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Arduino interrupts Version
07/11-2017
/ Valle Thorø Side 1 af 47
// Ikke helt færdigredigeret!!!
Arduino Timer Interrupts.
Hvordan får man Arduino til fx at udføre et interrupt og køre en programstump fx nøjagtig 100
gange i sekundet.
Det program, der normalt kører på en controller, er normalt en række af sekventielle instruktioner
udført efter hinanden i et loop. Den tid, et loop tager, er derfor afhængig af hvor stort programmet
er.
Derfor er man nødt til at anvende Interrupts, hvis man skal være sikker på timingen.
Et interrupt er en event – eller hændelse, udløst enten internt fra en tæller / counter, - eller eksternt
fra en pin, der ændrer status.
Et Interrupt er en programstump, der udløses af en hændelse og kører asynkront, ikke i et loop.
Interrupt’et udløses fx af et key-tryk, - eller af en tid gået, - timer-overflow, osv.
Interrupts udløses – og udføres et vilkårligt sted i et kørende program – og uafhængig heraf.
Fx kan et program køre – og samtidig kan der af en timer udløses et interrupt, der blinker en LED.
Det program, der køres når interuptet opstår, kaldes en interrupt service routine (ISR).
Altså: Når et Interrupt opstår, afbrydes det kørende program øjeblikkeligt, og interrupt service
rutinen, dvs. en subrutine, kaldes.
Når en ISR er færdig, vil det kørende program fortsætte hvorfra det blev afbrudt.
Typisk er der gjort brug af interrupts allerede i de tidligere opgaver, der er lavet. De er bare gemt !!
Det er fordi, Arduino´s underlæggende compiler automatisk indbygger mulighed for at bruge
funktioner som, millis() , micros() og delayMicroseconds(). Disse funktioner gør brug af interrupts
ved brug af timere.
PWM-funktionen analogWrite() bruger timere, ligesom tone(), noTone() og Servo library gør.
Opsætning af et interrupt
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Før man kan benytte interrupts, skal der noget opsætning til. Ved at sætte forskellige bits i
forskellige special function registre kan man opsætte processoren til at interrupte på forskellige
events.
Interrupts skal altså enables og den tilhørende interrupt maske skal enables, ligesom det skal
bestemmes, hvad processoren skal udføre, når den interruptes.
Interrupt Service Routine (ISR)
Interrupts can generally enabled / disabled with the function interrupts() / noInterrupts(). By default in the Arduino firmware interrupts are enabled. Interrupt masks are enabled / disabled by setting / clearing bits in the Interrupt mask register (TIMSKx).
When an interrupt occurs, a flag in the interrupt flag register (TIFRx) is been set. This interrupt will be automatically cleared when entering the ISR or by manually clearing the bit in the interrupt flag register.
Der findes to generelt forskellige interrupts: Pinudløste, - og timer/counter udløste interrupts.
Fordelen ved brug af interrupts er, at man kan have et Loop-program til fx at update et 7-segment
display, - og så kan interrupts fx udløst hver 100-del sekund opdatere variable, indeholdende 100-
del sekunder, sekunder, minutter osv.
Pin-udløste interrupts.
Kilder til afsnittet:
Se: http://www.engblaze.com/we-interrupt-this-program-to-bring-you-a-tutorial-on-arduino-interrupts/
Pinudløste interrupts kan sættes op til at ske ved en ændring på Arduino-pin 2 eller 3, henholdsvis
INT0 & INT1.
Der kan vælges om det signal på pin’en, der udløser interruptet skal være rising, falling edge, eller
pinchange.
Eksterne interrupts kan sættes op ” the arduino way ” – eller man kan selv pille bit!!
Et eksempel, ” the Arduino Way”:
void setup()
{
pinMode(13, OUTPUT); // Pin 13 is output to which an LED is connected
digitalWrite(13, LOW); // Make pin 13 low, switch LED off
pinMode(2, INPUT); // Pin 2 is input to which a switch is connected = INT0
Arduino interrupts Version
07/11-2017
/ Valle Thorø Side 3 af 47
pinMode(3, INPUT); // Pin 3 is input to which a switch is connected = INT1
attachInterrupt(0, blink1, RISING);
attachInterrupt(1, blink2, RISING);
// attachInterrupt(0, INT0_handler, CHANGE); //
}
void loop() {
/* Nothing to do: the program jumps automatically to Interrupt Service Routine
"blink" in case of a hardware interrupt on Ardiono pin 2 = INT0 */
}
void blink1(){ // Interrupt service routine
digitalWrite(13, HIGH);
}
void blink2(){ // Interrupt service routine
digitalWrite(13, LOW);
}
http://www.geertlangereis.nl/Electronics/Pin_Change_Interrupts/PinChange_en.html
detachInterrupt(0); // stopper interrupt ! detachInterrupt(1);
Arduino-funktionerne attachInterrupt() og detachInterrupt() bruges kun til pin-udløste interrupts.
Opsætningen af eksterne interrupts kan også styres ved at sætte bits i SFR-registre.
De SFR´s der bruges hertil er:
I External Interrupt Control Register
A indstilles måden, man ønsker et
interrupt udløst.
Eks: EICRA = 0b00000011 ;
Et Extern Interrupt skal enables. Det
sker i External Interrupt Mask
Register, kaldet EIMSK
Og når et INTF flag bliver høj,
udløses et interrupt.
Flaget resettes automatisk når
Interrupt Service Rutinen udføres.
Arduino interrupts Version
07/11-2017
/ Valle Thorø Side 4 af 47
Kilde: https://sites.google.com/site/qeewiki/books/avr-guide/external-interrupts-on-the-atmega328
Her forsøgt vist grafisk – og med eksempler på at sætte bit:
Kodeeksempler:
void setup(void)
{
pinMode(2, INPUT);
pinMode(13, OUTPUT);
digitalWrite(2, HIGH); // Enable pullup resistor
sei(); // Enable global interrupts
EIMSK |= 0b00000001; // Enable external interrupt INT0
EICRA |= 0b00000010; // Trigger INT0 on falling edge
}
void loop(void)
{
Do something
}
//
ISR(EXT_INT0_vect) // Interrupt Service Routine attached to INT0 vector
ISR(EXT_INT0_vect){
}
Extern Interrupt
Mask Register
/ Valle Thorø, Rev: 5/11 2017
Extern Interrupt setup
ISC01
setBit(EICRA,ISC00);setBit(EIMSK,0);
1
Extern Interrupt
Flag Register
EICRA = B00001010;
B1
1 2
0
Extern Sense
Control Register
Flag cleares automatisk
ved Interruptkald
Int0
SREG Bit 7
1
23
ISC00
INT1_VECT() {
IC Pin 4
B2
sei();
// Enable Global Interrupt
1
23
Ext Int 1
1
ISC11
Mux
02
EIMSK
1
23
Mux
Int1setBit(EICRA,0);
01
EIFR
EIMSK = B00000011;
setBit(EIMSK,INT0);
Bit1
Arduino
Pin 3
Bit1
Int1
Global Interrupt
Enable Bit
Int0
B0
Ext Int 0
10
Status Register
12
0
1
23
11
Bit3
setBit(EIMSK,1);
01
Arduino
Pin 2
Variable, der bruges både i ogudenfor en interruptrutine
skal defineres Globale,
"Volatile"
EICRA
11
ISC10
Sei();
asm("Sei");
Cli();
B0
00
IC Pin 5
B0
SetBit(EIFR,0); // Clr Flag
SetBit(EIFR,1);1 2
INT0_VECT() {
Arduino interrupts Version
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{
digitalWrite(13, !digitalRead(13)); // Toggle LED on pin 13
}
Men det er muligt, at få flere pins til at udføre interrupts. Se http://www.geertlangereis.nl/Electronics/Pin_Change_Interrupts/PinChange_en.html
Arduino Interrupts
int pbIn = 0; // Interrupt 0 is on DIGITAL PIN 2!
int ledOut = 4; // The output LED pin
volatile int state = LOW; // The input state toggle
void setup()
{
// Set up the digital pin 2 to an Interrupt and Pin 4 to an Output
pinMode(ledOut, OUTPUT);
//Attach the interrupt to the input pin and monitor for ANY Change
attachInterrupt(pbIn, stateChange, CHANGE);
}
void loop()
{
//Simulate a long running process or complex task
for (int i = 0; i < 100; i++)
{
// do nothing but waste some time
delay(10);
}
}
void stateChange()
{
state = !state;
digitalWrite(ledOut, state);
}
http://www.dave-auld.net/index.php?option=com_content&view=article&id=107:arduino-interrupts&catid=53:arduino-input-output-basics&Itemid=107
Arduino interrupts Version
07/11-2017
/ Valle Thorø Side 6 af 47
Timerudløste interrupts
Ved hjælp af Countere kan man opnå, at man kan få et interrupt til at ske med jævne mellemrum.
Fx hvis man ønsker at få opdateret et stopur hver 100-del af et sekund, eller man ønsker at anvende
en uC som frekvensgenerator. Eller fx som cykelcomputer, hvor der skal tælles pulser i en bestemt
tid.
Små perioder kan direkte udløses direkte ved hjælp af en timer. Men på grund af den ret høje
oscillatorfrekvens, kan længere varigheder mellem interrupts opnås ved fx at tælle antal interrupts i
en variabel, og så kun køre det rigtige interrupt-program hver 100. gang. Programmet kunne her fx
aflæse en sensor !!
En Timer/Counter kan arbejde på to forskellige måder, når en tid skal udmåles.
Man kan indstille en startværdi for Counteren, og så få et interrupt ved overflow
Eller man kan tælle fra 0, og så få et interrupt, når tælleren når en bestemt værdi, indstillet i et
register, et Compare-register.
Counter Overflow Counter Compare Match
Timerens startværdi indstilles, og når timeren
giver overflow, kan der udløses et interrupt.
Counteren starter på 00 00h
Der indsættes en værdi i et Compare-register.
Timerens værdi sammenlignes med Compare-
registeret, og ved match resettes timeren, og der
kan udløses et interrupt.
Indbyggede timere
Arduino Uno har 3 timere indbygget, timer0, timer1 og timer2.
Timer 0: 8 bit
Timer 1: 16 bit.
Timer 2: 8 bit
AT Mega 2560 har yderligere timer 3, 4 og 5, som er 16 bit
Timerne kan indstilles til at tælle eksterne pulser, eller der kan tælles på krystallets frekvens.
Prescaler. / Frekvensdeler.
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På Arduinoen sidder der et 16 MHz krystal. Derfor vil Timeren / Counteren køre ret hurtigt, og give
fx overflow for en 16 bit register i løbet af ca. 4 mS.
Men heldigvis er der indbygget mulighed for at vælge at neddele clockfrekvensen gennem en
frekvensdeler, eller som det kaldes en prescaler.
Hver counter ” har sin egen prescaler ”.
Prescaleren styres af nogle
bit i to SFR-registre,
TimerCounterControl-
Register, TCCRnA eller B
Bittene hedder:
CSn0, CSn1 og CSn2, hvor
tallet n er timerens nummer.
CS står for Clock Select bit.
http://courses.cs.washington.edu/courses/csep567/10wi/lectures/Lecture7.pdf
Se fx http://forum.arduino.cc/index.php/topic,27390.0.html
http://www.engblaze.com/microcontroller-tutorial-avr-and-arduino-timer-interrupts/
Udregning af Prescaler-værdi:
For at få affyret et interrupt med en korrekt frekvens, skal man udregne hvor meget man skal dele
krystallets frekvens ned, så timeren ikke når at give overflow før tiden er gået.
Herefter kan en timers startværdi udregnes, eller en Compare-Match-værdi.
Der kan findes hjælp på en række hjemmesider til at vælge den rette Prescaler til et bestemt formål.
Se fx:
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http://www.et06.dk/atmega_timers/
Forklaring af formlen Skal forbedres!
Udregningen sker som flg:
(timer speed (Hz)) = (Arduino clock speed (16MHz)) / prescaler
𝑖𝑛𝑡𝑒𝑟𝑟𝑢𝑝𝑡 𝑓𝑟𝑒𝑘𝑣𝑒𝑛𝑠 = 16 𝑀𝐻𝑧
𝑃𝑟𝑒𝑠𝑐𝑎𝑙𝑒𝑟 ∙ ((𝐶. 𝑀𝑎𝑡𝑐ℎ 𝑟𝑒𝑔) + 1)
( + 1 fordi det tager 1 clock cycle at resette.
Ligningen her løst for Compare match register, CMR:
𝐶𝑀𝑅 = (16.000.000
𝑃𝑟𝑒𝑠𝑐𝑎𝑙𝑒𝑟 ∙ 𝑖𝑛𝑡𝑒𝑟𝑟𝑢𝑝𝑡 𝑓𝑟𝑒𝑘𝑣.) − 1
Værdien skal være mindre end 256 hvis timer 0 eller 2 bruges, og mindre end 65.536 for Timer 1
for at det kan lade sig gøre:
Eksempel:
Interrupt vælges i dette eksempel til 10 gange pr. sekund, dvs. hver 1/10
sekund, eller til 10 Hz.
Timer 1 giver overflow ved FFFFh + 1 = 65536d.
Frekvensen på krystallet er 16 MHz. Dvs. på 0,1 sek. kommer 1.600.000 pulser.
Det er nødvendig med en frekvensdeler, en prescaler, fordi der kommer for mange
pulser på 0,1 sekund.
Der skal mindst deles med ( 1.600.000 / 65.536 ) = ca. 24,8
Prescaleren kan indstilles til 1, 8, 64, 256, 1024.
Arduino interrupts Version
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/ Valle Thorø Side 9 af 47
fx vælges 64
derfor kommer på 1/10 sekund 1.600.000/64 = 25.000 pulser.
Vælges overflow mode, må tællerens startværdi indstilles til:
( FFFF + 1 ) – 25.000 = 40.536
Vælges Output Compare, tælles fra 0000h og til 25.000. Compare registeret skal
derfor indstilles til 25.000.
Clock select and timer frequency
Different clock sources can be selected for each timer independently. To calculate the timer frequency (for
example 2Hz using timer1) you will need:
1. CPU frequency 16Mhz for Arduino
2. maximum timer counter value (256 for 8bit, 65536 for 16bit timer)
3. Divide CPU frequency through the choosen prescaler (16000000 / 256 = 62500)
4. Divide result through the desired frequency (62500 / 2Hz = 31250)
5. Verify the result against the maximum timer counter value (31250 < 65536 success) if fail, choose
bigger prescaler.
Eksempel på opsætning til 1 HZ interrupt:
Interrupt every second (frequency of 1Hz):
compare match register = [16,000,000 / (prescaler * 1) ] -1
with a prescaler of 1024 you get:
compare match register = [16,000,000 / (1024 * 1) ] -1 = 15,624
since 256 < 15,624 < 65,536, you must use timer1 for this interrupt.
Timer setup code is done inside the setup(){} function in an Arduino sketch.
Control registrere til counterne mm.
For at man kan styre timerne er der en del kontrol-registre, hvis bit – eller indhold skal bestemmes.
Hver timer har et antal SFR-registre tilknyttet.
TCCR1A og TCCR1B
Timer/Counter Control Register.
Pre-scaleren konfigureres her.
Består af 2 x 8 bit registre !!
Arduino interrupts Version
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/ Valle Thorø Side 10 af 47
Hjælp til valg af prescaler til
forskellige interruptfrekvenser,
se fx calculator ovenfor
Prescaler kan vælges til 1, 8,
64, 256, 1024. ( 1024 kan
ikke laves på timer 2 )
Og Bit WGM12 og WGM13
bestemmer mode.
Vi vælger CTC-mode ( timer )
ved at sætte bit WGM12.
TCNTx
Timer/Counter Register.
Indeholder den aktuelle timer
værdi, 16 bit.
TCNT1H og TCNT1L
OCRxx - Output Compare
Register
16 bit register
OCR1AH og OCR1AL
TIMSKx
Timer/Counter Interrupt Mask
Register. To enable/disable
timer interrupts.
Timer_Overflow_
TIFRx - Timer/Counter
Interrupt Flag Register.
Indicates a pending timer
interrupt.
http://courses.cs.washington.edu/courses/csep567/10wi/lectures/Lecture7.pdf http://www.avrbeginners.net/architecture/timers/timers.html
https://arduino-info.wikispaces.com/Timers-Arduino http://www.mikrocontroller.net/articles/AVR-GCC-Tutorial/Die_Timer_und_Z%C3%A4hler_des_AVR
http://www.eng.utah.edu/~cs5789/2010/slides/Interruptsx2.pdf
Med følgende diagram har jeg forsøgt at lave et samlet diagram over en timer og interrupt-
strukturen:
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Tegningen viser de forskellige registre involveret i opsætningen, og der er givet forskellige
eksempler på hvordan man kan manipulere med bittene i registrene:
Her er en kort oversigt over, hvad der skal opsættes:
Hvad skal gøres? Kode-eksempel
Disable global interrupt
Nulstil tæller
Compare værdien skal indstilles
Vælg CTC Mode
Prescaler-værdien skal indstilles
Timer interrupt skal enables
Enabel Global Timer interrupt
cli();
TCNT1 = 0; // Virker på 16 bit.
OCR1A = 15624; // OCR1A = 0x3D08; på hex form;
bitSet(TCCR1B, WGM12); // WGM12 = 3
bitSet(TCCR1B, CS10); // = 00000001
bitSet(TCCR1B, CS12); //TCCR1B er nu 00000101
bitSet(TIMSK1, OCIE1A);
sei(); // CS12=2, CS11=0, CS10=1
Alle registre og register-bit har navne som compileren kender, og den kender deres værdier. Derfor
kan man fx skrive bitSet(TCCR1B, CS12); For definerede værdier: se
bitSet (TCCR1B, WGM12); sætter et bit der vælger Timer Compare mode. Sættes denne ikke, er
der default valgt overflow mode.
12
3
noInterrupts ();
Frekvensdeler
= Prescaler
/ Valle
000 Stop Timer
001 Divide by 1
010 8
011 64
100 256
101 1024
11* Ekstern clock på T1
ISR(TIMER1_OVF_vect)
{
}
Output Compare Vector
Enable Global
TCCR1B
TIMSK1
Timer0 bruges til delay(); millis(); & micros();
Timer1 til servo();
Timer2 til tone();
CS10 = 0
CS11 = 1
CS12 = 2
WGM12 = 3
[ WGMxx = Wave Generation Mode ]
Timer/Counter 1L
Rev: 05/11-2017
TCCR1B |= ( 1 << CS12 ) | ( 1 << CS10 );
Cli();
Clock-pulser,
Ov erf low Vector
Compare match:
Disable
CTC Mode Interrupt
TCNT1L
12
3
ISR(Timer1_COMPA_Vect)
{
}Output Compare Register
bitSet(TCCR1B, CS12);
TIMSK1 |= B00000010;
Fra Pins
// Vælg Prescaler
12
3
ATMEL AVR ATMEGA328
TIMSK1 |= ( 1 << OCIE1A );
TCNT1 = 0;
bitSet(TCCR1B, 3);
TIMSK1-Bit: [xxxx x, OCIE1B, OCIE1A, TOIE1]
Sæt OCF1Abit16 Bit
Compare
Arduino Timer1 Interrupt-Opsætning
Eks: OCR1A = 15624;
16 Bit
TCNT1 = 25324;
OCRnB
TCCR1B |= B00001000;
Definerede
konstanter:
16 Bit
bitSet(TCCR1B, WGM12);
bitSet(TIMSK1, OCIE1A);
Reset Counter
Overflow:
TCCR1A
TCCR1B |= ( 1 << WGM12 );
bitSet(TIMSK1, 0);
interrupts ();
Timer/Counter 1H
[ CSxx = Clock Select bit ]
TCCR1B |= 0x05;
Sei();
Timer/Counter Control Register A/B
Sæt TOV1 Bit
Timer Interrupt Mask register
Output Compare Interrupt
Flag OCF1A og Overflov
flag TOV1 cleares af
hardware ved interrupt kald
Overflow
Bit 0
OCRnC
Interrupt
TCNT1H
OCR1B
f = ( osc / prescale )
bitSet(TCCR1B, CS10);
TIFR1
Oscillator16 MHz
( Clear Timer on
Compare Match )
TCCR1B-Bit[xxxx WGM12, CS12, CS11, CS10 ]
Timer Compare Value
bitSet(TIMSK1, 1);
[CS12, CS11, CS10]
Mode select registre
( Wave Generation Mode )
Compare
Bit 1
Timer 0 & 2 er kun 8 bit
Preload:
Timer/Counter Interrupt
Flag Register
TIMSK1 |= B00000001;
OCR1A
12
3
TCNT1 = 25324;
12
3
Enable Interrupt i TIMSK-reg:
// = 1024
bitSet(TIMSK1, TOIE1);
( Der er også en kanal B & C )
( Kun Kanal A Clearer timeren )
Turn on Compare ( CTC ) Mode
Timer Overflow Bit Flag
// = 1024
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WGM står for Waveform Generation Bit Mode ?
God dok: http://www.eng.utah.edu/~cs5789/2010/slides/Interruptsx2.pdf
*1 Se datablad: http://www.atmel.com/Images/doc8161.pdf
Timerne kan arbejde i et større antal modes, derfor skal man vælge: CTC Mode ( Counter-Timer-
Compare ?? )
Notice how the setups between the three timers differ slightly in the line which turns on CTC mode:
bitSet (TCCR0A, WGM01); //for timer0
bitSet(TCCR1B, WGM12); //for timer1
bitSet(TCCR2A, WGM21); //for timer2
This follows directly from the datasheet of the ATMEL 328/168 Kilde # .1
Bitmanipulation sker med disse instruktioner:
Fra side om C-bitmanipulation. Se : http://tom-itx.dyndns.org:81/~webpage/avr/c_bits/bits_index.php
| bitwise OR
& bitwise AND
~ bitwise NOT
^ bitwise EXLUSIVE OR (XOR)
<< bit LEFT SHIFT
>> bit RIGHT SHIFT
Ved man hvilke bit der skal sættes i et register, kan man gøre det med en af
følgende eksempler:
TCCR1A = 0b10101010;
TCCR1A = 0; // sæt hele TCCR1A register til 0
TCCR1B = 0;
TCCR1B = 0x03;
TCCR2A = B01000011; // her kendes hvilke bits, der skal sættes.
TCCR2B = B00001001;
TCCR2B |= 7; //Clock select. Internal, prescale 1024~64us
bitSet(TCCR1A, WGM01);
TCCR0A = _BV(WGM01); // Mode = CTC
TCCR0B = _BV(CS02) | _BV(CS00); // _BV er en function, der ???
1 Fra: (http://www.instructables.com/id/Arduino-Timer-Interrupts/step2/Structuring-Timer-Interrupts/ )
Datablad: http://www.atmel.com/Images/doc8161.pdf
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Timer Mode select:
Waveform Generation Mode Bit setup:
Timerne kan tillige indstilles til at hav af
forskellige funktioner. Det styres af ”
Waveform generation bits” også i reg.
TCCR1A og TCCR1B.
Det eneste bit der har interesse her er
WGM12, som vælger CTC mode.
http://www.atmel.com/images/atmel-8271-8-bit-avr-microcontroller-atmega48a-48pa-88a-88pa-168a-168pa-328-328p_datasheet_complete.pdf
Interrupt subrutiner
Her er vist, hvordan man skriver en interrupt-subrutine, en Interrupt Service Rutine.
Eks:
ISR(TIMER1_COMPA_vect) // Compare match
{
seconds++;
if (seconds == 10)
{
seconds = 0;
readMySensor(); // Sker hver 10’ende sekund
}
}
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ISR(TIMER1_OVF_vect) // Overflow interrupt service routine
{
TCNT1 = timer1_counter; // preload timer med værdi, fx med 23445
digitalWrite(ledPin, digitalRead(ledPin) ^ 1);
}
void loop()
{
// your program here...
}
Timer Overflow eksempler:
Timer overflow means the timer has reached is limit value. When a timer overflow interrupt occurs,
the timer overflow bit TOVx will be set in the interrupt flag register TIFRx. When the timer
overflow interrupt enable bit TOIEx in the interrupt mask register TIMSKx is set, the timer
overflow interrupt service routine ISR(TIMERx_OVF_vect) will be called.
I denne mode presettes timerne til en startværdi, - og overflow udløser så et interrupt.
Der kan også tilsluttes en ekstern klock-frekvens. Dvs. man kan tælle eksterne pulser.
Men de fleste gange bliver den interne oscillator-frekvens brugt.
/*
* Arduino 101: timer and interrupts
* Timer1 overflow interrupt example
* more infos: http://www.letmakerobots.com/node/28278
* created by RobotFreak
*/
#define ledPin 13
void setup()
{
pinMode(ledPin, OUTPUT);
// initialize timer1
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
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TCNT1 = 34286; // preload timer 65536-16MHz/256/2Hz
bitSet(TCCR1B, CS12); // 256 prescaler
bitSet(TIMSK1, TOIE1); // enable timer overflow interrupt
interrupts(); // enable all interrupts
}
ISR(TIMER1_OVF_vect) // interrupt service routine that wraps a user defined
function supplied by attachInterrupt
{
TCNT1 = 34286; // preload timer
digitalWrite(ledPin, digitalRead(ledPin) ^ 1);
}
void loop()
{
// your program here...
}
// Se: http://www.hobbytronics.co.uk/arduino-timer-interrupts
#define ledPin 13
int timer1_counter;
void setup()
{
pinMode(ledPin, OUTPUT);
// initialize timer1
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
// Set timer1_counter to the correct value for our interrupt interval
//timer1_counter = 64886; // preload timer 65536-16MHz/256/100Hz
//timer1_counter = 64286; // preload timer 65536-16MHz/256/50Hz
timer1_counter = 34286; // preload timer 65536-16MHz/256/2Hz
TCNT1 = timer1_counter; // preload timer
bitSet(TCCR1B, CS12); // 256 prescaler
bitSet(TIMSK1, TOIE1); // enable timer overflow interrupt
interrupts(); // enable all interrupts
}
ISR(TIMER1_OVF_vect) // interrupt service routine
{
TCNT1 = timer1_counter; // preload timer
digitalWrite(ledPin, digitalRead(ledPin) ^ 1);
}
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void loop()
{
// your program here...
}
/*
Eksempel på Interrupt ved timer overflow.
Testet!!
Valle / 8/11-2013
*/
#define ledPin 13
int timer1_startvalue;
int sekund = 0;
int minut = 0;
volatile boolean flag = 0;
//boolean flag = 0;
void setup()
{
pinMode(ledPin, OUTPUT);
Serial.begin(9600);
while (!Serial) {
; // wait for serial port to connect. Needed for Leonardo only
}
// initialize timer1
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
// Set timer1_startvalue to the correct value for our interrupt interval
//timer1_startvalue = 64886; // preload timer 65536-16MHz/256/100Hz
//timer1_startvalue = 64286; // preload timer 65536-16MHz/256/50Hz
//timer1_startvalue = 34286; // preload timer 65536-16MHz/256/2Hz
timer1_startvalue = 3036; // preload timer 65536-16MHz/256/1Hz
TCNT1 = timer1_startvalue; // preload timer
bitSet(TCCR1B, CS12); // 256 prescaler
bitSet(TIMSK1, TOIE1); // enable timer1 overflow interrupt
interrupts(); // enable all interrupts
}
ISR(TIMER1_OVF_vect) // interrupt service routine
{
TCNT1 = timer1_startvalue; // gen-load timer1
digitalWrite(ledPin, digitalRead(ledPin) ^ 1);
sekund++;
flag = HIGH;
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if (sekund > 59) {
sekund = 0;
minut++;
}
}
void loop()
{
while(flag==LOW) { // Wait til change !!
}
Serial.print(minut);
Serial.print(':');
if(sekund<10) Serial.print('0');
Serial.println(sekund);
flag=0;
// delay(1000);
// your program here...
}
// Se: http://www.hobbytronics.co.uk/arduino-timer-interrupts
Output Compare Match eksempler:
When a output compare match interrupt occurs, the OCFxy flag will be set in the interrupt flag
register TIFRx . When the output compare interrupt enable bit OCIExy in the interrupt mask
register TIMSKx is set, the output compare match interrupt service ISR(TIMERx_COMPy_vect)
routine will be called.
Timerne kan udløse et interrupt hver gang, en timer når op til samme værdi, som er gemt i et timer-
match register, - eller hvis de når deres max count-værdi, og giver overflow.
Når en timer når et match,- bliver det resat på det næste klockpuls – og fortsætter så opad igen fra 0
til næste match.
Ved at vælge Compare match værdien, - og vælge klock-frekvensen ( 16 MHz ) sammen med en
frekvensdeler, en prescaler, kan man kontrollere interruptfrekvensen.
Timeren sætter ved overflow en overflow bit som evt. kan tjekkes manuelt af programmet.
ISR-en ( Interrupt Service Routine resetter overflowbit.
/* Arduino 101: timer and interrupts
Timer1 compare match interrupt example
more infos: http://www.letmakerobots.com/node/28278
created by RobotFreak
*/
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#define ledPin 13
void setup()
{
pinMode(ledPin, OUTPUT);
// initialize timer1
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
TCNT1 = 0;
OCR1A = 31250; // compare match register 16MHz/256/2Hz
bitSet(TCCR1B, WGM12); // CTC mode
bitSet(TCCR1B, CS12); // 256 prescaler
bitSet(TIMSK1, OCIE1A); // enable timer compare interrupt
interrupts(); // enable all interrupts
}
ISR(TIMER1_COMPA_vect) // timer compare interrupt service routine
{
digitalWrite(ledPin, digitalRead(ledPin) ^ 1); // toggle LED pin
}
void loop()
{
// your program here...
}
// Arduino timer CTC interrupt example
#define LEDPIN 2
void setup()
{
pinMode(LEDPIN, OUTPUT);
// initialize Timer1
cli(); // disable global interrupts
TCCR1A = 0; // set entire TCCR1A register to 0
TCCR1B = 0; // same for TCCR1B
OCR1A = 15624; // set compare match register to desired timer count:
bitSet(TCCR1B, WGM12); // turn on CTC mode:
bitSet(TCCR1B, CS10); // Set CS10 and CS12 bits for 1024 prescaler:
bitSet(TCCR1B, CS12);
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bitSet(TIMSK1, OCIE1A); // enable timer compare interrupt:
sei(); // enable global interrupts:
}
void loop()
{
// do some crazy stuff while my LED keeps blinking
}
ISR(TIMER1_COMPA_vect)
{
digitalWrite(LEDPIN, !digitalRead(LEDPIN));
}
Eksempel på, at tælle antal interrupts, for at få noget til at foregå langsommere!
ISR(TIMER1_COMPA_vect)
{
seconds++;
if (seconds == 10)
{
seconds = 0;
readMySensor();
}
}
void setup()
{
//Use timer 5, output A (pin 44) ( Ikke for Uno )
// initialize timer5
noInterrupts(); // disable all interrupts
TCCR5A = 0;
TCCR5B = 0;
TCNT5 = 0;
OCR5A = 833; // compare match register 16MHz/256/75Hz ~75.03Hz
bitSet(TCCR5B, WGM12); // CTC mode
bitSet(TCCR5B, CS12); // 256 prescaler
bitSet(TIMSK5, OCIE5A); // enable timer compare interrupt mask
interrupts(); // enable all interrupts
}
void loop()
{
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}
ISR(TIMER5_COMPA_vect) // timer compare ISR
{
Serial.print(" et eller andet"); //print RTI fire time
}
// Denne interrupt kaldes ved 1kHz
// http://petemills.blogspot.dk/2011/05/real-time-clock-part-1.html
ISR(TIMER1_COMPA_vect)
{
static uint16_t milliseconds = 0; // mS value for timekeeping 1000mS/1S
static uint16_t clock_cal_counter = 0; // counting up the milliseconds to MS_ADJ
const uint16_t MS_ADJ = 35088; // F_CPU / (F_CPU * PPM_ERROR)
const uint16_t MS_IN_SEC = 1000; // 1000mS/1S
milliseconds++;
clock_cal_counter++;
if( milliseconds >= MS_IN_SEC )
{
milliseconds = 0;
ss++; // increment seconds
toggle_led(); // toggle led
if( ss > 59 )
{
mm++; // increment minutes
ss = 0; // reset seconds
}
if( mm > 59 )
{
hh++; // increment hours
mm = 0; // reset minutes
}
if( hh > 23 )
{
// increment day
hh = 0; // reset hours
}
}
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// milliseconds must be less than 999 to avoid missing an adjustment.
// eg if milliseconds were to be 999 and we increment it here to 1000
// the next ISR call will make it 1001 and reset to zero just as if it
// would for 1000 and the adjustment would be effectively canceled out.
if( ( clock_cal_counter >= MS_ADJ ) && ( milliseconds < MS_IN_SEC - 1 ) )
{
milliseconds++;
// it may be that clock_cal_counter is > than MS_ADJ in which case
// I want to count the tick towards the next adjustment
// should always be 1 or 0
clock_cal_counter = clock_cal_counter - MS_ADJ;
}
}
What are "volatile" variables?
Variables shared between ISR functions and normal functions should be declared "volatile". This
tells the compiler that such variables might change at any time, and thus the compiler must reload
the variable whenever you reference it, rather than relying upon a copy it might have in a processor
register.
For example:
volatile boolean flag;
// Interrupt Service Routine (ISR)
void isr ()
{
flag = true;
} // end of isr
void setup ()
{
attachInterrupt (0, isr, CHANGE); // attach interrupt handler
} // end of setup
void loop ()
{
if (flag)
{
// interrupt has occurred
}
} // end of loop
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Vist gentagelser i det følgende:
Flere noter:
(Note that there are two other OCR (OCR1B and OCR1C not used in this example. However they
may be used independent of OCR1A to generate another frequency or other Timer Counter
Functions.
When that value is reached the output toggles provided that the corresponding output pin is set to
output mode. )
Der er flere måder, hvorpå man kan få udløst et interrupt på tid:
Kode til at sætte værdier i kontrolregistre:
I flere Kode-eksempler er der vist en metode til at indstille registre-bits til interrupt-styring ved at
skifte en kode til venstre.
Fx:
TCCR1B |= (1 << CS12); // 256 prescaler , skift et ‘1’-tal så mange pladser til
venstre, som værdien af CS12. |= betyder Bitwise or.)
Det kan fx bruges, hvis man ikke kender placeringen af bittene i timer kontrol-registrene. Men det
kræver til gengæld, at man ved, at bit CSn2 skal sættes.
I eksemplet skiftes et 1-tal til venstre et antal gange, angivet af værdien af CS12. Compileren
kender denne værdi!
Prædefinerede værdier, som compileren kender:
De er defineret i en include-fil:
#define CS00 0
#define CS01 1
#define CS02 2
#define TOIE1 0 Se: http://courses.cs.washington.edu/courses/csep567/10wi/lectures/Lecture7.pdf
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Ved man hvilke bit der skal sættes i et register, kan man gøre det med en af følgende muligheder:
Interrupt subrutine:
En interrupt service rutine definers som følgende:
ISR(Timerx_ COMPA_VECT) {
Do something
}
Eksempel:
Arduino timer compare match interrupts:
Eksempler på opsætning af Prescaler:
void setup(){
cli(); //stop interrupts
//set timer0 interrupt at 2kHz
TCCR0A = 0; // set entire TCCR0A register to 0
TCCR0B = 0; // same for TCCR0B
TCNT0 = 0; //initialize counter value to 0
OCR0A = 124; // set compare match register for 2khz
// increments
// = (16*10^6) / (2000*64) - 1 (must be <256)
bitSet(TCCR0A, WGM01); // turn on CTC mode
bitSet(TCCR0B, CS01);
bitSet(TCCR0B, CS00); // Set CS01 and CS00 bits for 64 presc.
bitSet(TIMSK0, OCIE0A); // enable timer compare interrupt
//set timer1 interrupt at 1Hz
TCCR1A = 0; // set entire TCCR1A register to 0
TCCR1B = 0; // same for TCCR1B
TCNT1 = 0; //initialize counter value to 0
OCR1A = 15624; // set compare match register for 1hz
// increments
// = (16*10^6) / (1*1024) - 1 (must be <65536)
bitSet(TCCR1B, WGM12); // turn on CTC mode
bitSet(TCCR1B, CS12);
bitSet(TCCR1B, CS10); // Set CS10 og CS12 bits for 1024 presc.
bitSet(TIMSK1, OCIE1A); // enable timer compare interrupt
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//set timer2 interrupt at 8kHz
TCCR2A = 0; // set entire TCCR2A register to 0
TCCR2B = 0; // same for TCCR2B
TCNT2 = 0; //initialize counter value to 0
OCR2A = 249; // set compare match register for 8khz
// increments
// = (16*10^6) / (8000*8) - 1 (must be <256)
bitSet(TCCR2A, WGM21); // turn on CTC mode
bitSet(TCCR2B, CS21); // Set CS21 bit for 8 prescaler
bitSet(TIMSK2, OCIE2A); // enable timer compare interrupt
sei(); //allow interrupts
} //end setup
ISR(TIMER0_COMPA_vect){ //change the 0 to 1 for timer1 and 2 for timer2
//interrupt commands here
}
http://www.instructables.com/id/Arduino-Timer-Interrupts/
Interrupts(); noInterrupts();
Eksempel på beskyttelse af tidskritisk kode
volatile unsigned int count;
/* Det er altid tilrådeligt, at erklære variable, der optræder både i en ISR
og i et loop for globale ( Volatile )
Det får compileren til altid at placere variablene i RAM
*/
ISR (TIMER1_OVF_vect)
{
TCNT1 = 34286; // preload timer
count++;
} // end of TIMER1_OVF_vect
void setup ()
{
pinMode (13, OUTPUT);
noInterrupts(); // disable all interrupts
TCCR1A = 0;
TCCR1B = 0;
TCNT1 = 34286; // preload timer 65536-16MHz/256/2Hz
bitSet(TCCR1B, CS12); // 256 prescaler
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bitSet(TIMSK1, TOIE1); // enable timer overflow interrupt
interrupts(); // enable all interrupts
} // end of setup
void loop ()
{
noInterrupts (); // ; Beskyt loop-koden: = cli();
if (count > 4){
digitalWrite(13, digitalRead(13) ^ 1); // Flip pin
count = 0;
}
interrupts (); // Enable interrupt igen = sei();
// end of loop
}
Oversigtstegninger og animationer over timer-opbygning i ATMEGA processoren.
Der findes også andre
skitser over hvordan
interrupt-strukturen sættes
op.
Bemærk, at PWM1x vist
nu hedder WGM1x
http://www.kner.at/home/40.avr/_architektur/ztcpwm.html
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Her er animeret en compare
match.
http://www.kner.at/home/40.avr/_architektur/ztcbint.html
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Og en overflow match.
http://www.kner.at/home/40.avr/_architektur/ztcbint.html
Resten er endnu ikke helt gennemarbejdet, kan betragtes som Bonus Info
TIMSK1. This is the Timer/Counter1 Interrupt Mask Register. Setting the TOIE1 bit tells the timer to
trigger an interrupt when the timer overflows.
TIMSK and TIFR
The Timer Interrupt Mask Register (TIMSK) and Timer Interrupt Flag (TIFR) Register are used to control which interrupts are "valid" by setting their bits in TIMSK and to determine which interrupts are currently pending (TIFR).
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Bit 7 Bit 0
TOIE1 OCIE1A --- --- TICIE1 --- TOIE0 ---
TOIE1: Timer Overflow Interrupt Enable (Timer 1); If this bit is set and if global interrupts are enabled, the micro will jump to the Timer Overflow 1 interrupt vector upon Timer 1 Overflow.
OCIE1A: Output Compare Interrupt Enable 1 A; If set and if global Interrupts are enabled, the micro will jump to the Output Compare A Interrupt vetor upon compare match.
TICIE1: Timer 1 Input Capture Interrupt Enable; If set and if global Interrupts are enabled, the micro will jump to the Input Capture Interrupt vector upon an Input Capture event.
TOIE0: Timer Overflow Interrupt Enable (Timer 0); Same as TOIE1, but for the 8-bit Timer 0.
TCCR1A = 0x00;
// COM1A1=0, COM1A0=0 => Disconnect Pin OC1 from Timer/Counter 1 --
PWM11=0,PWM10=0 => PWM Operation disabled, ICNC1=0 => Capture Noise Canceler
disabled -- ICES1=0 => Input Capture Edge Select (not used) -- CTC1=0 => Clear
Timer/Counter 1 on Compare/Match, CS12=0 CS11=1 CS10=1 => Set prescaler to
clock/64
TCCR1B = 0x03;
// 16MHz clock with prescaler means TCNT1 increments every 4uS,
ICIE1=0 => Timer/Counter 1, Input Capture Interrupt Enable -- OCIE1A=0 => Output
Compare A Match Interrupt Enable -- OCIE1B=0 => Output Compare B Match Interrupt
Enable
TOIE1=0 => Timer 1 Overflow Interrupt Enable
TCCR3A register
COM3A1 COM3A0 COM3B1 COM3B0 COM3C1 COM3C0 WGM11 WGM10
TCCR3B register ICNC3 ICES3 – WGM13 WGM12 CS12 CS11 CS10
http://courses.cs.washington.edu/courses/csep567/10wi/lectures/Lecture7.pdf
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based on the AT90S2313.
http://www.avrbeginners.net/architecture/timers/timers.html
16 bit timere er
lidt mere
complex.
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Timer overflow og interrupt udløses :
http://www.avrbeginners.net/architecture/timers/timers.html
Output Compare Mode
The Output Compare mode is used to perform repeated timing. The value in TCNT1 (which is counting up if not stopped by the prescaler select bits) is permanently compared to the value in OCR1A. When these values are equal to each other, the Output Compare Interrupt Flag (OCF in TIFR) is set and an ISR can be called. By setting the CTC1 bit in TCCR1B, the timer can be automatically cleared upon compare match.
http://www.avrbeginners.net/architecture/timers/timers.html
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http://www.nunoalves.com/classes/spring_2012_cpe355/cpe355-02-b.pdf
http://www.gammon.com.au/forum/?id=11488
http://www.protostack.com/blog/2010/09/timer-interrupts-on-an-atmega168/ Gode oversigter over register!
http://www.instructables.com/id/Arduino-Timer-Interrupts/
Example- the following sketch sets up and executes 3 timer interrupts: //timer interrupts
//by Amanda Ghassaei
//June 2012
//http://www.instructables.com/id/Arduino-Timer-Interrupts/
/*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
*/
//timer setup for timer0, timer1, and timer2.
//For arduino uno or any board with ATMEL 328/168.. diecimila, duemilanove,
lilypad, nano, mini...
//this code will enable all three arduino timer interrupts.
//timer0 will interrupt at 2kHz
//timer1 will interrupt at 1Hz
//timer2 will interrupt at 8kHz
//storage variables
boolean toggle0 = 0;
boolean toggle1 = 0;
boolean toggle2 = 0;
void setup(){
pinMode(8, OUTPUT); //set pins as outputs
pinMode(9, OUTPUT);
pinMode(13, OUTPUT);
cli(); //stop interrupts
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//set timer0 interrupt at 2kHz
TCCR0A = 0; // set entire TCCR2A register to 0
TCCR0B = 0; // same for TCCR2B
TCNT0 = 0; //initialize counter value to 0
// set compare match register for 2khz
// increments
OCR0A = 124; // = (16*10^6) / (2000*64) - 1 (must be <256)
TCCR0A |= (1 << WGM01); // turn on CTC mode
TCCR0B |= (1 << CS01) | (1 << CS00); // Set CS01 and CS00 bits for 64
// prescaler
TIMSK0 |= (1 << OCIE0A); // enable timer compare interrupt
//set timer1 interrupt at 1Hz
TCCR1A = 0; // set entire TCCR1A register to 0
TCCR1B = 0; // same for TCCR1B
TCNT1 = 0; //initialize counter value to 0
// set compare match register for 1hz
// increments
OCR1A = 15624; // = (16*10^6) / (1*1024) - 1 (must be <65536)
TCCR1B |= (1 << WGM12); // turn on CTC mode
TCCR1B |= (1 << CS12) | (1 << CS10); // Set CS12 and CS10 bits for 1024
//prescaler
TIMSK1 |= (1 << OCIE1A); // enable timer compare interrupt
//set timer2 interrupt at 8kHz
TCCR2A = 0; // set entire TCCR2A register to 0
TCCR2B = 0; // same for TCCR2B
TCNT2 = 0; //initialize counter value to 0
// set compare match register for 8khz
// increments
OCR2A = 249; // = (16*10^6) / (8000*8) - 1 (must be <256)
TCCR2A |= (1 << WGM21); // turn on CTC mode
TCCR2B |= (1 << CS21); // Set CS21 bit for 8 prescaler
TIMSK2 |= (1 << OCIE2A); // enable timer compare interrupt
sei();//allow interrupts
}//end setup
ISR(TIMER0_COMPA_vect){ //timer0 interrupt 2kHz toggles pin 8
//generates pulse wave of frequency 2kHz/2 =
//1kHz (takes two cycles for full wave- toggle
// high then toggle low)
if (toggle0){
digitalWrite(8,HIGH);
toggle0 = 0;
}
else{
digitalWrite(8,LOW);
toggle0 = 1;
}
}
ISR(TIMER1_COMPA_vect){ //timer1 interrupt 1Hz toggles pin 13 (LED)
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//generates pulse wave of frequency 1Hz/2 =
//0.5kHz (takes two cycles for full wave-
//toggle high then toggle low)
if (toggle1){
digitalWrite(13,HIGH);
toggle1 = 0;
}
else{
digitalWrite(13,LOW);
toggle1 = 1;
}
}
ISR(TIMER2_COMPA_vect){ //timer1 interrupt 8kHz toggles pin 9
//generates pulse wave of frequency 8kHz/2 =
//4kHz (takes two cycles for full wave- toggle
// high then toggle low)
if (toggle2){
digitalWrite(9,HIGH);
toggle2 = 0;
}
else{
digitalWrite(9,LOW);
toggle2 = 1;
}
}
void loop(){
//do other things here
}
The images above show the outputs from these timer interrupts. Fig 1 shows a square wave oscillating between 0 and 5V at 1kHz (timer0 interrupt), fig 2 shows the LED attached to pin 13 turning on for one second then turning off for one second (timer1 interrupt), fig 3 shows a pulse wave oscillating between 0 and 5V at a frequency of 4khz (timer2 interrupt).
Bike Speedometer
In this example I made an arduino bike speedometer. It works by attaching a magnet to the wheel and measuring the amount of time it takes to pass by a magnetic switch mounted on the frame- the time for one complete rotation of the wheel. I set timer 1 to interrupt every ms (frequency of 1kHz) to measure the magnetic switch. If the magnet is passing by the switch, the signal from the switch is high and the variable "time" gets set to zero. If the magnet is not near the switch "time" gets incremented by 1. This way "time" is actually just a measurement of the amount of time in milliseconds that has passed since the magnet last passed by the magnetic switch. This info is used later in the code to calculate rpm and mph of the bike. Here's the bit of code that sets up timer1 for 1kHz interrupts Here's the complete code if you want to take a look: //bike speedometer
//by Amanda Ghassaei 2012
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//http://www.instructables.com/id/Arduino-Timer-Interrupts/
//http://www.instructables.com/id/Arduino-Timer-Interrupts/
/*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
*/
//sample calculations
//tire radius ~ 13.5 inches
//circumference = pi*2*r =~85 inches
//max speed of 35mph =~ 616inches/second
//max rps =~7.25
#define reed A0//pin connected to read switch
//storage variables
float radius = 13.5;// tire radius (in inches)- CHANGE THIS FOR YOUR OWN BIKE
int reedVal;
long time = 0;// time between one full rotation (in ms)
float mph = 0.00;
float circumference;
boolean backlight;
int maxReedCounter = 100;//min time (in ms) of one rotation (for debouncing)
int reedCounter;
void setup(){
reedCounter = maxReedCounter;
circumference = 2*3.14*radius;
pinMode(1,OUTPUT);//tx
pinMode(2,OUTPUT);//backlight switch
pinMode(reed,INPUT);//redd switch
checkBacklight();
Serial.write(12);//clear
// TIMER SETUP- the timer interrupt allows preceise timed measurements of the reed
switch
//for mor info about configuration of arduino timers see
http://arduino.cc/playground/Code/Timer1
cli();//stop interrupts
//set timer1 interrupt at 1kHz
TCCR1A = 0;// set entire TCCR1A register to 0
TCCR1B = 0;// same for TCCR1B
TCNT1 = 0;//initialize counter value to 0;
// set timer count for 1khz increments
OCR1A = 1999;// = (16*10^6) / (1000*8) - 1
// turn on CTC mode
TCCR1B |= (1 << WGM12);
// Set CS11 bit for 8 prescaler
TCCR1B |= (1 << CS11);
// enable timer compare interrupt
TIMSK1 |= (1 << OCIE1A);
sei();//allow interrupts
//END TIMER SETUP
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Serial.begin(9600);
}
void checkBacklight(){
backlight = digitalRead(2);
if (backlight){
Serial.write(17);//turn backlight on
}
else{
Serial.write(18);//turn backlight off
}
}
ISR(TIMER1_COMPA_vect) {//Interrupt at freq of 1kHz to measure reed switch
reedVal = digitalRead(reed);//get val of A0
if (reedVal){//if reed switch is closed
if (reedCounter == 0){//min time between pulses has passed
mph = (56.8*float(circumference))/float(time);//calculate miles per hour
time = 0;//reset timer
reedCounter = maxReedCounter;//reset reedCounter
}
else{
if (reedCounter > 0){//don't let reedCounter go negative
reedCounter -= 1;//decrement reedCounter
}
}
}
else{//if reed switch is open
if (reedCounter > 0){//don't let reedCounter go negative
reedCounter -= 1;//decrement reedCounter
}
}
if (time > 2000){
mph = 0;//if no new pulses from reed switch- tire is still, set mph to 0
}
else{
time += 1;//increment timer
}
}
void displayMPH(){
Serial.write(12);//clear
Serial.write("Speed =");
Serial.write(13);//start a new line
Serial.print(mph);
Serial.write(" MPH ");
//Serial.write("0.00 MPH ");
}
void loop(){
//print mph once a second
displayMPH();
delay(1000);
checkBacklight();
}
For this project, I used timer2 interrupts to periodically check if there was any incoming serial data, read it, and store it in the matrix "ledData[]". If you take a look at the code you will see that the main loop of
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the sketch is what is actually responsible for using the info in ledData to light up the correct LEDs and checking on the status of the buttons (a function called "shift()"). The interrupt routine is as short as possible- just checking for incoming bytes and storing them appropriately. Here is the setup for timer2: cli();//stop interrupts
//set timer2 interrupt every 128us
TCCR2A = 0;// set entire TCCR2A register to 0
TCCR2B = 0;// same for TCCR2B
TCNT2 = 0;//initialize counter value to 0
// set compare match register for 7.8khz increments
OCR2A = 255;// = (16*10^6) / (7812.5*8) - 1 (must be <256)
// turn on CTC mode
TCCR2A |= (1 << WGM21);
// Set CS21 bit for 8 prescaler
TCCR2B |= (1 << CS21);
// enable timer compare interrupt
TIMSK2 |= (1 << OCIE2A);
sei();//allow interrupts
Here's the complete Arduino sketch: //BUTTON TEST w/ 74HC595 and 74HC165 and serial communication
//by Amanda Ghassaei
//June 2012
//http://www.instructables.com/id/Arduino-Timer-Interrupts/
/*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
*/
//this firmware will send data back and forth with the maxmsp patch "beat slicer"
//pin connections
#define ledLatchPin A1
#define ledClockPin A0
#define ledDataPin A2
#define buttonLatchPin 9
#define buttonClockPin 10
#define buttonDataPin A3
//looping variables
byte i;
byte j;
byte k;
byte ledByte;
//storage for led states, 4 bytes
byte ledData[] = {0, 0, 0, 0};
//storage for buttons, 4 bytes
byte buttonCurrent[] = {0,0,0,0};
byte buttonLast[] = {0,0,0,0};
byte buttonEvent[] = {0,0,0,0};
byte buttonState[] = {0,0,0,0};
//button debounce counter- 16 bytes
byte buttonDebounceCounter[4][4];
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void setup() {
DDRC = 0xF7;//set A0-2 and A4-5 output, A3 input
DDRB = 0xFF;//digital pins 8-13 output
Serial.begin(57600);
cli();//stop interrupts
//set timer2 interrupt every 128us
TCCR2A = 0;// set entire TCCR2A register to 0
TCCR2B = 0;// same for TCCR2B
TCNT2 = 0;//initialize counter value to 0
// set compare match register for 7.8khz increments
OCR2A = 255;// = (16*10^6) / (7812.5*8) - 1 (must be <256)
// turn on CTC mode
TCCR2A |= (1 << WGM21);
// Set CS21 bit for 8 prescaler
TCCR2B |= (1 << CS21);
// enable timer compare interrupt
TIMSK2 |= (1 << OCIE2A);
sei();//allow interrupts
}
// buttonCheck - checks the state of a given button.
//this buttoncheck function is largely copied from the monome 40h firmware by brian
crabtree and joe lake
void buttonCheck(byte row, byte index)
{
if (((buttonCurrent[row] ^ buttonLast[row]) & (1 << index)) && // if the current
physical button state is different from the
((buttonCurrent[row] ^ buttonState[row]) & (1 << index))) { // last physical button
state AND the current debounced state
if (buttonCurrent[row] & (1 << index)) { // if the current
physical button state is depressed
buttonEvent[row] = 1 << index; // queue up a new button event
immediately
buttonState[row] |= (1 << index); // and set the debounced
state to down.
}
else{
buttonDebounceCounter[row][index] = 12;
} // otherwise the button was previously depressed and now
// has been released so we set our debounce counter.
}
else if (((buttonCurrent[row] ^ buttonLast[row]) & (1 << index)) == 0 && // if the
current physical button state is the same as
(buttonCurrent[row] ^ buttonState[row]) & (1 << index)) { // the last physical
button state but the current physical
// button state is different from the current debounce
// state...
if (buttonDebounceCounter[row][index] > 0 && --buttonDebounceCounter[row][index] ==
0) { // if the the debounce counter has
// been decremented to 0 (meaning the
// the button has been up for
// kButtonUpDefaultDebounceCount
// iterations///
buttonEvent[row] = 1 << index; // queue up a button state change event
if (buttonCurrent[row] & (1 << index)){ // and toggle the buttons
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debounce state.
buttonState[row] |= (1 << index);
}
else{
buttonState[row] &= ~(1 << index);
}
}
}
}
void shift(){
for (i=0;i<4;i++){
buttonLast[i] = buttonCurrent[i];
byte dataToSend = (1 << (i+4)) | (15 & ~ledData[i]);
// set latch pin low so the LEDs don't change while sending in bits
digitalWrite(ledLatchPin, LOW);
// shift out the bits of dataToSend
shiftOut(ledDataPin, ledClockPin, LSBFIRST, dataToSend);
//set latch pin high so the LEDs will receive new data
digitalWrite(ledLatchPin, HIGH);
//once one row has been set high, receive data from buttons
//set latch pin high
digitalWrite(buttonLatchPin, HIGH);
//shift in data
buttonCurrent[i] = shiftIn(buttonDataPin, buttonClockPin, LSBFIRST) >> 3;
//latchpin low
digitalWrite(buttonLatchPin, LOW);
for (k=0;k<4;k++){
buttonCheck(i,k);
if (buttonEvent[i]<<k){
if (buttonState[i]&1<<k){
Serial.write(((3-k)<<3)+(i<<1)+1);
}
else{
Serial.write(((3-k)<<3)+(i<<1)+0);
}
buttonEvent[i] &= ~(1<<k);
}
}
}
}
ISR(TIMER2_COMPA_vect) {
do{
if (Serial.available()){
ledByte = Serial.read();//000xxyys
boolean ledstate = ledByte & 1;
byte ledy = (ledByte >> 1) & 3;
byte ledx = (ledByte >> 3) & 3;
if (ledstate){
ledData[ledy] |= 8 >> ledx;
}
else{
ledData[ledy] &= ~ (8 >> ledx);
}
}//end if serial available
}//end do
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while (Serial.available() > 8);
}
void loop() {
shift();//updates leds and receives data from buttons
}
One last thing to note- certain timer setups will actually disable some of the Arduino library functions. Timer0 is used by the functions millis() and delay(), if you manually set up timer0, these functions will not work correctly. Additionally, all three timers underwrite the function analogWrite(). Manually setting up a timer will stop analogWrite() from working. If there is some portion of your code that you don't want interrupted, considering using cli() and sei() to globally disable and enable interrupts. You can read more about this on the Arduino website.
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Stopwatch http://playground.arduino.cc/Code/Stopwatch
A sketch that demonstrates how to do two (or more) things at once by using millis().
/* StopWatch
* Paul Badger 2008
* Demonstrates using millis(), pullup resistors,
* making two things happen at once, printing fractions
*
* Physical setup: momentary switch connected to pin 4, other side connected to ground
* LED with series resistor between pin 13 and ground
*/
#define ledPin 13 // LED connected to digital pin 13
#define buttonPin 4 // button on pin 4
int value = LOW; // previous value of the LED
int buttonState; // variable to store button state
int lastButtonState; // variable to store last button state
int blinking; // condition for blinking - timer is timing
long interval = 100; // blink interval - change to suit
long previousMillis = 0; // variable to store last time LED was updated
long startTime ; // start time for stop watch
long elapsedTime ; // elapsed time for stop watch
int fractional; // variable used to store fractional part of time
void setup()
{
Serial.begin(9600);
pinMode(ledPin, OUTPUT); // sets the digital pin as output
pinMode(buttonPin, INPUT); // not really necessary, pins default to INPUT anyway
digitalWrite(buttonPin, HIGH); // turn on pullup resistors. Wire button so that press shorts
pin to ground.
}
void loop()
{
// check for button press
buttonState = digitalRead(buttonPin); // read the button state and store
if (buttonState == LOW && lastButtonState == HIGH && blinking== false){ // check for a
high to low transition
// if true then found a new button press while clock is not running - start the clock
startTime = millis(); // store the start time
blinking = true; // turn on blinking while timing
delay(5); // short delay to debounce switch
lastButtonState = buttonState; // store buttonState in
lastButtonState, to compare next time
}
else if (buttonState == LOW && lastButtonState == HIGH &&blinking == true){ // check for a
high to low transition
// if true then found a new button press while clock is running - stop the clock and report
elapsedTime = millis() - startTime; // store elapsed time
blinking = false; // turn off blinking, all done timing
lastButtonState = buttonState; // store buttonState in lastButtonState,
to compare next time
// routine to report elapsed time
Serial.print( (int)(elapsedTime / 1000L)); // divide by 1000 to convert to seconds
- then cast to an int to print
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Serial.print("."); // print decimal point
// use modulo operator to get fractional part of time
fractional = (int)(elapsedTime % 1000L);
// pad in leading zeros - wouldn't it be nice if
// Arduino language had a flag for this? :)
if (fractional == 0)
Serial.print("000"); // add three zero's else if (fractional < 10) // if fractional < 10 the 0 is ignored giving a wrong time, so
add the zeros
Serial.print("00"); // add two zeros else if (fractional < 100)
Serial.print("0"); // add one zero
Serial.println(fractional); // print fractional part of time
}
else{
lastButtonState = buttonState; // store buttonState in
lastButtonState, to compare next time
}
// blink routine - blink the LED while timing
// check to see if it's time to blink the LED; that is, the difference
// between the current time and last time we blinked the LED is larger than
// the interval at which we want to blink the LED.
if ( (millis() - previousMillis > interval) ) {
if (blinking == true){
previousMillis = millis(); // remember the last time we blinked
the LED
// if the LED is off turn it on and vice-versa.
if (value == LOW)
value = HIGH;
else
value = LOW;
digitalWrite(ledPin, value);
}
else{
digitalWrite(ledPin, LOW); // turn off LED when not blinking
}
}
}
Brug af milis: cykelcomputer: Interrupt Triggers hver puls fra føler:
To calculate the circumference – use the formula:
circumference = 2πr
where r is the radius of the circle. Now that you have the wheel circumference, this value can be considered as our
‘fixed distance’, and therefore the speed can be calculated by measuring the elapsed time between of a full
rotation.
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Your sensor – once fitted – should act in the same method as a normally-open button that is pushed every
rotation. Our sketch will measure the time elapsed between every pulse from the sensor. To do this, our example
will have the sensor output connected to digital pin 2 – as it will trigger an interrupt to calculate the speed.
(Interrupts? See chapter three). The sketch will otherwise be displaying the speed on a normal I2C-interface
LCD module. The I2C interface is suggested as this requires only 4 wires from the Arduino board to the LCD –
the less wires the better.
Example 37.3
/*
Example 37.3 – Basic speedometer using millis();
http://tronixstuff.wordpress.com/tutorials > chapter 37
John Boxall | CC by-sa-nc
*/
#include "Wire.h" // for I2C bus LCD
#include "LiquidCrystal_I2C.h" // for I2C bus LCD module - http://bit.ly/m7K5wt
LiquidCrystal_I2C lcd(0x27,16,2); // set the LCD address to 0x27 for a 16
chars and 2 line display
float start, finished;
float elapsed, time;
float circMetric=1.2; // wheel circumference relative to sensor position (in
meters)
float circImperial; // using 1 kilometer = 0.621371192 miles
float speedk, speedm; // holds calculated speed vales in metric and imperial
void setup()
{
attachInterrupt(0, speedCalc, RISING); // interrupt called when sensors sends
digital 2 high (every wheel rotation)
start=millis();
// setup LCD
lcd.init(); // initialize the lcd
lcd.backlight(); // turn on LCD backlight
lcd.clear();
lcd.println(" Wear a helmet! ");
delay(3000);
lcd.clear();
Serial.begin(115200);
circImperial=circMetric*.62137; // convert metric to imperial for MPH
calculations
}
void speedCalc()
{
elapsed=millis()-start;
start=millis();
speedk=(3600*circMetric)/elapsed; // km/h
speedm=(3600*circImperial)/elapsed; // Miles per hour
}
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void loop()
{
lcd.setCursor(0,0);
lcd.print(int(speedk));
lcd.print(" km/h ");
lcd.print(int(speedm));
lcd.print(" MPH ");
lcd.setCursor(0,1);
lcd.print(int(elapsed));
lcd.print(" ms/rev ");
delay(1000); // adjust for personal preference to minimise flicker
}
There isn’t that much going on – every time the wheel completes one revolution the signal from the sensor will go
from low to high – triggering an interrupt which calls the function speedCalc(). This takes a reading of millis() and
then calculates the difference between the current reading and the previous reading – this value becomes the time
to cover the distance (which is the circumference of the wheel relative to the sensor – stored in
float circMetric=1.2;
and is measured in metres). It finally calculates the speed in km/h and MPH. Between interrupts the sketch
displays the updated speed data on the LCD as well as the raw time value for each revolution for curiosity’s sake.
In real life I don’t think anyone would mount an LCD on a bicycle, perhaps an LED display would be more relevant.
In the meanwhile, you can see how this example works in the following short video clip. Instead of a bike wheel
and reed switch/magnet combination, I have connected the square-wave output from a function generator to the
interrupt pin to simulate the pulses from the sensor, so you can get an idea of how it works:
http://letsmakerobots.com/node/28278
1 Reset
2 External Interrupt Request 0 (pin D2) (INT0_vect)
3 External Interrupt Request 1 (pin D3) (INT1_vect)
4 Pin Change Interrupt Request 0 (pins D8 to D13) (PCINT0_vect)
5 Pin Change Interrupt Request 1 (pins A0 to A5) (PCINT1_vect)
6 Pin Change Interrupt Request 2 (pins D0 to D7) (PCINT2_vect)
7 Watchdog Time-out Interrupt (WDT_vect)
8 Timer/Counter2 Compare Match A (TIMER2_COMPA_vect)
9 Timer/Counter2 Compare Match B (TIMER2_COMPB_vect)
10 Timer/Counter2 Overflow (TIMER2_OVF_vect)
11 Timer/Counter1 Capture Event (TIMER1_CAPT_vect)
12 Timer/Counter1 Compare Match A (TIMER1_COMPA_vect)
13 Timer/Counter1 Compare Match B (TIMER1_COMPB_vect)
14 Timer/Counter1 Overflow (TIMER1_OVF_vect)
15 Timer/Counter0 Compare Match A (TIMER0_COMPA_vect)
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16 Timer/Counter0 Compare Match B (TIMER0_COMPB_vect)
17 Timer/Counter0 Overflow (TIMER0_OVF_vect)
18 SPI Serial Transfer Complete (SPI_STC_vect)
19 USART Rx Complete (USART_RX_vect)
20 USART, Data Register Empty (USART_UDRE_vect)
21 USART, Tx Complete (USART_TX_vect)
22 ADC Conversion Complete (ADC_vect)
23 EEPROM Ready (EE_READY_vect)
24 Analog Comparator (ANALOG_COMP_vect)
25 2-wire Serial Interface (I2C) (TWI_vect)
26 Store Program Memory Ready (SPM_READY_vect)
Fra: http://www.gammon.com.au/forum/?id=11488
God og stor samling Tutorials: http://tronixstuff.com/tutorials/
#include <avr/io.h>
#include <avr/interrupt.h>
int ledPin = 8;
volatile int compAval = 10;
void setup() {
Serial.begin(9600);
pinMode(ledPin, OUTPUT);
digitalWrite(ledPin, LOW);
sei(); //Enable interrupts
TCCR2A |= 3; //Fast PWM mode 3.
TCCR2A |= (3 << 6); //fire INT on Compare match
TCNT2 = 0; //initialize Timer2 to 0
OCR2A = compAval; //Set compare A value
TIMSK2 |= (1 << 1); //Enable CompA interrupt
TIMSK2 |= 1; //Enable OVF interrupt
TCCR2B |= 7; //Clock select. Internal, prescale 1024~64us
}
ISR(TIMER2_COMPA_vect)
{
digitalWrite(ledPin, HIGH);
}
ISR(TIMER2_OVF_vect)
{
digitalWrite(ledPin, LOW);
compAval = compAval + 4;
if(compAval > 254)
compAval = 10;
OCR2A = compAval;
}
void loop()
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{
//Serial.println(TCNT2, DEC);
}
http://courses.cs.washington.edu/courses/csep567/10wi/lectures/Lecture6.pdf
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TCCR1B:
Bit 7 Bit 0
ICNC1 ICES1 --- --- CTC1 CS12 CS11 CS10
ICNC1: Input Capture Noise Canceler; If set, the Noise Canceler on the ICP pin is activated. It will trigger the input capture after 4 equal samples. The edge to be triggered on is selected by the ICES1 bit.
ICES1: Input Capture Edge Select;
When cleared, the contents of TCNT1 are transferred to ICR (Input Capture Register) on the falling edge of the ICP pin.
If set, the contents of TCNT1 are transferred on the rising edge of the ICP pin.
CTC1: Clear Timer/Counter 1 on Compare Match; If set, the TCNT1 register is cleared on compare match. Use this bit to create repeated Interrupts after a certain time, e.g. to handle button debouncing or other frequently occuring events. Timer 1 is also used in normal mode, remember to clear this bit when leaving compare match mode if it was set. Otherwise the timer will never overflow and the timing is corrupted.
http://www.let-elektronik.dk/tutorials
en samling links til Jeremy Bloms videos:
Se: http://harperjiangnew.blogspot.dk/2013/05/arduino-using-atmegas-internal.html
http://tom-itx.dyndns.org:81/~webpage/abcminiuser/articles/avr_timers_index.php
CTC mode: http://maxembedded.com/2011/06/28/avr-timers-timer1/
http://www.youtube.com/watch?v=CRJUdf5TTQQ http://www.uchobby.com/index.php/2007/11/24/arduino-interrupts/ http://www.protostack.com/blog/2010/09/timer-interrupts-on-an-atmega168/ http://www.instructables.com/id/Arduino-Timer-Interrupts/step2/Structuring-Timer-Interrupts/ http://www.instructables.com/id/Arduino-Timer-Interrupts/ http://www.engblaze.com/microcontroller-tutorial-avr-and-arduino-timer-interrupts/ http://arduino-info.wikispaces.com/Timers-Arduino
Links:
God side om timere: https://sites.google.com/site/qeewiki/books/avr-guide/timer-on-the-atmega8
http://www.engblaze.com/microcontroller-tutorial-avr-and-arduino-timer-interrupts/
Se eksempel på Cykel-computer:
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http://www.instructables.com/id/Arduino-Bike-Speedometer/?ALLSTEPS
http://letsmakerobots.com/node/28278
God og stor samling Tutorials: http://tronixstuff.com/tutorials/
http://www.let-elektronik.dk/tutorials
en samling links til Jeremy Bloms videos:
http://harperjiangnew.blogspot.dk/2013/05/arduino-using-atmegas-internal.html
http://tom-itx.dyndns.org:81/~webpage/abcminiuser/articles/avr_timers_index.php
CTC mode: http://maxembedded.com/2011/06/28/avr-timers-timer1/
http://www.youtube.com/watch?v=CRJUdf5TTQQ
Link til datablad: