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source: firmware/FSC/src/FSC_old.c@ 12679

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Last change on this file since 12679 was 10667, checked in by neise, 14 years ago

File size: 22.8 KB

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1	//-----------------------------------------------------------------------------
2	#include "typedefs.h"
3	#include "application.h"
4	#include "spi_master.h"
5	#include "ad7719_adc.h"
6	#include "atmega_adc.h"
7	#include "usart.h"
8	#include "macros.h"
9	#include "interpol.h"
10	#include "w5100_spi_interface.h"
11	#include <avr/interrupt.h>
12	#include <avr/wdt.h>
13	#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 moment
27	void check_if_measured_all() ;
28	// end of function definition:
29	//-----------------------------------------------------------------------------
30
31	// MAIN WORKFLOW GLOBAL VARIABLES
32	bool verbose;
33	bool heartbeat_enable;
34
35	// USART global variables
36	U08 usart_rx_buffer[USART_RX_BUFFER_SIZE];
37	U08 usart_tx_buffer[USART_TX_BUFFER_SIZE];
38	U08 usart_rx_buffer_index = 0;
39	U08 usart_tx_buffer_index = 0;
40	U08 usart_last_char; // last received char
41
42	// USART FLAGS
43	bool usart_tx_buffer_overflow = false; // true if usart_tx_buffer was full.
44	bool usart_rx_ready = false; // EOL was received, parser needs to be called
45
46	// TIMER global variable
47	volatile U32 local_ms = 0;
48
49	// AD7719 global variables
50	#define TEMP_CHANNELS 64
51	#define CHANNEL_BITMAP 8
52	#define AD7719_READINGS_UNTIL_SETTLED 1 // bei3:480ms
53	U32 ad7719_values[TEMP_CHANNELS];
54	U08 ad7719_enables[CHANNEL_BITMAP];
55	U08 ad7719_channels_ready[CHANNEL_BITMAP];
56	U08 ad7719_readings_since_last_muxing = 0;
57	U08 ad7719_current_channel = 0;
58	U32 ad7719_current_reading = 0;
59	bool ad7719_measured_all = false;
60
61	// ATMEGA ADC global variables
62	#define V_CHANNELS 40
63	#define I_CHANNELS 40
64	#define H_CHANNELS 4
65	#define V_BITMAP 5
66	#define I_BITMAP 5
67	#define H_BITMAP 1
68	#define ADC_READINGS_UNTIL_SETTLED 1
69	U32 adc_values[V_CHANNELS + I_CHANNELS + H_CHANNELS]; // stores measured voltage in steps of 16mV
70	U08 adc_enables[V_BITMAP + I_BITMAP + H_BITMAP];
71	U08 adc_channels_ready[V_BITMAP + I_BITMAP + H_BITMAP];
72	U08 adc_readings_since_last_muxing = 0;
73	U08 adc_current_channel = 0;
74	U08 adc_current_reading = 0;
75	bool adc_measured_all = false;
76
77	//-----------------------------------------------------------------------------
78	// M A I N --- M A I N --- M A I N --- M A I N --- M A I N
79	//-----------------------------------------------------------------------------
80	int main(void)
81	{
82	app_init(); // Setup: Watchdog and I/Os
83	usart_init(); // Initialize serial interface
84	spi_init(); // Initialize SPI interface as master
85	ad7719_init(); // Initialize AD7719 ADC as SPI slave
86	atmega_adc_init();
87
88	// TIMER2 is used as local clock:
89	// configure timer 2
90	TCCR2 = (1<<WGM21); // CTC Modus
91	TCCR2 \|= (1<<CS21) \| (1<<CS20); // Prescaler 64 --> counts up every 8us
92	OCR2 = 125-1; // --> output compare interrupt occurs every 125 x 8us = 1ms
93	// Compare Interrupt erlauben
94	TIMSK \|= (1<<OCIE2);
95
96	// Enable interrupts
97	sei();
98
99	for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) {
100	ad7719_enables[i]=0xFF;
101	ad7719_channels_ready[i]=0;
102	}
103	for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) {
104	adc_enables[i]=0xFF;
105	adc_channels_ready[i]=0;
106	}
107	static U08 welcome[]="\n\nwelcome to FACT FSC commandline interface v0.1\nready?";
108	usart_write_str(welcome);
109
110
111	//MAIN LOOP
112	while (1)
113	{
114	if (heartbeat_enable) PORTB ^= (1<<PB3); // toggle Out2_spare --> heartbeat
115	//----------------------------------------------------------------------------
116	//IF we need to send away one byte, and ready to send
117
118	if ( (usart_tx_buffer_index > 0) && (UCSRA & (1<<UDRE)) ) {
119	UDR = usart_tx_buffer[0];
120	// THis is shit
121	for (U08 i=0 ; i < USART_TX_BUFFER_SIZE; ++i) {
122	usart_tx_buffer[i] = usart_tx_buffer[i+1];
123	}
124	usart_tx_buffer_index--;
125	}
126	//----------------------------------------------------------------------------
127
128	//IF we just received one byte, and there is enough space in the RX_buffer
129	if ( (UCSRA & (1<<RXC)) && (usart_rx_buffer_index < USART_RX_BUFFER_SIZE) ){
130	usart_last_char = UDR;
131	if (usart_last_char == '\n'){ // if EOL was received
132	usart_rx_ready = true;
133	}else {
134	usart_rx_buffer[usart_rx_buffer_index] = usart_last_char;
135	usart_rx_buffer_index++;
136	}
137	// here is still something strange .... better send an enter automatically
138	} else if (UCSRA & (1<<RXC)) { // if there is no scace in the buffer; read anyway.
139	usart_last_char = UDR;
140	usart_rx_buffer_index =0;
141	}
142	//----------------------------------------------------------------------------
143
144	//IF USART DOR bit is set, PC is sending data to fast!!!
145	if ( UCSRA & (1<<DOR) ){
146	// flush TX_buffer and write warning message in
147	// maybe even switch off every measurement. ?
148	}
149	//----------------------------------------------------------------------------
150
151	//IF TX_BUFFER was overrun.
152	if (usart_tx_buffer_overflow) {
153	// flash TX_buffer and write warning message in
154	// maybe even switch off every measurement. ?
155	//
156	// this should only happen, in verbose mode and with low baudrates.
157	}
158	//----------------------------------------------------------------------------
159
160	//IF one command was received.
161	// -It is not allowed to send more than one command between two '\n'
162	if (usart_rx_ready){
163	parse();
164	usart_rx_buffer_index = 0;
165	usart_rx_ready = false;
166	}
167	//----------------------------------------------------------------------------
168
169	//IF ATmega internal ADC did finish a conversion --every 200us
170	if ( (ADCSRA & (1<<ADIF)) && !adc_measured_all) {
171	adc_current_reading = ADCH;
172	if (adc_readings_since_last_muxing == ADC_READINGS_UNTIL_SETTLED) {
173	adc_values[adc_current_channel] = adc_current_reading;
174	adc_readings_since_last_muxing=0;
175	// note that this channel is ready, now and
176	adc_output(adc_current_channel, adc_current_reading);
177	// proceed to the next enabled channel.
178	adc_channels_ready[adc_current_channel/8] \|= (1<<(adc_current_channel%8));
179	adc_current_channel = increase_adc (adc_current_channel);
180	Set_V_Muxer(adc_current_channel);
181	} else { // the ADC did not settle yet, we discard the reading
182	++adc_readings_since_last_muxing;
183	// current reading is not used for anything else
184	}
185	}
186	//----------------------------------------------------------------------------
187
188	//IF AD7719 ADC just finished a conversion -- every 60ms
189
190	if (AD7719_IS_READY()) {
191	ad7719_current_reading = read_adc(); // --takes at 4MHz SCLK speed about 6us
192	// AD7719 is only read out if settled. saves time.
193	if (ad7719_readings_since_last_muxing == AD7719_READINGS_UNTIL_SETTLED) {
194	ad7719_values[ad7719_current_channel] = ad7719_current_reading;
195	ad7719_readings_since_last_muxing=0;
196	// now prepare the data to be send away via USART.
197	//ad7719_output(ad7719_current_channel, ad7719_current_reading);
198	// note that this channel is ready, now and
199	// proceed to the next enabled channel.
200	ad7719_channels_ready[ad7719_current_channel/8] \|= (1<<(ad7719_current_channel%8));
201	ad7719_current_channel = increase_ad7719 (ad7719_current_channel);
202	Set_T_Muxer(ad7719_current_channel);
203	} else { // the AD7719 did not settle yet, we discard the reading
204	++ad7719_readings_since_last_muxing;
205
206	// current reading is not used for anything else
207	}
208	}
209	//----------------------------------------------------------------------------
210	//IF one of the ADC measured all channels, we wanted to know.
211	check_if_measured_all();
212
213	if (ad7719_measured_all && adc_measured_all)
214	adc_output_all();
215
216	//----------------------------------------------------------------------------
217	/*
218	if (verbose == true)
219	// talk() was just defined so the
220	// code is not at this place ... look down.
221	talk();
222	*/
223
224	} // end of MAIN LOOP
225
226	//-----------------------------------------------------------------------------
227	// E N D E N D E N D E N D E N D E N D E N D
228	//-----------------------------------------------------------------------------
229
230
231
232	float resistance;
233
234	U08 SA_mux_val = 0x00;
235	U08 SB_mux_val = 0x00;
236
237	//U08 counter = 0;
238	U08 Res_or_Volt = 0x00;
239
240
241	while (TRUE)
242	{
243
244
245	++Res_or_Volt;
246	if (Res_or_Volt <= 64){
247
248
249	// if USART data arrives. i.e. data via USB
250	// the usart_rx_ready flag is set TRUE
251	// now process the incoming data which is stored in
252	// U08 usart_rx_buffer[USART_RX_BUFFER_SIZE]
253	// and tell the USART interface, it may receive new data
254	// by setting the usart_rx_ready flag FALSE again
255	++SA_mux_val;
256	if (Res_or_Volt == 1) SB_mux_val = 16;
257	else if (SA_mux_val == 64) SA_mux_val = 32;
258	else if (SA_mux_val == 16) SA_mux_val = 48;
259	else if (SA_mux_val == 32) SA_mux_val = 0;
260	PORTA = (SA_mux_val & 0x3F);
261
262	// usart_write_str((pU08)"SA:");
263	usart_write_U08(SA_mux_val,2);
264	usart_write_str((pU08)" Sensor:");
265	usart_write_U08((SA_mux_val % 8)+1,2);
266	usart_write_str((pU08)" an Temperatur_");
267	switch (SA_mux_val / 8)
268	{
269	case 0: usart_write_str((pU08)"C");
270	break;
271	case 1: usart_write_str((pU08)"D");
272	break;
273	case 2: usart_write_str((pU08)"A");
274	break;
275	case 3: usart_write_str((pU08)"B");
276	break;
277	case 4: usart_write_str((pU08)"G");
278	break;
279	case 5: usart_write_str((pU08)"H");
280	break;
281	case 6: usart_write_str((pU08)"E");
282	break;
283	case 7: usart_write_str((pU08)"F");
284	break;
285	default: usart_write_str((pU08)"alarm!");
286	break;
287	}
288	// usart_write_str((pU08)"\n");
289	usart_write_str((pU08)" ");
290
291
292	startconv(0);
293
294
295	while (!AD7719_IS_READY())
296	{
297	// just wait until ADC is redy -- really bad code here!
298	}
299
300	resistance = getresistance();
301	//Start a new A/D Conversion
302	//temp = readandsendtemp();
303	//adcword = getadc();
304
305	//temperature = gettemp();
306	usart_write_str((pU08)"R:");
307	usart_write_float(resistance,3,4);
308	usart_write_str((pU08)"kOhm ");
309
310	//_delay_ms(200);
311
312	startconv(0);
313
314	while (!AD7719_IS_READY())
315	{
316	// just wait until ADC is redy -- really bad code here!
317	}
318	//Start a new A/D Conversion
319	//temp = readandsendtemp();
320	//adcword = getadc();
321	resistance = getresistance();
322	//temperature = gettemp();
323	usart_write_str((pU08)"R:");
324	usart_write_float(resistance,3,4);
325	usart_write_str((pU08)"kOhm ");
326
327	//usart_write_str((pU08)"\n");
328	switch (SA_mux_val)
329	{
330	case 7: usart_write_str((pU08)"\n\n");
331	break;
332	case 15: usart_write_str((pU08)"\n\n");
333	break;
334	case 23: usart_write_str((pU08)"\n\n");
335	break;
336	case 31: usart_write_str((pU08)"\n\n");
337	break;
338	case 39: usart_write_str((pU08)"\n\n");
339	break;
340	case 47: usart_write_str((pU08)"\n\n");
341	break;
342	case 55: usart_write_str((pU08)"\n\n");
343	break;
344	case 63: usart_write_str((pU08)"\n\n");
345	break;
346	default: usart_write_str((pU08)"\n");
347	break;
348	}
349	SB_mux_val = 0;
350	}
351	else if (Res_or_Volt == 148) Res_or_Volt = 0;
352	else {
353
354
355	++SB_mux_val;
356	if (SB_mux_val == 84) SB_mux_val = 0;
357	else if (SB_mux_val == 74) SB_mux_val = 82;
358	else if (SB_mux_val == 82) SB_mux_val = 72;
359	else if (SB_mux_val == 72) SB_mux_val = 74;
360	else if (SB_mux_val == 48) SB_mux_val = 64;
361	else if (SB_mux_val == 64) SB_mux_val = 32;
362	else if (SB_mux_val == 32) SB_mux_val = 48;
363	PORTC = (SB_mux_val & 0x7F);
364
365
366
367
368	usart_write_str((pU08)"8bit-ADC: ");
369
370	if (SB_mux_val < 64)
371	{
372	switch (SB_mux_val / 16)
373	{
374	case 0: usart_write_str((pU08)"voltage_A: ");
375	break;
376	case 1: usart_write_str((pU08)"voltage_B: ");
377	break;
378	case 2: usart_write_str((pU08)"voltage_D: ");
379	break;
380	case 3: usart_write_str((pU08)"voltage_C: ");
381	break;
382	}
383
384	if (SB_mux_val % 2 == 0) {
385	usart_write_str((pU08)"U");
386	usart_write_U08( (SB_mux_val%16)/2 , 1 );
387	} else {
388	usart_write_str((pU08)"I");
389	usart_write_U08( ((SB_mux_val%16)-1)/2 , 1 );
390	}
391
392
393	} else {
394
395
396	if (SB_mux_val < 72) {
397	usart_write_str((pU08)"voltage_E: ");
398	if (SB_mux_val % 2 == 0) {
399	usart_write_str((pU08)"U");
400	usart_write_U08( (SB_mux_val%8)/2 , 1 );
401	} else {
402	usart_write_str((pU08)"I");
403	usart_write_U08( ((SB_mux_val%8)-1)/2 , 1 );
404	}
405
406	}
407	else if (SB_mux_val == 72) usart_write_str((pU08)"humidity_A: H0");
408	else if (SB_mux_val == 73) usart_write_str((pU08)"humidity_A: H1");
409
410	else if (SB_mux_val < 82) {
411	usart_write_str((pU08)"voltage_F: ");
412	if (SB_mux_val % 2 == 0) {
413	usart_write_str((pU08)"U");
414	usart_write_U08( ((SB_mux_val-2)%8)/2 , 1 );
415	} else {
416	usart_write_str((pU08)"I");
417	usart_write_U08( (((SB_mux_val-2)%8)-1)/2 , 1 );
418	}
419
420	}
421	else if (SB_mux_val == 82) usart_write_str((pU08)"humidity_B: H0");
422	else if (SB_mux_val == 83) usart_write_str((pU08)"humidity_B: H1");
423	}
424
425	for (U08 counter = 0; counter < 1; ++counter) {
426	while (ADCSRA & (1<<ADSC) ); // wait until internal ADC is ready
427	float voltage;
428	voltage = ( (float)ADCH ) / 256 * 4.096;
429	usart_write_str((pU08)" ");
430	usart_write_float(voltage,3,4);
431
432
433	}
434	//usart_write_str((pU08)"\n");
435
436	switch (SB_mux_val)
437	{
438	case 15: usart_write_str((pU08)"\n\n");
439	break;
440	case 31: usart_write_str((pU08)"\n\n");
441	break;
442	case 47: usart_write_str((pU08)"\n\n");
443	break;
444	case 63: usart_write_str((pU08)"\n\n");
445	break;
446	case 71: usart_write_str((pU08)"\n\n");
447	break;
448	case 73: usart_write_str((pU08)"\n\n");
449	break;
450	case 81: usart_write_str((pU08)"\n\n");
451	break;
452	case 83: usart_write_str((pU08)"\n\n");
453	break;
454	default: usart_write_str((pU08)"\n");
455	break;
456	}
457
458	SA_mux_val = 15;
459	}
460	/*
461	if ( usart_rx_ready == TRUE )
462	{
463	//understand what it means and react
464
465	switch (usart_rx_buffer[0])
466	{
467
468	case 'h':
469	{
470	// toggle the heartbeat mode on or off.
471	heartbeat_enable = !heartbeat_enable;
472	break;
473	}
474	case 'a':
475	{
476	// conduct adc - AD7719 SPI interface test
477
478	break;
479	}
480	case 'e':
481	{
482	// conduct ethernet module SPI interface test
483	strtol((char*) usart_rx_buffer+1, NULL, 0);
484	break;
485	}
486
487	default:
488	{
489	usart_write_str((pU08)"? you wrote: ");
490	usart_write_str((pU08)usart_rx_buffer);
491	usart_write_str((pU08)"\n");
492	break;
493	}
494	}
495
496	heartbeat_enable = !heartbeat_enable;
497	usart_rx_ready = FALSE;
498	}
499	*/
500	// das ist ein paar schritte zu früh.
501	// erstmal müssen die interfaces getestet werden.
502	/*
503
504	for (U08 i = 0; i<16; i++)
505	{
506
507	if((~PIND) & 0x08) // PD4 is #ADC_RDY input. Inverted logic! if PD4=0 this evaluates to true
508	{
509	PORTA = (PORTA & 0xF0) \| ((i) & 0x0F); // switch muxer
510	startconv(); //Start a new A/D Conversion
511	//temp = readandsendtemp();
512	//adcword = getadc();
513	//resistance = getresistance();
514	temperature = gettemp();
515	usart_write_float(temperature,2,4);
516	usart_write_str((pU08)"\t");
517
518	} // end of if adc ready
519	else
520	{
521	i--;
522	}
523	} // end of for loop over 16 channels
524	usart_write_crlf();
525
526	*/
527
528	} // end of infinite while loop
529	} // end of main()
530
531
532	ISR (TIMER2_COMP_vect)
533	{
534	++local_ms;
535	}
536
537
538	U08 increase_adc (U08 channel){
539	bool valid_ch_found = false;
540	while (!valid_ch_found){
541
542	// just increase 'channel' or turnover to zero.
543	++channel;
544	if (channel == V_CHANNELS + I_CHANNELS + H_CHANNELS)
545	channel = 0;
546
547	// check if this channel is enabled in the bitmap
548	if (adc_enables[channel/8] & (1<<channel%8))
549	valid_ch_found = true;
550	} // end of while loop
551	return channel;
552	} // end if increase_adc;
553
554	U08 increase_ad7719 (U08 channel){
555	bool valid_ch_found = false;
556	while (!valid_ch_found){
557
558	// just increase 'channel' or turnover to zero.
559	++channel;
560	if (channel == TEMP_CHANNELS)
561	channel = 0;
562
563	// check if this channel is enabled in the bitmap
564	if (ad7719_enables[channel/8] & (1<<channel%8))
565	valid_ch_found = true;
566	} // end of while loop
567	return channel;
568	} // end if increase_adc;
569
570
571	// Sets voltage Muxer to current channel
572	// this is a Muxing, and therefor the adc might need some time to settle.
573	// Since there are:
574	// - 40 voltage monitor channels
575	// - 40 current monitor channels
576	// - 4 humidity monitor channels
577	// the muxer is set as follows.
578	// channel 00..39 --> looking at the voltage channels
579	// channel 40..79 --> looking at the current channels
580	// channel 80..83 --> looking at the humidities
581	void Set_V_Muxer (U08 channel){
582	U08 SB = 0;
583	// voltages
584	if (channel < 40) {
585	if (channel < 36)
586	SB = channel*2;
587	else
588	SB = (channel+1)*2;
589	}
590	// currents
591	else if (channel < 80) {
592	channel -= 40;
593	if (channel < 36)
594	SB = channel*2+1;
595	else
596	SB = (channel+1)*2+1;
597	}
598	// humidities
599	else if (channel < 84) {
600	channel -= 80;
601	switch (channel) {
602	case 0:
603	SB = 0x48; //0100.1000
604	break;
605	case 1:
606	SB = 0x49; //0100.1001
607	break;
608	case 2:
609	SB = 0x58; //0101.0010
610	break;
611	case 3:
612	SB = 0x58; //0101.0011
613	break;
614	} // end of switch-case
615	} // end of if (channel < some_number)
616
617	PORTC = (PORTC & 0x80) \| (0x7F & SB); // Here the muxer is switched.
618	}
619
620	void Set_T_Muxer(U08 channel) {
621	U08 SA = 0x00;
622
623	switch (channel/16) {
624	case 0:
625	SA \|= 1<<4; // 0001.0000
626	break;
627	case 1:
628	break; // 0000.0000
629	case 2:
630	SA \|= (1<<4)\|(1<<5); // 0011.0000
631	break;
632	case 3:
633	SA \|= 1<<5; // 0010.0000
634	break;
635	}
636
637	SA = SA \| (channel%16);
638
639	PORTA = (PORTA & 0xC0) \| (0x3F & SA); // Here the muxer is switched.
640	}
641
642	void talk(void){
643
644	/*
645	// makes no sense to declare the 'new_measurement' vars here
646	// but maybe the whole function will be deleted, anyway ...
647	// I'm thinking about it.
648	bool ad7719_new_measurement;
649	bool atmega_adc_new_measurement;
650	if (verbose == true) {
651	// somebody wants to read every new measured value, even if it is trash!
652	// do not actually send away data !
653	// just prepare the data to be send away.
654	if ( ad7719_new_measurement == true ) {
655	add_str_to_output_stream("ad7719: reading:");
656	add_dec_to_output_stream(reading_since_last_muxer_switch,1);
657	add_str_to_output_stream(" temperature channel:");
658	add_dec_to_output_stream(current_temperature_channel,2);
659	add_str_to_output_stream(" = ");
660	add_float_to_output_stream(current_ad7719_value,4,3);
661	add_str_to_output_stream("\n");
662	}
663	if (atmega_adc_new_measurement == true) {
664	add_str_to_output_stream("atmega_adc: reading:");
665	add_dec_to_output_stream(reading_since_last_muxer_switch,1);
666	add_str_to_output_stream(" voltage channel:");
667	add_dec_to_output_stream(current_voltage_channel,2);
668	add_str_to_output_stream(" = ");
669	add_float_to_output_stream(current_atmega_adc_value,4,3);
670	add_str_to_output_stream("\n");
671	}
672	} // end of: if verbose
673	*/
674	} // end of talk()
675
676	// this function generates some output.
677	void ad7719_output(U08 channel, U32 data) {
678	usart_write_str((pU08)"R:"); //R for resistance
679	usart_write_char('A'+channel/8); // Letters A,B,C,D,E,F,G,H
680	usart_write_char(' ');
681	usart_write_U08(channel%8+1,1); // Numbers 1...8
682	usart_write_char(':');
683	usart_write_U32_hex(data); //data
684	usart_write_char('\n');
685	}
686
687	void adc_output(U08 channel, U08 data) {
688
689	if (channel < 40)
690	usart_write_str((pU08)"V:");
691	else if (channel < 80)
692	usart_write_str((pU08)"I:");
693	else if (channel < 84)
694	usart_write_str((pU08)"H:");
695
696	switch (channel/16) {
697	case 0:
698	usart_write_char('A');
699	break;
700	case 1:
701	usart_write_char('B');
702	break;
703	case 2:
704	usart_write_char('D');
705	break;
706	case 3:
707	usart_write_char('C');
708	break;
709	case 4:
710	usart_write_char('E');
711	usart_write_char('E');
712	break;
713
714	usart_write_char(' ');
715	usart_write_U08((channel/2)%8+1,1); // Numbers 1...8
716	usart_write_char(':');
717	usart_write_U16((U16)data*16,5); //data
718	usart_write_char('\n');
719
720
721	}
722
723
724	void adc_output_all() {
725	// output all values, which are enabled
726	for (U08 i=0 ; i<40; ++i){
727	if (i==0) usart_write_str((pU08)"voltages:(in units of 16mV)\n");
728	if (i==40) usart_write_str((pU08)"currents:\n");
729	if (i==80) usart_write_str((pU08)"humidities:\n");
730	if (adc_enables[i/8] & i%8){
731	usart_write_U08(adc_values[i],3);
732	usart_write_char('\t');
733	}
734	if (i%8==7) usart_write_char('\n');
735	if (i==83) usart_write_char('\n');
736	}
737	}
738
739
740	// this method parses the data,
741	// which came in via USART
742	// later it might as well parse the data from ethernet.
743	void parse() {
744	U08 command = usart_rx_buffer[0];
745	// look at first byte
746	// I hope, I can manage to use one byte commands
747	usart_rx_buffer[USART_RX_BUFFER_SIZE-1] = 0;
748	usart_write_str((pU08)"got:");
749	usart_write_str(usart_rx_buffer);
750
751
752
753	switch (command) {
754	case 'E': // AD7719 enable bitmaps may be set
755	for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) {
756	ad7719_enables[i]=usart_rx_buffer[i+1];
757	ad7719_channels_ready[i]=0;
758	}
759	break;
760	case 'e': // ATmega internal ADC enable bitmaps may be set
761	for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) {
762	adc_enables[i]=usart_rx_buffer[i+1];
763	adc_channels_ready[i]=0;
764	}
765	break;
766	case 'h':
767	usart_write_str((pU08)"\nheartbeat ");
768	heartbeat_enable = true;
769	if (usart_rx_buffer[1] == '0'){
770	heartbeat_enable = false;
771	usart_write_str((pU08)"off\n");
772	} else {
773	usart_write_str((pU08)"on\n");
774	}
775	break;
776	case 'G': // GET the Temperature channels, which are enabled
777	for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) {
778	ad7719_channels_ready[i]=0;
779	}
780	break;
781	case 'g': // GET the voltage/current/humidity channels, which are enabled
782	for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) {
783	adc_channels_ready[i]=0;
784	}
785	break;
786	case 's':
787	usart_write_char('\n');
788	for (U08 i=0; i< CHANNEL_BITMAP;++i) {
789	usart_write_U08_bin(ad7719_enables[i]);
790	usart_write_char('\t');
791	}
792	usart_write_char('\n');
793	for (U08 i=0; i< CHANNEL_BITMAP;++i){
794	usart_write_U08_bin(ad7719_channels_ready[i]);
795	usart_write_char('\t');
796	}
797	usart_write_char('\n');
798	usart_write_U32_hex(local_ms);
799	break;
800	}
801	usart_write_str((pU08)"\nready?");
802	for (U08 i=0; i<USART_RX_BUFFER_SIZE; ++i)
803	usart_rx_buffer[i] = 0;
804	}
805
806	void check_if_measured_all() {
807	adc_measured_all = true;
808	for ( U08 i=0; i<V_BITMAP + I_BITMAP + H_BITMAP; ++i ) {
809	if ((adc_enables[i] ^ adc_channels_ready[i]) != 0x00) {
810	adc_measured_all = false;
811	break;
812	}
813	}
814	ad7719_measured_all = true;
815	for ( U08 i=0; i<CHANNEL_BITMAP; ++i ) {
816	if ((ad7719_enables[i] ^ ad7719_channels_ready[i]) != 0x00) {
817	ad7719_measured_all = false;
818	break;
819	}
820	}
821
822
823	}

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