From: jon.langseth@lilug.no Date: Mon, 29 Aug 2011 12:37:12 +0000 (+0200) Subject: Initial code import, contains "fairly runnable" RCTXDuino code. X-Git-Url: https://git.defcon.no/?a=commitdiff_plain;h=eb26ecc53cac3453f083fefa643cdcff13ba8a06;p=rctxduino Initial code import, contains "fairly runnable" RCTXDuino code. --- eb26ecc53cac3453f083fefa643cdcff13ba8a06 diff --git a/README b/README new file mode 100644 index 0000000..4ca7df0 --- /dev/null +++ b/README @@ -0,0 +1,3 @@ +All the README files in this project are going to +need updating with useful content. Just adding +some README files with dummylike content first. diff --git a/hardware/README b/hardware/README new file mode 100644 index 0000000..1c09113 --- /dev/null +++ b/hardware/README @@ -0,0 +1,4 @@ +Anticipating several versions/editions before a final design +of the hardware is landed, this directory is split up from the +start. This way, we do not have to throw away the old designs +to make room for new ones :P diff --git a/hardware/prototype_1/rctxduino.sch b/hardware/prototype_1/rctxduino.sch new file mode 100644 index 0000000..839c46b Binary files /dev/null and b/hardware/prototype_1/rctxduino.sch differ diff --git a/source/RCTXDuino/RCTXDuino.pde b/source/RCTXDuino/RCTXDuino.pde new file mode 100644 index 0000000..cf711bb --- /dev/null +++ b/source/RCTXDuino/RCTXDuino.pde @@ -0,0 +1,720 @@ +#include +#include + +// --------------- ADC related stuffs.... -------------------- + +int maxval[8]; // Stores maximum values read during calibration, setup() sets 1024 +int minval[8]; // Stores minimum values read during calibration, setup() sets 0 +int rev[8]; +int dr[8]; // The Dual-rate array uses magic numbers :P +/* dr[0] = Input channel #1 of 2 for D/R switch #1. 0 means off, 1-4 valid values. + dr[1] = Input channel #2 of 2 for D/R switch #1. 0 means off, 1-4 valid values. + dr[2] = Input channel #1 of 2 for D/R switch #2. 0 means off, 1-4 valid values. + dr[3] = Input channel #2 of 2 for D/R switch #2. 0 means off, 1-4 valid values. + dr[4] = D/R value for switch # 1 LOW(off). Value -100 to 100 in steps of 5. + dr[5] = D/R value for switch # 1 HIGH(on). Value -100 to 100 in steps of 5. + dr[6] = D/R value for switch # 1 LOW(off). Value -100 to 100 in steps of 5. + dr[7] = D/R value for switch # 1 HIGH(on). Value -100 to 100 in steps of 5. +*/ + +volatile float channel[8]; + +// ----------------- Display related stuffs -------------------- +LiquidCrystal lcd( 12, 11, 10, 6, 7, 8, 9); +// Parameters are: rs, rw, enable, d4, d5, d6, d7 pin numbers. + +// ----------------- PPM related stuffs ------------------------ +// The PPM generation is handled by Timer0 interrupts, and needs +// all modifiable variables to be global and volatile... +int max_channels = 6; // How many channels should PPM generate ... +volatile long sum = 0; // Frame-time spent so far +volatile int cchannel = 0; // Current channnel +volatile bool do_channel = true; // Is next operation a channel or a separator + +// All time values in usecs +// TODO: +// The timing here (and/or in the ISR) needs to be tweaked to provide valid +// RC PPM signals accepted by standard RC RX'es and the Microcopter... +long framelength = 21500; // Max length of frame +long seplength = 400; // Lenght of a channel separator +long chmax = 1700; // Max lenght of channel pulse +long chmin = 600; // Min length of channel +long chwidht = (chmax - chmin); // Useable time of channel pulse (1000) + +// ----------------- Menu/IU related stuffs -------------------- + +// Keys/buttons/switches for UI use, including dual-rate/expo +// are digital inputs connected to a 4051 multiplexer, giving +// 8 inputs on a single input pin. +#define KEY_UP 0 +#define KEY_DOWN 1 +#define KEY_RIGHT 2 +#define KEY_LEFT 3 +#define KEY_INC 4 +#define KEY_DEC 5 +#define KEY_DR1 6 +#define KEY_DR2 7 + +// Voltage sense pin is connected to a 1/3'd voltage divider. +#define BATTERY_CONV (10 * 3 * (5.0f/1024.0f)) +#define BATTERY_LOW 92 + +enum { + VALUES, + BATTERY, + TIMER, + MENU +} +displaystate; + +enum { + TOP, + INVERTS, + DUALRATES, + EXPOS, // Some radios have "drawn curves", i.e. loopup tables stored in external EEPROM ... + DEBUG, + SAVE +} +menu_mainstate; +int menu_substate; + +boolean keys[8]; +boolean prev_keys[8]; + +int battery_val; + +// The display/UI is handled only when more +// than UI_INTERVAL milliecs has passed since last... +#define UI_INTERVAL 250 +unsigned long last = 0; + +unsigned long timer_start = 0; +unsigned long timer_init = 0; +unsigned long timer_value = 0; +boolean timer_running = false; + +// ----------------- DEBUG-STUFF -------------------- +unsigned long prev_loop_time; +unsigned long avg_loop_time; +unsigned long t; + + +// ---------- CODE! ----------------------------------- + +// ---------- Arduino SETUP code ---------------------- +void setup(){ + pinMode(13, OUTPUT); // led + + pinMode(2, OUTPUT); // s0 + pinMode(3, OUTPUT); // s1 + pinMode(4, OUTPUT); // s2 + pinMode(5, OUTPUT); // e + + lcd.begin(16,2); + lcd.print("Starting...."); + + Serial.begin(9600); + Serial.println("Starting...."); + delay(500); + read_settings(); + scan_keys(); + if ( keys[KEY_UP]) + calibrate(); + + pinMode(A5, OUTPUT); // PPM output pin + do_channel = false; + set_timer( seplength ); + Timer1.initialize(framelength); + Timer1.attachInterrupt(ISR_timer); + + displaystate = VALUES; + + // Arduino believes all pins on Port C are Analog. + // In reality they are tri-purpose; ADC, Digital, Digital Interrupts + // Unfortunately the interrupt mode is unusable in this scenario, but digital I/O works :P + pinMode(A2, INPUT); + + // Debugging: how long does the main loop take on avg... + t = micros(); + avg_loop_time = t; + prev_loop_time = t; + + dr[0] = dr[1] = dr[2] = dr[3] = 0; + dr[4] = dr[5] = dr[6] = dr[7] = 100; + +} + +// ---------- Arduino main loop ----------------------- +void loop () { + + // Determine if the UI needs to run... + boolean disp; + if ( millis() - last > UI_INTERVAL ) { + last = millis(); + disp = true; + } + else disp = false; + + process_inputs(); + + // Wasting a full I/O pin on battery status monitoring! + battery_val = analogRead(1) * BATTERY_CONV; + if ( battery_val < BATTERY_LOW ) { + digitalWrite(13, 1); // Simulate alarm :P + displaystate = BATTERY; + } + + if ( disp ) + { + ui_handler(); + } + if ( displaystate != MENU ) + { + // Debugging: how long does the main loop take on avg, + // when not handling the UI... + t = micros(); + avg_loop_time = ( t - prev_loop_time + avg_loop_time ) / 2; + prev_loop_time = t; + } + + // Whoa! Slow down partner! Let everything settle down before proceeding. + delay(5); +} + +// ----- Simple support functions used by more complex functions ---- + +void set_ppm_output( bool state ) +{ + digitalWrite(A5, state); // Hard coded PPM output +} + +void set_timer(long time) +{ + Timer1.detachInterrupt(); + Timer1.attachInterrupt(ISR_timer, time); +} + +boolean check_key( int key) +{ + return ( keys[key] && !prev_keys[key] ); +} + +void mplx_select(int pin) +{ + digitalWrite(5, 1); + delayMicroseconds(24); + + digitalWrite(2, bitRead(pin,0)); // Arduino alias for non-modifying bitshift operation + digitalWrite(3, bitRead(pin,1)); // us used to extract individual bits from the int (0..7) + digitalWrite(4, bitRead(pin,2)); // Select the appropriate input by setting s1,s2,s3 and e + digitalWrite(5, 0); // on the 4051 multiplexer. + + // May need to slow the following read down to be able to + // get fully reliable values from the 4051 multiplex. + delayMicroseconds(24); + +} + +// ----- "Complex" functions follow --------------------------------- + +void calibrate() +{ + int i, r0, r1, r2, adc_in; + int calcount = 0; + int num_calibrations = 200; + + lcd.clear(); + lcd.print("Move controls to"); + lcd.setCursor(0,1); + lcd.print("their extremes.."); + Serial.print("Calibration. Move all controls to their extremes."); + + for (i=0; i<=7; i++) { + minval[i] = 1024; + maxval[i] = 0; + } + while ( calcount <= num_calibrations ) + { + for (i=0; i<=7; i++) { + mplx_select(i); + adc_in = analogRead(0); + + // Naive min/max calibration + if ( adc_in < minval[i] ) { + minval[i] = adc_in; + } + if ( adc_in > maxval[i] ) { + maxval[i] = adc_in; + } + delay(10); + } + + calcount++; + } + + // TODO: WILL need to do center-point calibration after min-max... + + lcd.clear(); + lcd.print("Done calibrating"); + + Serial.print("Done calibrating"); + delay(2000); +} + +void read_settings(void) +{ + // Dummy. Will be modified to read model settings from EEPROM + for (int i=0; i<=7; i++) { + minval[i] = 0; + maxval[i] = 1024; + } +} + +void write_settings(void) +{ + // Dummy. Not used anywhere. Will be fleshed out to save settings to EEPROM. +} + +void scan_keys ( void ) +{ + int i, r0, r1, r2; + boolean key_in; + + // To get more inputs, another 4051 analog multiplexer is used, + // but this time it is used for digital inputs. 8 digital inputs + // on one input line, as long as proper debouncing and filtering + // is done in hardware :P + for (i=0; i<=7; i++) { + // To be able to detect that a key has changed state, preserve the previous.. + prev_keys[i] = keys[i]; + + // Select and read input. + mplx_select(i); + keys[i] = digitalRead(A2); + delay(2); + } +} + + +void process_inputs(void ) +{ + int current_input, r0, r1, r2, adc_in; + for (current_input=0; current_input<=7; current_input++) { + + mplx_select(current_input); + adc_in = analogRead(0); + + channel[current_input] = ((float)adc_in - (float)minval[current_input]) / (float)(maxval[current_input]-minval[current_input]); + if ( rev[current_input] ) channel[current_input] = 1.0f - channel[current_input]; + } +} + + +void ISR_timer(void) +{ + Timer1.stop(); // Make sure we do not run twice while working :P + + if ( !do_channel ) + { + set_ppm_output( LOW ); + sum += seplength; + do_channel = true; + set_timer(seplength); + return; + } + + if ( cchannel >= max_channels ) + { + set_ppm_output( HIGH ); + long framesep = framelength - sum; + + sum = 0; + do_channel = false; + cchannel = 0; + set_timer ( framesep ); + return; + } + + if ( do_channel ) + { + set_ppm_output( HIGH ); + long next_timer = (( chwidht * channel[cchannel] ) + chmin); + // Do sanity-check of next_timer compared to chmax ... + while ( chmax < next_timer ) next_timer--; + sum += next_timer; + + // Done with channel separator and value, + // prepare for next channel... + cchannel++; + do_channel = false; + set_timer ( next_timer ); + return; + } +} + +void serial_debug() +{ + int current_input; + for (current_input=0; current_input<=7; current_input++) { + int v = (int)(channel[current_input] * 100); + + Serial.print("Input #"); + Serial.print(current_input); + Serial.print(" value: "); + Serial.print(channel[current_input]); + Serial.print(" pct: "); + Serial.print(v); + Serial.print(" min: "); + Serial.print(minval[current_input]); + Serial.print(" max: "); + Serial.print(maxval[current_input]); + Serial.println(); + } + Serial.print("Battery level is: "); + Serial.println(battery_val); + + Serial.print("Average loop time:"); + Serial.println(avg_loop_time); + + Serial.println(); +} +void dr_inputselect( int no, int in ) +{ + if ( dr[menu_substate] < 0 ) dr[menu_substate] = 4; + if ( dr[menu_substate] > 4 ) dr[menu_substate] = 0; + + lcd.setCursor(0 , 0); + lcd.print("D/R switch "); + lcd.print( no + 1 ); + lcd.print(" "); + lcd.setCursor(0 , 1); + lcd.print("Input "); + lcd.print(in+1); + + lcd.print(": "); + if ( ! dr[menu_substate] ) lcd.print("Off"); + else lcd.print(dr[menu_substate]); + + if ( check_key(KEY_INC) ) { + dr[menu_substate]++; + return; + } + else if ( check_key(KEY_DEC) ) { + dr[menu_substate]--; + return; + } + // Wrap around. + return; + +} + +void dr_value() +{ + int pos; + int state; + + if ( menu_substate == 4) state = keys[KEY_DR1]; + else state = keys[KEY_DR2]; + + pos = 4 + (menu_substate - 4) * 2; + if (state) pos++; + + lcd.setCursor(0 , 0); + lcd.print("D/R switch "); + lcd.print( menu_substate - 3 ); + lcd.print(" "); + lcd.setCursor(0 , 1); + lcd.print( state ? "HI" : "LO" ); + lcd.print(" Value :"); + + lcd.print( dr[pos] ); + + if ( keys[KEY_INC] ) { + if ( dr[pos] < 100) dr[pos] += 5; + return; + } + else if ( keys[KEY_DEC] ) { + if ( dr[pos] > -100) dr[pos] -= 5; + return; + } + + return; +} +void ui_handler() +{ + int row; + int col; + scan_keys(); + + if ( displaystate != MENU ) + { + menu_substate = 0; + if ( check_key(KEY_UP) && displaystate == VALUES ) { + displaystate = BATTERY; + return; + } + else if ( check_key(KEY_UP) && displaystate == BATTERY ) { + displaystate = TIMER; + return; + } + else if ( check_key(KEY_UP) && displaystate == TIMER ) { + displaystate = VALUES; + return; + } + + else if ( check_key(KEY_DOWN) ) { + displaystate = MENU; + return; + } + } + + digitalWrite(13, digitalRead(13) ^ 1 ); + + switch ( displaystate ) + { + case VALUES: + int current_input; + for (current_input=0; current_input<=7; current_input++) { + // In channel value display, do a simple calc + // of the LCD row & column location. With 8 channels + // we can fit eight channels as percentage values on + // a simple 16x2 display... + if ( current_input < 4 ) + { + col = current_input * 4; + row = 0; + } + else + { + col = (current_input-4) * 4; + row = 1; + } + // Overwriting the needed positions with + // blanks cause less display-flicker than + // actually clearing the display... + lcd.setCursor(col, row); + lcd.print(" "); + lcd.setCursor(col, row); + // Display uses percents, while PPM uses ratio.... + int v = (int)(channel[current_input] * 100); + lcd.print(v); + } + break; + + + case BATTERY: + lcd.clear(); + lcd.print("Battery level: "); + lcd.setCursor(0 , 1); + lcd.print( (float)battery_val/10); + lcd.print("V"); + if ( battery_val < BATTERY_LOW ) lcd.print(" - WARNING"); + else lcd.print(" - OK"); + break; + + + + case TIMER: + unsigned long delta; + int hours; + int minutes; + int seconds; + + lcd.clear(); + lcd.print("Timer: "); + lcd.print( timer_running ? "Running" : "Stopped" ); + lcd.setCursor(5 , 1); + if ( timer_running ) + { + timer_value = millis() - (timer_start + timer_init); + } + hours = ( timer_value / 1000 ) / 3600; + timer_value = timer_value % 3600000; + minutes = ( timer_value / 1000 ) / 60; + seconds = ( timer_value / 1000 ) % 60; + if ( hours ) { + lcd.print(hours); + lcd.print(":"); + } + if ( minutes < 10 ) lcd.print("0"); + lcd.print( minutes ); + lcd.print(":"); + if ( seconds < 10 ) lcd.print("0"); + lcd.print( seconds ); + + if ( check_key(KEY_INC) ) { + if ( !timer_running && !timer_start ) + { + timer_start = millis(); + timer_value = 0; + timer_running = true; + } else if ( !timer_running && timer_start ) { + timer_start = millis() - timer_value; + timer_running = true; + } else if ( timer_running ) { + timer_running = false; + } + return; + } else if ( check_key(KEY_DEC) ) { + if ( !timer_running && timer_start ) { + timer_value = 0; + timer_start = 0; + timer_init = 0; + } + return; + } + break; + + case MENU: + lcd.clear(); + switch ( menu_mainstate ) + { + case TOP: + lcd.print("In MENU mode!"); + lcd.setCursor(0 , 1); + lcd.print("Esc UP. Scrl DN."); + menu_substate = 0; + if ( check_key(KEY_UP) ) { + displaystate = VALUES; + return; + } + else if ( check_key(KEY_DOWN) ) { + menu_mainstate = INVERTS; + return; + } + break; + + + case INVERTS: + if ( menu_substate >= max_channels ) menu_substate = 0; + if ( menu_substate < 0) menu_substate = (max_channels - 1); + lcd.print("Channel invert"); + lcd.setCursor(0 , 1); + lcd.print("Ch "); + lcd.print(menu_substate+1); + lcd.print( (rev[menu_substate] ? ": Invert" : ": Normal")); + + if ( check_key(KEY_UP) ) { + menu_mainstate = TOP; + return; + } + else if ( check_key(KEY_DOWN) ) { + menu_mainstate = DUALRATES; + return; + } + + if ( check_key(KEY_RIGHT) ) { + menu_substate++; + return; + } + else if ( check_key(KEY_LEFT) ) { + menu_substate--; + return; + } + else if ( check_key(KEY_INC) || check_key(KEY_DEC) ) { + rev[menu_substate] ^= 1; + return; + } + break; + + case DUALRATES: + if ( menu_substate > 5 ) menu_substate = 0; + if ( menu_substate < 0) menu_substate = 5; + + if ( check_key(KEY_UP) ) { + menu_mainstate = INVERTS; + return; + } + if ( check_key(KEY_DOWN) ) { + menu_mainstate = EXPOS; + return; + } + if ( check_key(KEY_RIGHT) ) { + menu_substate++; + return; + } + else if ( check_key(KEY_LEFT) ) { + menu_substate--; + return; + } + switch (menu_substate) + { + case 0: + dr_inputselect(0, 0); + return; + case 1: + dr_inputselect(0, 1); + return; + case 2: + dr_inputselect(1, 0); + return; + case 3: + dr_inputselect(1, 1); + return; + case 4: + case 5: + dr_value(); + return; + default: + menu_substate = 0; + break; + } + break; + + case EXPOS: + //________________ + lcd.print("Input expo curve"); + lcd.setCursor(0 , 1); + lcd.print("Not implemented"); + // Possible, if input values are mapped to +/- 100 rather than 0..1 .. + // plot ( x*(1 - 1.0*cos (x/(20*PI)) )) 0 to 100 + // Run in wolfram to see result, adjust the 1.0 factor to inc/red effect. + // Problem: -100 to 100 is terribly bad presicion, esp. considering that + // the values started as 0...1024, and we have 1000usec to "spend" on channels. + if ( check_key(KEY_UP ) ) { + menu_mainstate = DUALRATES; + return; + } + if ( check_key(KEY_DOWN ) ) { + menu_mainstate = DEBUG; + return; + } + break; + + case DEBUG: + lcd.setCursor(0 , 0); + lcd.print("Dumping debug to"); + lcd.setCursor(0 , 1); + lcd.print("serial port 0"); + serial_debug(); + if ( check_key(KEY_UP ) ) { + // FIXME: Remember to update the "Scroll up" state! + menu_mainstate = EXPOS; + return; + } else if ( check_key(KEY_DOWN ) ) { + menu_mainstate = SAVE; + return; + } + break; + + default: + lcd.print("Not implemented"); + lcd.setCursor(0 , 1); + lcd.print("Press DOWN..."); + if ( check_key(KEY_DOWN ) ) menu_mainstate = TOP; + } + break; + + + default: + // Invalid + return; + } + + return; +} + + + + + diff --git a/source/README b/source/README new file mode 100644 index 0000000..f2fa38d --- /dev/null +++ b/source/README @@ -0,0 +1,3 @@ +The reason for the folder-in-a-folder here, is to keep things +fairly clean, while at the same time satisfy the Arduino requirement +that the PDE file must live in a folder of the same name. diff --git a/tools/README b/tools/README new file mode 100644 index 0000000..b1daebb --- /dev/null +++ b/tools/README @@ -0,0 +1,6 @@ +Yeah. Tools. Must have tools. +Possible tool examples: + * scripts that generate stuff. + * scripts that verify stuff. + * other stuff. +