lye cypher
ES_SD541_HW52a
Fork of
lightsense_kl46z_basic
by 
Stanley Cohen
Diff: main.cpp
- Revision:
- 8:3b19ecdc4261
- Parent:
- 7:8d7089b514ae
- Child:
- 9:f619cdaa7a65
--- a/main.cpp Wed Sep 17 18:20:10 2014 +0000
+++ b/main.cpp Fri Sep 09 19:31:08 2016 +0000
@@ -2,30 +2,16 @@
#include "SLCD.h"
-// An State Machine solution to HW 4.1 Q3
-// using wait() for high and low limits.
-//#define PRINTDEBUG
-#define PROGNAME "blink_kl46z_states nowait v1\n\r"
-#define LEDON false
-#define LEDOFF true
-#define LEDTMESS "TRUE"
-#define LEDFMESS "FALS"
-#define BLINKDWELL 400 // milliseconds
-#define LIMITSTAYON 1000
-#define DFDELTA 0.01
-#define PWMTIME 1 // ms (kHz
+#define PROGNAME "lightsense_kl46z_minmax v1\n\r"
+#define DATATIME 400 // milliseconds
#define LCDLEN 10
-#define NUMSTATES 2
-#define LOWLIMIT 0.1
-#define HILIMIT 0.85
-#define ONTIME 1.0
+#define LIGHTSENSORPORT PTE22
-enum blinkStates {IDLESTATE, NEWBLINK, LOWLITE, HILITE}; // define the states
-char logicalString [NUMSTATES][LCDLEN] = {LEDFMESS, LEDTMESS};
SLCD slcd; //define LCD display globally define
Serial pc(USBTX, USBRX);
+Timer LEDTimer;
void LCDMess(char *lMess){
slcd.Home();
@@ -34,80 +20,33 @@
}
int main() {
- DigitalOut greenColor(LED_GREEN);
- DigitalOut redColor(LED_RED);
- AnalogIn LightSensor(PTE22);
+ float maxLight = 0;
+ float minLight = 1.0;
+ PwmOut greenColor(LED_GREEN);
+ PwmOut redColor(LED_RED);
+ AnalogIn LightSensor(LIGHTSENSORPORT);
float lightData;
char lcdData[LCDLEN];
- Timer LEDTimer; // time till next PWM values is to change.
- blinkStates PGMState = IDLESTATE; // work till timer transitions
- int ledState = LEDON;
-
- int timeToChangeDF = BLINKDWELL;
+ int timeToChangeDF = DATATIME;
// set up timer for next step of Duty Factor timing
LEDTimer.start();
LEDTimer.reset();
pc.printf(PROGNAME);
-
- while(true) {
- switch (PGMState){
- case IDLESTATE: {
- if (LEDTimer.read_ms() > timeToChangeDF){ // check for timer time out transtion
- lightData = (1.0 - LightSensor.read());
- sprintf(lcdData,"%4.3f",lightData);
- LCDMess(lcdData);
- timeToChangeDF = BLINKDWELL;
- if (lightData < LOWLIMIT){ // find appropriate state
- PGMState = LOWLITE;
- timeToChangeDF = LIMITSTAYON;
- } else if (lightData > HILIMIT){
- PGMState = HILITE;
- timeToChangeDF = LIMITSTAYON;
- } else {
- PGMState = NEWBLINK;
- timeToChangeDF = BLINKDWELL;
- }
-
- }
- break;
- }
- case NEWBLINK: {
- ledState = !ledState;
- redColor.write(ledState);
- greenColor.write(!ledState);
- // create string for display on LCD
-
- LEDTimer.reset(); // reset the timer
- PGMState = IDLESTATE; // go idle state
- break;
- }
- case HILITE: {
- redColor.write(LEDON);
- greenColor.write(LEDOFF);
- // create string for display on LCD
- if (LEDTimer.read_ms() > timeToChangeDF){
- LEDTimer.reset(); // reset the timer
- PGMState = IDLESTATE; // go idle state
- }
- break;
- }
- case LOWLITE: {
- redColor.write(LEDOFF);
- greenColor.write(LEDON);
- // create string for display on LCD
- if (LEDTimer.read_ms() > timeToChangeDF){
- LEDTimer.reset(); // reset the timer
- PGMState = IDLESTATE; // go idle state
- }
- break;
- }
- } // end state machine
-
-#ifdef PRINTDEBUG
- pc.printf("i= %d dutyfactor = %5.4f workingDelta %5.4f \n\r", i, dutyFactor, workingDelta);
-#endif
+ while(true) {
+ if (LEDTimer.read_ms() > timeToChangeDF){ // check for timer time out transtion
+ lightData = (1.0 - LightSensor.read()); // show as increasiing with increasing intensity
+ greenColor.write(1.0- lightData);
+ redColor.write(1.0-lightData);
+ sprintf(lcdData,"%4.3f",lightData);
+ LCDMess(lcdData);
+ if(lightData > maxLight) maxLight = lightData;
+ if(lightData < minLight) minLight = lightData;
+ pc.printf("%4.3f min = %4.3f max = %4.3f\r\n",lightData, minLight, maxLight);
+ timeToChangeDF = DATATIME;
+ LEDTimer.reset();
+ }
}// emd while
}