, TFT_BLACK);
img.drawCircle(9 - x1, 9 - y1, i * 28, grey);
img.fillCircle(9, 9, 5, bodyColour[i]);
img.pushSprite(sunX + x1 - 9, sunY + y1 - 9, TFT_TRANSPARENT);
if (body[i] == BODY_EARTH)
{
astro_angle_result_t mang = Astronomy_LongitudeFromSun(BODY_MOON, astro_time);
int xm = 0;
int ym = 0;
getCoord(x1, y1, &xm, &ym, 15, 180 + ang.angle + mang.angle); // Get x1 ,y1
img.fillSprite(TFT_TRANSPARENT);
img.fillCircle(9, 9, 7, TFT_BLACK);
img.drawCircle(9 - xm, 9 - ym, i * 28, grey);
img.fillCircle(9, 9, 2, TFT_WHITE);
img.pushSprite(sunX + xm - 9, sunY + ym - 9, TFT_TRANSPARENT);
}
}
return 0;
}