Changeset 17634
- Timestamp:
- 03/18/14 16:33:18 (11 years ago)
- File:
-
- 1 edited
Legend:
- Unmodified
- Added
- Removed
-
firmware/FSC/src/FSC.c
r10753 r17634 1 //-----------------------------------------------------------------------------2 1 #include "typedefs.h" 3 #include "application.h" 2 #include "application.h" // <-- global Registers 3 4 4 #include "spi_master.h" 5 #include "timer.h" 6 #include "atmega_adc.h" 5 7 #include "ad7719_adc.h" 6 #include " atmega_adc.h"7 #include "usart.h" 8 #include "w5100_spi_interface.h" 9 8 10 #include "macros.h" 9 #include " interpol.h"10 //#include "w5100_spi_interface.h" 11 #include "muxer_fsc.h" 12 11 13 #include <avr/interrupt.h> 12 14 #include <avr/wdt.h> 13 15 #include <stdlib.h> 14 //-----------------------------------------------------------------------------15 // definition of some functions:16 // these function are implemented in this file, this is not doog coding style.17 // sooner or later, they will be moved into more apropriate files.18 U08 increase_adc (U08 channel);19 U08 increase_ad7719 (U08 channel);20 void Set_V_Muxer (U08 channel);21 void Set_T_Muxer(U08 channel);22 void talk(void);// never used up to now.23 void ad7719_output(U08 channel, U32 data);24 void adc_output(U08 channel, U08 data);25 void adc_output_all();26 void parse(); //doesn't do anything at the moment27 void check_if_measured_all() ;28 void print_ad7719_nicely();29 void print_adc_nicely();30 void print_temp_nicely();31 // end of function definition:32 //-----------------------------------------------------------------------------33 16 34 // MAIN WORKFLOW GLOBAL VARIABLES35 bool verbose;36 bool heartbeat_enable;37 17 38 // USART global variables39 U08 usart_rx_buffer[USART_RX_BUFFER_SIZE];40 U08 usart_tx_buffer[USART_TX_BUFFER_SIZE];41 U08 usart_received_chars;42 U08 usart_rx_buffer_index = 0;43 U08 usart_tx_buffer_index = 0;44 U08 usart_last_char; // last received char45 46 // USART FLAGS47 bool usart_tx_buffer_overflow = false; // true if usart_tx_buffer was full.48 bool usart_rx_ready = false; // EOL was received, parser needs to be called49 50 // TIMER global variable51 volatile U32 local_ms = 0;52 53 // AD7719 global variables54 #define TEMP_CHANNELS 6455 #define CHANNEL_BITMAP 856 #define AD7719_READINGS_UNTIL_SETTLED 3 // bei3:480ms57 U32 ad7719_values[TEMP_CHANNELS];58 U08 ad7719_enables[CHANNEL_BITMAP];59 U08 ad7719_channels_ready[CHANNEL_BITMAP];60 U08 ad7719_readings_since_last_muxing = 0;61 U08 ad7719_current_channel = 0;62 U32 ad7719_current_reading = 0;63 bool ad7719_measured_all = false;64 65 // ATMEGA ADC global variables66 #define V_CHANNELS 4067 #define I_CHANNELS 4068 #define H_CHANNELS 469 #define V_BITMAP 570 #define I_BITMAP 571 #define H_BITMAP 172 #define ADC_READINGS_UNTIL_SETTLED 173 U08 adc_values[V_CHANNELS + I_CHANNELS + H_CHANNELS]; // stores measured voltage in steps of 16mV74 U08 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP];75 U08 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP];76 U08 adc_readings_since_last_muxing = 0;77 U08 adc_current_channel = 0;78 U08 adc_current_reading = 0;79 bool adc_measured_all = false;80 81 bool once_told_you = true;82 bool debug_mode = false;83 84 //-----------------------------------------------------------------------------85 // M A I N --- M A I N --- M A I N --- M A I N --- M A I N86 //-----------------------------------------------------------------------------87 18 int main(void) 88 19 { 89 app_init(); // Setup: Watchdog and I/Os 90 usart_init(); // Initialize serial interface 91 spi_init(); // Initialize SPI interface as master 92 ad7719_init(); // Initialize AD7719 ADC as SPI slave 93 atmega_adc_init(); 20 U08 highbyte; 21 U08 lowbyte; 22 U16 eth_red_bytes; 23 U08 rc; 94 24 95 // TIMER2 is used as local clock: 96 // configure timer 2 97 TCCR2 = (1<<WGM21); // CTC Modus 98 TCCR2 |= (1<<CS21) | (1<<CS20); // Prescaler 64 --> counts up every 8us 99 OCR2 = 125-1; // --> output compare interrupt occurs every 125 x 8us = 1ms 100 // Compare Interrupt erlauben 101 TIMSK |= (1<<OCIE2); 102 103 // Enable interrupts 104 sei(); 105 106 PORTB &= ~(1<<PB2); 107 108 ad7719_enables[0]=0x00; 109 ad7719_enables[1]=0x00; 110 ad7719_enables[2]=0x00; 111 ad7719_enables[3]=0x00; 112 ad7719_enables[4]=0x00; 113 ad7719_enables[5]=0x00; 114 ad7719_enables[6]=0x00; 115 ad7719_enables[7]=0x00; 116 for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) { 117 ad7719_channels_ready[i]=0; 118 } 119 ad7719_current_channel = increase_ad7719 (ad7719_current_channel); 120 121 for ( U08 i=0; i<V_BITMAP + I_BITMAP; ++i ) { 122 adc_enables[i]=0xFF; 123 adc_channels_ready[i]=0; 124 } 125 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP -1] = 0x0F; 126 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP -1]=0; 127 128 static U08 welcome[]="\n\nwelcome to FACT FSC commandline interface v0.4\nDN 17.03.2011\nready?"; 129 usart_write_str(welcome); 25 gReg.ad7719_measured_all = false; 26 gReg.adc_measured_all = false; 27 for ( U08 i=0; i < (RESISTANCE_REGS); ++i ) { 28 gReg.ad7719_enables[i]=0xFF; 29 gReg.ad7719_channels_ready[i]=0x00; 30 } 31 for ( U08 i=0; i < (VOLTAGE_REGS); ++i ) { 32 if (i < (VOLTAGE_REGS)-1) { 33 gReg.adc_enables[i]=0xFF; 34 } 35 else { 36 gReg.adc_enables[i]=0x0F; 37 } 38 gReg.adc_channels_ready[i]=0; 39 } 130 40 131 41 132 //MAIN LOOP 133 while (1) 134 { 42 app_init(); // Setup: Watchdog and I/Os 43 spi_init(); // Initialize SPI interface as master 44 timer_init(); // set up TIMER2: TIMER2_COMP interrupt occurs every 1ms 45 atmega_adc_init(); 135 46 136 //IF one of the ADC measured all channels, we wanted to know. 137 check_if_measured_all(); 138 139 if (ad7719_measured_all && adc_measured_all && !once_told_you) 140 { 141 adc_output_all(); 142 once_told_you = true; 143 } 144 //---------------------------------------------------------------------------- 47 w5100_reset(); 48 w5100_init(); 145 49 146 if (heartbeat_enable) PORTB ^= (1<<PB3); // toggle Out2_spare --> heartbeat 147 //---------------------------------------------------------------------------- 148 //IF we need to send away one byte, and ready to send 50 ad7719_init(); 51 sei(); 149 52 150 if ( (usart_tx_buffer_index > 0) && (UCSRA & (1<<UDRE)) ) { 151 UDR = usart_tx_buffer[0]; 152 // THis is shit 153 for (U08 i=0 ; i < USART_TX_BUFFER_SIZE; ++i) { 154 usart_tx_buffer[i] = usart_tx_buffer[i+1]; 155 } 156 usart_tx_buffer_index--; 157 } 158 //---------------------------------------------------------------------------- 53 //MAIN LOOP 54 while (1) 55 { 56 // checks if socket is okay and resets in case of problem the W5100 57 rc=w5100_caretaker(); 58 if ( rc != 0x17 && rc != 0x14) 59 { 60 // something is not okay with the ethernet ... 61 // will be reset in the next revolution.. but maybe we want to do more... 62 } 63 // this if should check every 25ms if we have any data on the W5100 64 if ( (gVolReg.time_ms % W5100_INPUT_CHECK_TIME == 0) && (w5100_ready) ) { 65 if ( (eth_red_bytes = get_S0_RX_RSR()) != 0) { 66 for (U08 rep=0; rep<1; ) { 67 if (eth_red_bytes == get_S0_RX_RSR() ) { 68 rep++; 69 } 70 else { 71 eth_red_bytes =get_S0_RX_RSR(); 72 } 73 } 74 //parse_w5300_incoming( w5100_get_RX(ETH_READ_BUFFER_SIZE, true) ); 75 } 76 } 77 //---------------------------------------------------------------------------- 78 if (check_if_measured_all()) { 79 write_status_via_eth(); 80 reset_resistance_done(); 81 reset_voltage_done(); 82 reset_voltage_values(); 83 } 159 84 160 //IF we just received one byte, and there is enough space in the RX_buffer 161 if ( (UCSRA & (1<<RXC)) && (usart_rx_buffer_index < USART_RX_BUFFER_SIZE) ){ 162 usart_last_char = UDR; 163 if (usart_last_char == '\n'){ // if EOL was received 164 usart_rx_ready = true; 165 }else { 166 usart_rx_buffer[usart_rx_buffer_index] = usart_last_char; 167 usart_rx_buffer_index++; 168 } 169 // here is still something strange .... better send an enter automatically 170 } else if (UCSRA & (1<<RXC)) { // if there is no scace in the buffer; read anyway. 171 usart_last_char = UDR; 172 usart_rx_buffer_index =0; 173 } 174 //---------------------------------------------------------------------------- 85 //IF ATmega internal ADC did finish a conversion --every 200us 86 if ( (ADCSRA & (1<<ADIF)) && !gReg.adc_measured_all) { 87 lowbyte = ADCL; 88 highbyte = ADCH; 89 ADCSRA |= 1<<ADIF; 90 gReg.adc_current_reading = ((U16)highbyte<<8) | ((U16)lowbyte); 91 if (gReg.adc_readings_since_last_muxing == ADC_READINGS_UNTIL_SETTLED + ADC_READINGS_UNTIL_MEAN - 1) { 92 gReg.adc_values[gReg.adc_current_channel] += gReg.adc_current_reading; 93 gReg.adc_channels_ready[gReg.adc_current_channel/8] |= (1<<(gReg.adc_current_channel%8)); 94 gReg.adc_current_channel = increase_adc(gReg.adc_current_channel); 95 Set_V_Muxer(gReg.adc_current_channel); 96 gReg.adc_readings_since_last_muxing = 0; 97 _delay_ms(10); // this is a muxer delay 98 } 99 else if (gReg.adc_readings_since_last_muxing >= ADC_READINGS_UNTIL_SETTLED-1) { 100 gReg.adc_values[gReg.adc_current_channel] += gReg.adc_current_reading; 101 ++gReg.adc_readings_since_last_muxing; 102 } 103 else { 104 ++gReg.adc_readings_since_last_muxing; 105 } 106 } 107 //---------------------------------------------------------------------------- 175 108 176 //IF USART DOR bit is set, PC is sending data to fast!!! 177 if ( UCSRA & (1<<DOR) ){ 178 // flush TX_buffer and write warning message in 179 // maybe even switch off every measurement. ? 180 } 181 //---------------------------------------------------------------------------- 109 //IF AD7719 ADC just finished a conversion -- every 60ms 110 if (AD7719_IS_READY() && !gReg.ad7719_measured_all) { 111 gReg.ad7719_current_reading = read_adc(); // --takes at 4MHz SCLK speed about 6us 112 // AD7719 is only read out if settled. saves time. 113 if (gReg.ad7719_readings_since_last_muxing == AD7719_READINGS_UNTIL_SETTLED-1) { 114 gReg.ad7719_values[gReg.ad7719_current_channel] = gReg.ad7719_current_reading; 115 gReg.ad7719_readings_since_last_muxing=0; 116 // now prepare the data to be send away via USART. 117 // note that this channel is ready, now and 118 // proceed to the next enabled channel. 119 gReg.ad7719_channels_ready[gReg.ad7719_current_channel/8] |= (1<<(gReg.ad7719_current_channel%8)); 120 gReg.ad7719_current_channel = increase_ad7719(gReg.ad7719_current_channel); 121 Set_T_Muxer(gReg.ad7719_current_channel); 122 } 123 else { // the AD7719 did not settle yet, we discard the reading 124 ++gReg.ad7719_readings_since_last_muxing; 125 } 126 } 182 127 183 //IF TX_BUFFER was overrun. 184 if (usart_tx_buffer_overflow) { 185 // flash TX_buffer and write warning message in 186 // maybe even switch off every measurement. ? 187 // 188 // this should only happen, in verbose mode and with low baudrates. 189 } 190 //---------------------------------------------------------------------------- 191 192 //IF one command was received. 193 // -It is not allowed to send more than one command between two '\n' 194 if (usart_rx_ready){ 195 parse(); 196 usart_rx_buffer_index = 0; 197 usart_rx_ready = false; 198 } 199 //---------------------------------------------------------------------------- 200 201 //IF ATmega internal ADC did finish a conversion --every 200us 202 if ( (ADCSRA & (1<<ADIF)) && !adc_measured_all) { 203 adc_current_reading = ADCH; 204 if (adc_readings_since_last_muxing == ADC_READINGS_UNTIL_SETTLED) { 205 adc_values[adc_current_channel] = adc_current_reading; 206 adc_readings_since_last_muxing=0; 207 // note that this channel is ready, now and 208 //adc_output(adc_current_channel, adc_current_reading); 209 // proceed to the next enabled channel. 210 adc_channels_ready[adc_current_channel/8] |= (1<<(adc_current_channel%8)); 211 adc_current_channel = increase_adc (adc_current_channel); 212 Set_V_Muxer(adc_current_channel); 213 _delay_ms(10); 214 } else { // the ADC did not settle yet, we discard the reading 215 ++adc_readings_since_last_muxing; 216 // current reading is not used for anything else 217 } 218 } 219 //---------------------------------------------------------------------------- 220 221 //IF AD7719 ADC just finished a conversion -- every 60ms 222 223 if (AD7719_IS_READY() && !ad7719_measured_all) { 224 ad7719_current_reading = read_adc(); // --takes at 4MHz SCLK speed about 6us 225 // AD7719 is only read out if settled. saves time. 226 if (ad7719_readings_since_last_muxing == AD7719_READINGS_UNTIL_SETTLED) { 227 ad7719_values[ad7719_current_channel] = ad7719_current_reading; 228 ad7719_readings_since_last_muxing=0; 229 if (debug_mode) { 230 usart_write_U32_hex(ad7719_current_reading); 231 usart_write_char('\n'); 232 usart_write_char('\n'); 233 } 234 // now prepare the data to be send away via USART. 235 //ad7719_output(ad7719_current_channel, ad7719_current_reading); 236 // note that this channel is ready, now and 237 // proceed to the next enabled channel. 238 ad7719_channels_ready[ad7719_current_channel/8] |= (1<<(ad7719_current_channel%8)); 239 ad7719_current_channel = increase_ad7719 (ad7719_current_channel); 240 Set_T_Muxer(ad7719_current_channel); 241 } else { // the AD7719 did not settle yet, we discard the reading 242 ++ad7719_readings_since_last_muxing; 243 if (debug_mode) { 244 usart_write_U32_hex(ad7719_current_reading); 245 usart_write_char('\n'); 246 } 247 248 // current reading is not used for anything else 249 } 250 } 251 252 //---------------------------------------------------------------------------- 253 /* 254 if (verbose == true) 255 // talk() was just defined so the 256 // code is not at this place ... look down. 257 talk(); 258 */ 259 260 } // end of MAIN LOOP 261 //----------------------------------------------------------------------------- 262 // E N D E N D E N D E N D E N D E N D E N D 263 //----------------------------------------------------------------------------- 264 265 266 267 float resistance; 268 269 U08 SA_mux_val = 0x00; 270 U08 SB_mux_val = 0x00; 271 272 //U08 counter = 0; 273 U08 Res_or_Volt = 0x00; 274 275 276 while (TRUE) 277 { 278 279 280 ++Res_or_Volt; 281 if (Res_or_Volt <= 64){ 282 283 284 // if USART data arrives. i.e. data via USB 285 // the usart_rx_ready flag is set TRUE 286 // now process the incoming data which is stored in 287 // U08 usart_rx_buffer[USART_RX_BUFFER_SIZE] 288 // and tell the USART interface, it may receive new data 289 // by setting the usart_rx_ready flag FALSE again 290 ++SA_mux_val; 291 if (Res_or_Volt == 1) SB_mux_val = 16; 292 else if (SA_mux_val == 64) SA_mux_val = 32; 293 else if (SA_mux_val == 16) SA_mux_val = 48; 294 else if (SA_mux_val == 32) SA_mux_val = 0; 295 PORTA = (SA_mux_val & 0x3F); 296 297 // usart_write_str((pU08)"SA:"); 298 usart_write_U08(SA_mux_val,2); 299 usart_write_str((pU08)" Sensor:"); 300 usart_write_U08((SA_mux_val % 8)+1,2); 301 usart_write_str((pU08)" an Temperatur_"); 302 switch (SA_mux_val / 8) 303 { 304 case 0: usart_write_str((pU08)"C"); 305 break; 306 case 1: usart_write_str((pU08)"D"); 307 break; 308 case 2: usart_write_str((pU08)"A"); 309 break; 310 case 3: usart_write_str((pU08)"B"); 311 break; 312 case 4: usart_write_str((pU08)"G"); 313 break; 314 case 5: usart_write_str((pU08)"H"); 315 break; 316 case 6: usart_write_str((pU08)"E"); 317 break; 318 case 7: usart_write_str((pU08)"F"); 319 break; 320 default: usart_write_str((pU08)"alarm!"); 321 break; 322 } 323 // usart_write_str((pU08)"\n"); 324 usart_write_str((pU08)" "); 325 326 327 startconv(0); 328 329 330 while (!AD7719_IS_READY()) 331 { 332 // just wait until ADC is redy -- really bad code here! 333 } 334 335 resistance = getresistance(); 336 //Start a new A/D Conversion 337 //temp = readandsendtemp(); 338 //adcword = getadc(); 339 340 //temperature = gettemp(); 341 usart_write_str((pU08)"R:"); 342 usart_write_float(resistance,3,4); 343 usart_write_str((pU08)"kOhm "); 344 345 //_delay_ms(200); 346 347 startconv(0); 348 349 while (!AD7719_IS_READY()) 350 { 351 // just wait until ADC is redy -- really bad code here! 352 } 353 //Start a new A/D Conversion 354 //temp = readandsendtemp(); 355 //adcword = getadc(); 356 resistance = getresistance(); 357 //temperature = gettemp(); 358 usart_write_str((pU08)"R:"); 359 usart_write_float(resistance,3,4); 360 usart_write_str((pU08)"kOhm "); 361 362 //usart_write_str((pU08)"\n"); 363 switch (SA_mux_val) 364 { 365 case 7: usart_write_str((pU08)"\n\n"); 366 break; 367 case 15: usart_write_str((pU08)"\n\n"); 368 break; 369 case 23: usart_write_str((pU08)"\n\n"); 370 break; 371 case 31: usart_write_str((pU08)"\n\n"); 372 break; 373 case 39: usart_write_str((pU08)"\n\n"); 374 break; 375 case 47: usart_write_str((pU08)"\n\n"); 376 break; 377 case 55: usart_write_str((pU08)"\n\n"); 378 break; 379 case 63: usart_write_str((pU08)"\n\n"); 380 break; 381 default: usart_write_str((pU08)"\n"); 382 break; 383 } 384 SB_mux_val = 0; 385 } 386 else if (Res_or_Volt == 148) Res_or_Volt = 0; 387 else { 388 389 390 ++SB_mux_val; 391 if (SB_mux_val == 84) SB_mux_val = 0; 392 else if (SB_mux_val == 74) SB_mux_val = 82; 393 else if (SB_mux_val == 82) SB_mux_val = 72; 394 else if (SB_mux_val == 72) SB_mux_val = 74; 395 else if (SB_mux_val == 48) SB_mux_val = 64; 396 else if (SB_mux_val == 64) SB_mux_val = 32; 397 else if (SB_mux_val == 32) SB_mux_val = 48; 398 PORTC = (SB_mux_val & 0x7F); 399 400 401 402 403 usart_write_str((pU08)"8bit-ADC: "); 404 405 if (SB_mux_val < 64) 406 { 407 switch (SB_mux_val / 16) 408 { 409 case 0: usart_write_str((pU08)"voltage_A: "); 410 break; 411 case 1: usart_write_str((pU08)"voltage_B: "); 412 break; 413 case 2: usart_write_str((pU08)"voltage_D: "); 414 break; 415 case 3: usart_write_str((pU08)"voltage_C: "); 416 break; 417 } 418 419 if (SB_mux_val % 2 == 0) { 420 usart_write_str((pU08)"U"); 421 usart_write_U08( (SB_mux_val%16)/2 , 1 ); 422 } else { 423 usart_write_str((pU08)"I"); 424 usart_write_U08( ((SB_mux_val%16)-1)/2 , 1 ); 425 } 426 427 428 } else { 429 430 431 if (SB_mux_val < 72) { 432 usart_write_str((pU08)"voltage_E: "); 433 if (SB_mux_val % 2 == 0) { 434 usart_write_str((pU08)"U"); 435 usart_write_U08( (SB_mux_val%8)/2 , 1 ); 436 } else { 437 usart_write_str((pU08)"I"); 438 usart_write_U08( ((SB_mux_val%8)-1)/2 , 1 ); 439 } 440 441 } 442 else if (SB_mux_val == 72) usart_write_str((pU08)"humidity_A: H0"); 443 else if (SB_mux_val == 73) usart_write_str((pU08)"humidity_A: H1"); 444 445 else if (SB_mux_val < 82) { 446 usart_write_str((pU08)"voltage_F: "); 447 if (SB_mux_val % 2 == 0) { 448 usart_write_str((pU08)"U"); 449 usart_write_U08( ((SB_mux_val-2)%8)/2 , 1 ); 450 } else { 451 usart_write_str((pU08)"I"); 452 usart_write_U08( (((SB_mux_val-2)%8)-1)/2 , 1 ); 453 } 454 455 } 456 else if (SB_mux_val == 82) usart_write_str((pU08)"humidity_B: H0"); 457 else if (SB_mux_val == 83) usart_write_str((pU08)"humidity_B: H1"); 458 } 459 460 for (U08 counter = 0; counter < 1; ++counter) { 461 while (ADCSRA & (1<<ADSC) ); // wait until internal ADC is ready 462 float voltage; 463 voltage = ( (float)ADCH ) / 256 * 4.096; 464 usart_write_str((pU08)" "); 465 usart_write_float(voltage,3,4); 466 467 468 } 469 //usart_write_str((pU08)"\n"); 470 471 switch (SB_mux_val) 472 { 473 case 15: usart_write_str((pU08)"\n\n"); 474 break; 475 case 31: usart_write_str((pU08)"\n\n"); 476 break; 477 case 47: usart_write_str((pU08)"\n\n"); 478 break; 479 case 63: usart_write_str((pU08)"\n\n"); 480 break; 481 case 71: usart_write_str((pU08)"\n\n"); 482 break; 483 case 73: usart_write_str((pU08)"\n\n"); 484 break; 485 case 81: usart_write_str((pU08)"\n\n"); 486 break; 487 case 83: usart_write_str((pU08)"\n\n"); 488 break; 489 default: usart_write_str((pU08)"\n"); 490 break; 491 } 492 493 SA_mux_val = 15; 494 } 495 /* 496 if ( usart_rx_ready == TRUE ) 497 { 498 //understand what it means and react 499 500 switch (usart_rx_buffer[0]) 501 { 502 503 case 'h': 504 { 505 // toggle the heartbeat mode on or off. 506 heartbeat_enable = !heartbeat_enable; 507 break; 508 } 509 case 'a': 510 { 511 // conduct adc - AD7719 SPI interface test 512 513 break; 514 } 515 case 'e': 516 { 517 // conduct ethernet module SPI interface test 518 strtol((char*) usart_rx_buffer+1, NULL, 0); 519 break; 520 } 521 522 default: 523 { 524 usart_write_str((pU08)"? you wrote: "); 525 usart_write_str((pU08)usart_rx_buffer); 526 usart_write_str((pU08)"\n"); 527 break; 528 } 529 } 530 531 heartbeat_enable = !heartbeat_enable; 532 usart_rx_ready = FALSE; 533 } 534 */ 535 // das ist ein paar schritte zu früh. 536 // erstmal müssen die interfaces getestet werden. 537 /* 538 539 for (U08 i = 0; i<16; i++) 540 { 541 542 if((~PIND) & 0x08) // PD4 is #ADC_RDY input. Inverted logic! if PD4=0 this evaluates to true 543 { 544 PORTA = (PORTA & 0xF0) | ((i) & 0x0F); // switch muxer 545 startconv(); //Start a new A/D Conversion 546 //temp = readandsendtemp(); 547 //adcword = getadc(); 548 //resistance = getresistance(); 549 temperature = gettemp(); 550 usart_write_float(temperature,2,4); 551 usart_write_str((pU08)"\t"); 552 553 } // end of if adc ready 554 else 555 { 556 i--; 557 } 558 } // end of for loop over 16 channels 559 usart_write_crlf(); 560 561 */ 562 563 } // end of infinite while loop 564 } // end of main() 565 566 567 ISR (TIMER2_COMP_vect) 568 { 569 ++local_ms; 570 } 571 572 573 U08 increase_adc (U08 channel){ 574 bool valid_ch_found = false; 575 while (!valid_ch_found){ 576 577 // just increase 'channel' or turnover to zero. 578 ++channel; 579 if (channel == V_CHANNELS + I_CHANNELS + H_CHANNELS) 580 channel = 0; 581 582 // check if this channel is enabled in the bitmap 583 if (adc_enables[channel/8] & (1<<channel%8)) 584 valid_ch_found = true; 585 } // end of while loop 586 return channel; 587 } // end if increase_adc; 588 589 U08 increase_ad7719 (U08 channel){ 590 bool valid_ch_found = false; 591 while (!valid_ch_found){ 592 593 // just increase 'channel' or turnover to zero. 594 ++channel; 595 if (channel == TEMP_CHANNELS) 596 channel = 0; 597 598 // check if this channel is enabled in the bitmap 599 if (ad7719_enables[channel/8] & (1<<channel%8)) 600 valid_ch_found = true; 601 } // end of while loop 602 return channel; 603 } // end if increase_adc; 604 605 606 // Sets voltage Muxer to current channel 607 // this is a Muxing, and therefor the adc might need some time to settle. 608 // Since there are: 609 // - 40 voltage monitor channels 610 // - 40 current monitor channels 611 // - 4 humidity monitor channels 612 // the muxer is set as follows. 613 // channel 00..39 --> looking at the voltage channels 614 // channel 40..79 --> looking at the current channels 615 // channel 80..83 --> looking at the humidities 616 void Set_V_Muxer (U08 channel){ 617 U08 SB = 0; 618 // voltages 619 if (channel < 40) { 620 if (channel < 36) 621 SB = channel*2; 622 else 623 SB = (channel+1)*2; 624 } 625 // currents 626 else if (channel < 80) { 627 channel -= 40; 628 if (channel < 36) 629 SB = channel*2+1; 630 else 631 SB = (channel+1)*2+1; 632 } 633 // humidities 634 else if (channel < 84) { 635 channel -= 80; 636 switch (channel) { 637 case 0: 638 SB = 0x48; //0100.1000 639 break; 640 case 1: 641 SB = 0x49; //0100.1001 642 break; 643 case 2: 644 SB = 0x58; //0101.0010 645 break; 646 case 3: 647 SB = 0x58; //0101.0011 648 break; 649 } // end of switch-case 650 } // end of if (channel < some_number) 651 652 PORTC = (PORTC & 0x80) | (0x7F & SB); // Here the muxer is switched. 653 } 654 655 void Set_T_Muxer(U08 channel) { 656 U08 SA = 0x00; 657 658 switch (channel/16) { 659 case 0: 660 SA |= 1<<4; // 0001.0000 661 break; 662 case 1: 663 break; // 0000.0000 664 case 2: 665 SA |= (1<<4)|(1<<5); // 0011.0000 666 break; 667 case 3: 668 SA |= 1<<5; // 0010.0000 669 break; 670 } 671 672 SA = SA | (channel%16); 673 674 PORTA = (PORTA & 0xC0) | (0x3F & SA); // Here the muxer is switched. 675 } 676 677 void talk(void){ 678 679 /* 680 // makes no sense to declare the 'new_measurement' vars here 681 // but maybe the whole function will be deleted, anyway ... 682 // I'm thinking about it. 683 bool ad7719_new_measurement; 684 bool atmega_adc_new_measurement; 685 if (verbose == true) { 686 // somebody wants to read every new measured value, even if it is trash! 687 // do not actually send away data ! 688 // just prepare the data to be send away. 689 if ( ad7719_new_measurement == true ) { 690 add_str_to_output_stream("ad7719: reading:"); 691 add_dec_to_output_stream(reading_since_last_muxer_switch,1); 692 add_str_to_output_stream(" temperature channel:"); 693 add_dec_to_output_stream(current_temperature_channel,2); 694 add_str_to_output_stream(" = "); 695 add_float_to_output_stream(current_ad7719_value,4,3); 696 add_str_to_output_stream("\n"); 697 } 698 if (atmega_adc_new_measurement == true) { 699 add_str_to_output_stream("atmega_adc: reading:"); 700 add_dec_to_output_stream(reading_since_last_muxer_switch,1); 701 add_str_to_output_stream(" voltage channel:"); 702 add_dec_to_output_stream(current_voltage_channel,2); 703 add_str_to_output_stream(" = "); 704 add_float_to_output_stream(current_atmega_adc_value,4,3); 705 add_str_to_output_stream("\n"); 706 } 707 } // end of: if verbose 708 */ 709 } // end of talk() 710 711 // this function generates some output. 712 void ad7719_output(U08 channel, U32 data) { 713 float value = 0; 714 usart_write_str((pU08)"R:"); //R for resistance 715 usart_write_char('A'+channel/8); // Letters A,B,C,D,E,F,G,H 716 //usart_write_char(' '); 717 usart_write_U08(channel%8+1,1); // Numbers 1...8 718 usart_write_char(':'); 719 720 721 value = (6.25 * data) / ((U32)1 << 25); 722 usart_write_float(value, 3,6); 723 //usart_write_U32_hex(data); //data 724 725 726 } 727 728 void adc_output(U08 channel, U08 data) { 729 730 // if (channel < 40) 731 // usart_write_str((pU08)"V:"); 732 // else if (channel < 80) 733 // usart_write_str((pU08)"I:"); 734 // else if (channel < 84) 735 // usart_write_str((pU08)"H:"); 736 737 if (channel <80) 738 { 739 switch ((channel%40)/4) { 740 case 0: 741 case 1: 742 usart_write_char('A'); 743 break; 744 case 2: 745 case 3: 746 usart_write_char('B'); 747 break; 748 case 4: 749 case 5: 750 usart_write_char('C'); 751 break; 752 case 6: 753 case 7: 754 usart_write_char('D'); 755 break; 756 case 8: 757 usart_write_char('E'); 758 break; 759 case 9: 760 usart_write_char('F'); 761 break; 762 default: 763 usart_write_char('?'); 764 break; 765 } 766 } 767 else // channel 80..83 768 { 769 usart_write_char('H'); 770 } 771 //usart_write_char(' '); 772 773 if ( (channel%40)/4 == 9) 774 usart_write_U08((channel)%4+1,1); // Numbers 1...4 775 else 776 usart_write_U08((channel)%8+1,1); // Numbers 1...8 777 778 779 //usart_write_U08(channel,2); // Numbers 1...8 780 usart_write_char(':'); 781 usart_write_U16((U16)data*16, 4); //data 782 } 783 784 785 void adc_output_all() { 786 print_adc_nicely(); 787 print_ad7719_nicely(); 788 } 789 790 791 // this method parses the data, 792 // which came in via USART 793 // later it might as well parse the data from ethernet. 794 void parse() { 795 U08 command = usart_rx_buffer[0]; 796 // look at first byte 797 // I hope, I can manage to use one byte commands 798 usart_rx_buffer[USART_RX_BUFFER_SIZE-1] = 0; 799 usart_write_str((pU08)"got:"); 800 usart_write_str(usart_rx_buffer); 801 802 803 804 switch (command) { 805 case 'E': // AD7719 enable bitmaps may be set 806 usart_write_str((pU08)"\n set enable bits of AD7719 Port "); 807 if ((usart_rx_buffer_index>=5) && 808 (usart_rx_buffer[2] >= 'A' && usart_rx_buffer[2] <= 'H')) 809 { 810 usart_write_char(usart_rx_buffer[2]); 811 usart_write_str((pU08)" to "); 812 usart_write_U08_hex(usart_rx_buffer[4]); 813 usart_write_char('\n'); 814 ad7719_enables[usart_rx_buffer[2]-'A']=usart_rx_buffer[4]; 815 ad7719_channels_ready[usart_rx_buffer[2]-'A']=0x00; 816 } 817 else if ((usart_rx_buffer_index=3) && 818 (usart_rx_buffer[1] >= 'A' && usart_rx_buffer[1] <= 'H')) 819 { 820 usart_write_char(usart_rx_buffer[1]); 821 if (usart_rx_buffer[2]!='0') { 822 usart_write_str((pU08)" to 0xFF\n"); 823 ad7719_enables[usart_rx_buffer[1]-'A']=0xFF; 824 } else 825 { 826 usart_write_str((pU08)" to 0x00\n"); 827 ad7719_enables[usart_rx_buffer[1]-'A']=0x00; 828 } 829 ad7719_channels_ready[usart_rx_buffer[1]-'A']=0x00; 830 } 831 else 832 { 833 usart_write_str((pU08)"\n something wrong\n"); 834 usart_write_str((pU08)"usart_rx_buffer_index: "); 835 usart_write_U08(usart_rx_buffer_index, 3); 836 usart_write_str((pU08)"\n usart_rx_buffer[2]: "); 837 usart_write_char(usart_rx_buffer[2]); 838 usart_write_str((pU08)"\n usart_rx_buffer[4]: "); 839 usart_write_U08_hex(usart_rx_buffer[4]); 840 usart_write_char('\n'); 841 } 842 break; 843 case 'e': // ATmega internal ADC enable bitmaps may be set 844 usart_write_str((pU08)"\n setting ADC enable registers all"); 845 if (usart_rx_buffer[1] == '0'){ 846 usart_write_str((pU08)"OFF \n"); 847 for ( U08 i=0; i<V_BITMAP + I_BITMAP; ++i ) { 848 adc_enables[i]=0x00; 849 adc_channels_ready[i]=0; 850 } 851 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP -1] = 0x00; 852 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP -1]=0; 853 } else { 854 usart_write_str((pU08)"ON\n"); 855 for ( U08 i=0; i<V_BITMAP + I_BITMAP; ++i ) { 856 adc_enables[i]=0xFF; 857 adc_channels_ready[i]=0; 858 } 859 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP -1] = 0x0F; 860 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP -1]=0; 861 } 862 863 864 break; 865 case 'h': 866 usart_write_str((pU08)"\nheartbeat "); 867 heartbeat_enable = true; 868 if (usart_rx_buffer[1] == '0'){ 869 heartbeat_enable = false; 870 usart_write_str((pU08)"off\n"); 871 } else { 872 usart_write_str((pU08)"on\n"); 873 } 874 break; 875 case 'G': // GET the Temperature channels, which are enabled 876 once_told_you = false; 877 for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) { 878 ad7719_channels_ready[i]=0; 879 } 880 break; 881 case 'g': // GET the voltage/current/humidity channels, which are enabled 882 once_told_you = false; 883 for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) { 884 adc_channels_ready[i]=0; 885 } 886 break; 887 888 case 'Q': 889 for (U08 i=0; i< TEMP_CHANNELS;++i) { 890 if (i%8 == 0) usart_write_char('\n'); 891 usart_write_U32_hex(ad7719_values[i]); 892 usart_write_char('\t'); 893 } 894 usart_write_char('\n'); 895 break; 896 897 case 'q': 898 // output: U08 adc_values[V_CHANNELS + I_CHANNELS + H_CHANNELS]; 899 for (U08 i=0; i< V_CHANNELS + I_CHANNELS + H_CHANNELS;++i) { 900 if (i%8 == 0) usart_write_char('\n'); 901 usart_write_U16(adc_values[i]*16, 5); 902 usart_write_char('\t'); 903 } 904 usart_write_char('\n'); 905 break; 906 907 case 'P': 908 print_ad7719_nicely(); 909 break; 910 911 case 'p': 912 print_adc_nicely(); 913 break; 914 915 case 'T': 916 print_temp_nicely(); 917 break; 918 919 920 case 's': 921 922 usart_write_str((pU08)"adc status:\n"); 923 for (U08 i=0; i< V_BITMAP + I_BITMAP + H_BITMAP;++i) { 924 usart_write_U08_bin(adc_enables[i]); 925 usart_write_char(' '); 926 } 927 usart_write_char('\n'); 928 for (U08 i=0; i< V_BITMAP + I_BITMAP + H_BITMAP;++i){ 929 usart_write_U08_bin(adc_channels_ready[i]); 930 usart_write_char(' '); 931 } 932 usart_write_char('\n'); 933 934 usart_write_str((pU08)"ad7719 status:\n"); 935 for (U08 i=0; i< CHANNEL_BITMAP;++i) { 936 usart_write_U08_bin(ad7719_enables[i]); 937 usart_write_char(' '); 938 } 939 usart_write_char('\n'); 940 for (U08 i=0; i< CHANNEL_BITMAP;++i){ 941 usart_write_U08_bin(ad7719_channels_ready[i]); 942 usart_write_char(' '); 943 } 944 usart_write_char('\n'); 945 946 usart_write_str((pU08)"time:"); 947 usart_write_float((float)local_ms/1000 , 1,7); 948 usart_write_str((pU08)" sec.\n"); 949 950 usart_write_str((pU08)"adc measured all: "); 951 if (adc_measured_all) 952 usart_write_str((pU08)" true\n"); 953 else 954 usart_write_str((pU08)"false\n"); 955 956 usart_write_str((pU08)"ad7719 measured all: "); 957 if (ad7719_measured_all) 958 usart_write_str((pU08)" true\n"); 959 else 960 usart_write_str((pU08)"false\n"); 961 962 usart_write_str((pU08)"adc current channel:"); 963 usart_write_U08(adc_current_channel,2); 964 usart_write_char('\n'); 965 966 usart_write_str((pU08)"ad7719 current channel:"); 967 usart_write_U08(ad7719_current_channel,2); 968 usart_write_char('\n'); 969 break; 970 971 case 'd': 972 usart_write_str((pU08)"\ndebug mode "); 973 debug_mode = true; 974 if (usart_rx_buffer[1] == '0'){ 975 debug_mode = false; 976 usart_write_str((pU08)"off\n"); 977 } else { 978 usart_write_str((pU08)"on\n"); 979 } 980 break; 981 } 982 983 984 usart_write_str((pU08)"\nready?"); 985 for (U08 i=0; i<USART_RX_BUFFER_SIZE; ++i) 986 usart_rx_buffer[i] = 0; 987 } 988 989 void check_if_measured_all() { 990 adc_measured_all = true; 991 for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) { 992 if ((adc_enables[i] ^ adc_channels_ready[i]) != 0x00) { 993 adc_measured_all = false; 994 break; 995 } 996 } 997 ad7719_measured_all = true; 998 for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) { 999 if ((ad7719_enables[i] ^ ad7719_channels_ready[i]) != 0x00) { 1000 ad7719_measured_all = false; 1001 break; 1002 } 1003 } 1004 1005 1006 } 1007 1008 void print_ad7719_nicely() 1009 { 1010 float value; 1011 1012 usart_write_str((pU08)"\n printing measured resistance in kohms:\n"); 1013 1014 for (U08 i=0; i< TEMP_CHANNELS;++i) { 1015 if (i%8 == 0) usart_write_char('\n'); 1016 1017 // print channel name: 1018 usart_write_str((pU08)"R:"); //R for resistance 1019 usart_write_char('A'+i/8); // Letters A,B,C,D,E,F,G,H 1020 //usart_write_char(' '); 1021 usart_write_U08(i%8+1,1); // Numbers 1...8 1022 usart_write_char(':'); 1023 1024 // check if this channel is enabled in the bitmap 1025 if (ad7719_enables[i/8] & (1<<i%8)) 1026 { 1027 value = (6.25 * 1.024 * ad7719_values[i]) / ((U32)1 << 25); 1028 usart_write_float(value, 3,6); 1029 //usart_write_U32(ad7719_values[i],8); 1030 //usart_write_U32_hex(data); //data 1031 usart_write_str((pU08)" "); 1032 } else { 1033 usart_write_str((pU08)" "); 1034 } 1035 //usart_write_char('\n'); 1036 } 1037 } 1038 1039 void print_adc_nicely() { 1040 usart_write_str((pU08)"\n printing voltages in mV:\n"); 1041 // output: U08 adc_values[V_CHANNELS + I_CHANNELS + H_CHANNELS]; 1042 for (U08 i=0; i< V_CHANNELS + I_CHANNELS + H_CHANNELS;++i) { 1043 if (i%8 == 0) usart_write_char('\n'); 1044 1045 if (i==0) 1046 usart_write_str((pU08)"voltages:\n"); 1047 if (i==40) 1048 usart_write_str((pU08)"currents in mV :-) :\n"); 1049 if (i==80) 1050 usart_write_str((pU08)"humiditiesin mV :-) :\n"); 1051 1052 1053 1054 adc_output(i, adc_values[i]); 1055 usart_write_str((pU08)" "); 1056 } 1057 usart_write_char('\n'); 1058 } 1059 1060 1061 void print_temp_nicely() 1062 { 1063 float temp; 1064 1065 usart_write_str((pU08)"\n printing measured temperature in °C:\n"); 1066 1067 for (U08 i=0; i< TEMP_CHANNELS;++i) { 1068 if (i%8 == 0) usart_write_char('\n'); 1069 1070 // print channel name: 1071 usart_write_str((pU08)"T:"); //R for resistance 1072 usart_write_char('A'+i/8); // Letters A,B,C,D,E,F,G,H 1073 //usart_write_char(' '); 1074 usart_write_U08(i%8+1,1); // Numbers 1...8 1075 usart_write_char(':'); 1076 1077 // check if this channel is enabled in the bitmap 1078 if (ad7719_enables[i/8] & (1<<i%8)) 1079 { 1080 temp = calc_temp(ad7719_values[i]); 1081 usart_write_float(temp, 3,6); 1082 //usart_write_U32(ad7719_values[i],8); 1083 //usart_write_U32_hex(data); //data 1084 usart_write_str((pU08)" "); 1085 } else { 1086 usart_write_str((pU08)" "); 1087 } 1088 //usart_write_char('\n'); 1089 } 1090 } 128 } // end of main while loop 129 } // end of main function
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