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Secrets of Arduino PWM
Pulse-width modulation (PWM) can be implemented on the Arduino in several ways. This article explains simple PWM techniques, as well as how to use the PWM registers directly for more control over the duty cycle and frequency. This article focuses on the Arduino Diecimila and Duemilanove models, which use the ATmega168 or ATmega328.If you're unfamiliar with Pulse Width Modulation, see the tutorial. Briefly, a PWM signal is a digital square wave, where the frequency is constant, but that fraction of the time the signal is on (the duty cycle) can be varied between 0 and 100%.
PWM has several uses:
Simple Pulse Width Modulation with
The Arduino's programming language makes PWM easy to use; simply call
The ATmega328P has three timers known as Timer 0, Timer 1, and Timer 2. Each timer has two output compare registers that control the PWM width for the timer's two outputs: when the timer reaches the compare register value, the corresponding output is toggled. The two outputs for each timer will normally have the same frequency, but can have different duty cycles (depending on the respective output compare register).
Each of the timers has a prescaler that generates the timer clock by dividing the system clock by a prescale factor such as 1, 8, 64, 256, or 1024. The Arduino has a system clock of 16MHz and the timer clock frequency will be the system clock frequency divided by the prescale factor. Note that Timer 2 has a different set of prescale values from the other timers.
The timers are complicated by several different modes. The main PWM modes are "Fast PWM" and "Phase-correct PWM", which will be described below. The timer can either run from 0 to 255, or from 0 to a fixed value. (The 16-bit Timer 1 has additional modes to supports timer values up to 16 bits.) Each output can also be inverted.
The timers can also generate interrupts on overflow and/or match against either output compare register, but that's beyond the scope of this article.
The following diagram shows the outputs for two particular values of OCRnA and OCRnB. Note that both outputs have the same frequency, matching the frequency of a complete timer cycle.
The following code fragment sets up fast PWM on pins 3 and 11 (Timer 2). To summarize the register settings, setting the waveform generation mode bits WGM to 011 selects fast PWM. Setting the COM2A bits and COM2B bits to 10 provides non-inverted PWM for outputs A and B. Setting the CS bits to 100 sets the prescaler to divide the clock by 64. (Since the bits are different for the different timers, consult the datasheet for the right values.) The output compare registers are arbitrarily set to 180 and 50 to control the PWM duty cycle of outputs A and B. (Of course, you can modify the registers directly instead of using
The following code fragment sets up phase-correct PWM on pins 3 and 11 (Timer 2). The waveform generation mode bits WGM are set to to 001 for phase-correct PWM. The other bits are the same as for fast PWM.
In the following diagram, the timer resets when it matches OCRnA, yielding a faster output frequency for OCnB than in the previous diagrams. Note how OCnA toggles once for each timer reset.
The following code fragment sets up fast PWM on pins 3 and 11 (Timer 2), using OCR2A as the top value for the timer. The waveform generation mode bits WGM are set to to 111 for fast PWM with OCRA controlling the top limit. The OCR2A top limit is arbitrarily set to 180, and the OCR2B compare register is arbitrarily set to 50. OCR2A's mode is set to "Toggle on Compare Match" by setting the COM2A bits to 01.
The following code fragment sets up phase-correct PWM on pins 3 and 11 (Timer 2), using OCR2A as the top value for the timer. The waveform generation mode bits WGM are set to to 101 for phase-correct PWM with OCRA controlling the top limit. The OCR2A top limit is arbitrarily set to 180, and the OCR2B compare register is arbitrarily set to 50. OCR2A's mode is set to "Toggle on Compare Match" by setting the COM2A bits to 01.
Now consider phase-correct PWM mode with the timer counting up to an OCRnA value of 3. The timer values will be 012321012321... There are 6 clock cycles in each timer cycle (012321). Thus the frequency will be divided by 6. The duty cycle will be a multiple of 33%, since the output can be high for 0, 2, 4, or 6 of the 6 cycles. Likewise, if the timer counts up to 255 and back down, there will be 510 clock cycles in each timer cycle, and the duty cycle will be a multiple of 1/255. To summarize, phase-correct PWM divides by 2N, where N is the maximum timer value.
The second important timing difference is that fast PWM holds the output high for one cycle longer than the output compare register value. The motivation for this is that for fast PWM counting to 255, the duty cycle can be from 0 to 256 cycles, but the output compare register can only hold a value from 0 to 255. What happens to the missing value? The fast PWM mode keeps the output high for N+1 cycles when the output compare register is set to N so an output compare register value of 255 is 100% duty cycle, but an output compare register value of 0 is not 0% duty cycle but 1/256 duty cycle. This is unlike phase-correct PWM, where a register value of 255 is 100% duty cycle and a value of 0 is a 0% duty cycle.
The Arduino performs some initialization of the timers. The Arduino initializes the prescaler on all three timers to divide the clock by 64. Timer 0 is initialized to Fast PWM, while Timer 1 and Timer 2 is initialized to Phase Correct PWM. See the Arduino source file wiring.cfor details.
The Arduino uses Timer 0 internally for the
The
If you use
Some other Arduino models use dfferent AVR processors with similar timers. The Arduino Mega uses the ATmega1280 (datasheet), which has four 16-bit timers with 3 outputs each and two 8-bit timers with 2 outputs each. Only 14 of the PWM outputs are supported by the Arduino Wiring library, however. Some older Arduino models use the ATmega8 (datasheet), which has three timers but only 3 PWM outputs: Timer 0 has no PWM, Timer 1 is 16 bits and has two PWM outputs, and Timer 2 is 8 bits and has one PWM output.
PWM has several uses:
- Dimming an LED
- Providing an analog output; if the digital output is filtered, it will provide an analog voltage between 0% and 100% .
- Generating audio signals.
- Providing variable speed control for motors.
- Generating a modulated signal, for example to drive an infrared LED for a remote control.
Simple Pulse Width Modulation with analogWrite
The Arduino's programming language makes PWM easy to use; simply call analogWrite(pin, dutyCycle)
, where dutyCycle
is a value from 0 to 255, and pin
is one of the PWM pins (3, 5, 6, 9, 10, or 11). The analogWrite
function provides a simple interface to the hardware PWM, but doesn't provide any control over frequency. (Note that despite the function name, the output is a digital signal.)Probably 99% of the readers can stop here, and just use analogWrite
, but there are other options that provide more flexibility.Bit-banging Pulse Width Modulation
You can "manually" implement PWM on any pin by repeatedly turning the pin on and off for the desired times. e.g.void setup() { pinMode(13, OUTPUT); } void loop() { digitalWrite(13, HIGH); delayMicroseconds(100); // Approximately 10% duty cycle @ 1KHz digitalWrite(13, LOW); delayMicroseconds(900); }This technique has the advantage that it can use any digital output pin. In addition, you have full control the duty cycle and frequency. One major disadvantage is that any interrupts will affect the timing, which can cause considerable jitter unless you disable interrupts. A second disadvantage is you can't leave the output running while the processor does something else. Finally, it's difficult to determine the appropriate constants for a particular duty cycle and frequency unless you either carefully count cycles, or tweak the values while watching an oscilloscope.
Using the ATmega PWM registers directly
The ATmega168P/328P chip has three PWM timers, controlling 6 PWM outputs. By manipulating the chip's timer registers directly, you can obtain more control than theanalogWrite
function provides.The AVR ATmega328P datasheet provides a detailed description of the PWM timers, but the datasheet can be difficult to understand, due to the many different control and output modes of the timers. The following attempts to clarify the use of the timers.The ATmega328P has three timers known as Timer 0, Timer 1, and Timer 2. Each timer has two output compare registers that control the PWM width for the timer's two outputs: when the timer reaches the compare register value, the corresponding output is toggled. The two outputs for each timer will normally have the same frequency, but can have different duty cycles (depending on the respective output compare register).
Each of the timers has a prescaler that generates the timer clock by dividing the system clock by a prescale factor such as 1, 8, 64, 256, or 1024. The Arduino has a system clock of 16MHz and the timer clock frequency will be the system clock frequency divided by the prescale factor. Note that Timer 2 has a different set of prescale values from the other timers.
The timers are complicated by several different modes. The main PWM modes are "Fast PWM" and "Phase-correct PWM", which will be described below. The timer can either run from 0 to 255, or from 0 to a fixed value. (The 16-bit Timer 1 has additional modes to supports timer values up to 16 bits.) Each output can also be inverted.
The timers can also generate interrupts on overflow and/or match against either output compare register, but that's beyond the scope of this article.
Timer Registers
Several registers are used to control each timer. The Timer/Counter Control Registers TCCRnA and TCCRnB hold the main control bits for the timer. (Note that TCCRnA and TCCRnB do not correspond to the outputs A and B.) These registers hold several groups of bits:- Waveform Generation Mode bits (WGM): these control the overall mode of the timer. (These bits are split between TCCRnA and TCCRnB.)
- Clock Select bits (CS): these control the clock prescaler
- Compare Match Output A Mode bits (COMnA): these enable/disable/invert output A
- Compare Match Output B Mode bits (COMnB): these enable/disable/invert output B
Fast PWM
In the simplest PWM mode, the timer repeatedly counts from 0 to 255. The output turns on when the timer is at 0, and turns off when the timer matches the output compare register. The higher the value in the output compare register, the higher the duty cycle. This mode is known as Fast PWM Mode.The following diagram shows the outputs for two particular values of OCRnA and OCRnB. Note that both outputs have the same frequency, matching the frequency of a complete timer cycle.
The following code fragment sets up fast PWM on pins 3 and 11 (Timer 2). To summarize the register settings, setting the waveform generation mode bits WGM to 011 selects fast PWM. Setting the COM2A bits and COM2B bits to 10 provides non-inverted PWM for outputs A and B. Setting the CS bits to 100 sets the prescaler to divide the clock by 64. (Since the bits are different for the different timers, consult the datasheet for the right values.) The output compare registers are arbitrarily set to 180 and 50 to control the PWM duty cycle of outputs A and B. (Of course, you can modify the registers directly instead of using
pinMode
, but you do need to set the pins to output.)pinMode(3, OUTPUT); pinMode(11, OUTPUT); TCCR2A = _BV(COM2A1) | _BV(COM2B1) | _BV(WGM21) | _BV(WGM20); TCCR2B = _BV(CS22); OCR2A = 180; OCR2B = 50;On the Arduino Duemilanove, these values yield:
- Output A frequency: 16 MHz / 64 / 256 = 976.5625Hz
- Output A duty cycle: (180+1) / 256 = 70.7%
- Output B frequency: 16 MHz / 64 / 256 = 976.5625Hz
- Output B duty cycle: (50+1) / 256 = 19.9%
Phase-Correct PWM
The second PWM mode is called phase-correct PWM. In this mode, the timer counts from 0 to 255 and then back down to 0. The output turns off as the timer hits the output compare register value on the way up, and turns back on as the timer hits the output compare register value on the way down. The result is a more symmetrical output. The output frequency will be approximately half of the value for fast PWM mode, because the timer runs both up and down.The following code fragment sets up phase-correct PWM on pins 3 and 11 (Timer 2). The waveform generation mode bits WGM are set to to 001 for phase-correct PWM. The other bits are the same as for fast PWM.
pinMode(3, OUTPUT); pinMode(11, OUTPUT); TCCR2A = _BV(COM2A1) | _BV(COM2B1) | _BV(WGM20); TCCR2B = _BV(CS22); OCR2A = 180; OCR2B = 50;On the Arduino Duemilanove, these values yield:
- Output A frequency: 16 MHz / 64 / 255 / 2 = 490.196Hz
- Output A duty cycle: 180 / 255 = 70.6%
- Output B frequency: 16 MHz / 64 / 255 / 2 = 490.196Hz
- Output B duty cycle: 50 / 255 = 19.6%
Varying the timer top limit: fast PWM
Both fast PWM and phase correct PWM have an additional mode that gives control over the output frequency. In this mode, the timer counts from 0 to OCRA (the value of output compare register A), rather than from 0 to 255. This gives much more control over the output frequency than the previous modes. (For even more frequency control, use the 16-bit Timer 1.)Note that in this mode, only output B can be used for PWM; OCRA cannot be used both as the top value and the PWM compare value. However, there is a special-case mode "Toggle OCnA on Compare Match" that will toggle output A at the end of each cycle, generating a fixed 50% duty cycle and half frequency in this case. The examples will use this mode.In the following diagram, the timer resets when it matches OCRnA, yielding a faster output frequency for OCnB than in the previous diagrams. Note how OCnA toggles once for each timer reset.
The following code fragment sets up fast PWM on pins 3 and 11 (Timer 2), using OCR2A as the top value for the timer. The waveform generation mode bits WGM are set to to 111 for fast PWM with OCRA controlling the top limit. The OCR2A top limit is arbitrarily set to 180, and the OCR2B compare register is arbitrarily set to 50. OCR2A's mode is set to "Toggle on Compare Match" by setting the COM2A bits to 01.
pinMode(3, OUTPUT); pinMode(11, OUTPUT); TCCR2A = _BV(COM2A0) | _BV(COM2B1) | _BV(WGM21) | _BV(WGM20); TCCR2B = _BV(WGM22) | _BV(CS22); OCR2A = 180; OCR2B = 50;On the Arduino Duemilanove, these values yield:
- Output A frequency: 16 MHz / 64 / (180+1) / 2 = 690.6Hz
- Output A duty cycle: 50%
- Output B frequency: 16 MHz / 64 / (180+1) = 1381.2Hz
- Output B duty cycle: (50+1) / (180+1) = 28.2%
Varying the timer top limit: phase-correct PWM
Similarly, the timer can be configured in phase-correct PWM mode to reset when it reaches OCRnA.The following code fragment sets up phase-correct PWM on pins 3 and 11 (Timer 2), using OCR2A as the top value for the timer. The waveform generation mode bits WGM are set to to 101 for phase-correct PWM with OCRA controlling the top limit. The OCR2A top limit is arbitrarily set to 180, and the OCR2B compare register is arbitrarily set to 50. OCR2A's mode is set to "Toggle on Compare Match" by setting the COM2A bits to 01.
pinMode(3, OUTPUT); pinMode(11, OUTPUT); TCCR2A = _BV(COM2A0) | _BV(COM2B1) | _BV(WGM20); TCCR2B = _BV(WGM22) | _BV(CS22); OCR2A = 180; OCR2B = 50;On the Arduino Duemilanove, these values yield:
- Output A frequency: 16 MHz / 64 / 180 / 2 / 2 = 347.2Hz
- Output A duty cycle: 50%
- Output B frequency: 16 MHz / 64 / 180 / 2 = 694.4Hz
- Output B duty cycle: 50 / 180 = 27.8%
Off-by-one
You may have noticed that fast PWM and phase-correct PWM seem to be off-by-one with respect to each other, dividing by 256 versus 255 and adding one in various places. The documentation is a bit opaque here, so I'll explain in a bit of detail.Suppose the timer is set to fast PWM mode and is set to count up to an OCRnA value of 3. The timer will take on the values 012301230123... Note that there are 4 clock cycles in each timer cycle. Thus, the frequency will be divided by 4, not 3. The duty cycle will be a multiple of 25%, since the output can be high for 0, 1, 2, 3, or 4 cycles out of the four. Likewise, if the timer counts up to 255, there will be 256 clock cycles in each timer cycle, and the duty cycle will be a multiple of 1/256. To summarize, fast PWM divides by N+1 where N is the maximum timer value (either OCRnA or 255).Now consider phase-correct PWM mode with the timer counting up to an OCRnA value of 3. The timer values will be 012321012321... There are 6 clock cycles in each timer cycle (012321). Thus the frequency will be divided by 6. The duty cycle will be a multiple of 33%, since the output can be high for 0, 2, 4, or 6 of the 6 cycles. Likewise, if the timer counts up to 255 and back down, there will be 510 clock cycles in each timer cycle, and the duty cycle will be a multiple of 1/255. To summarize, phase-correct PWM divides by 2N, where N is the maximum timer value.
The second important timing difference is that fast PWM holds the output high for one cycle longer than the output compare register value. The motivation for this is that for fast PWM counting to 255, the duty cycle can be from 0 to 256 cycles, but the output compare register can only hold a value from 0 to 255. What happens to the missing value? The fast PWM mode keeps the output high for N+1 cycles when the output compare register is set to N so an output compare register value of 255 is 100% duty cycle, but an output compare register value of 0 is not 0% duty cycle but 1/256 duty cycle. This is unlike phase-correct PWM, where a register value of 255 is 100% duty cycle and a value of 0 is a 0% duty cycle.
Timers and the Arduino
The Arduino supports PWM on a subset of its output pins. It may not be immediately obvious which timer controls which output, but the following table will clarify the situation. It gives for each timer output the output pin on the Arduino (i.e. the silkscreened label on the board), the pin on the ATmega chip, and the name and bit of the output port. For instance Timer 0 output OC0A is connected to the Arduino output pin 6; it uses chip pin 12 which is also known as PD6.Timer output | Arduino output | Chip pin | Pin name |
---|---|---|---|
OC0A | 6 | 12 | PD6 |
OC0B | 5 | 11 | PD5 |
OC1A | 9 | 15 | PB1 |
OC1B | 10 | 16 | PB2 |
OC2A | 11 | 17 | PB3 |
OC2B | 3 | 5 | PD3 |
The Arduino uses Timer 0 internally for the
millis()
and delay()
functions, so be warned that changing the frequency of this timer will cause those functions to be erroneous. Using the PWM outputs is safe if you don't change the frequency, though.The
analogWrite(pin, duty_cycle)
function sets the appropriate pin to PWM and sets the appropriate output compare register to duty_cycle
(with the special case for duty cycle of 0 on Timer 0). The digitalWrite()
function turns off PWM output if called on a timer pin. The relevant code is wiring_analog.c and wiring_digital.c.If you use
analogWrite(5, 0)
you get a duty cycle of 0%, even though pin 5's timer (Timer 0) is using fast PWM. How can this be, when a fast PWM value of 0 yields a duty cycle of 1/256 as explained above? The answer is that analogWrite
"cheats"; it has special-case code to explicitly turn off the pin when called on Timer 0 with a duty cycle of 0. As a consequency, the duty cycle of 1/256 is unavailable when you use analogWrite
on Timer0, and there is a jump in the actual duty cycle between values of 0 and 1.Some other Arduino models use dfferent AVR processors with similar timers. The Arduino Mega uses the ATmega1280 (datasheet), which has four 16-bit timers with 3 outputs each and two 8-bit timers with 2 outputs each. Only 14 of the PWM outputs are supported by the Arduino Wiring library, however. Some older Arduino models use the ATmega8 (datasheet), which has three timers but only 3 PWM outputs: Timer 0 has no PWM, Timer 1 is 16 bits and has two PWM outputs, and Timer 2 is 8 bits and has one PWM output.
Troubleshooting
It can be tricky to get the PWM outputs to work. Some tips:- You need to both enable the pin for output and enable the PWM mode on the pin in order to get any output. I.e. you need to do
pinMode()
and set the COM bits. - The different timers use the control bits and prescaler differently; check the documentation for the appropriate timer.
- Some combinations of bits that you might expect to work are reserved, which means if you try to use them, they won't work. For example, toggle mode doesn't work with fast PWM to 255, or with output B.
- Make sure the bits are set the way you think. Bit operations can be tricky, so print out the register values and make sure they are what you expect.
- Make sure you're using the right output pins. See the table above.
- You'll probably want a decoupling capacitor to avoid spikes on the output.
62 comments:
As a beginning Arduino user, this is very helpful!
One question though-likely I am not understanding some subtlety.
It seems from the datasheet that the 64 pre-scale corresponds to 110. I am wondering if I am missing something, as you mention 100 as the 64 prescale divider.
Thank you!
Thanks,
Mike
I am just learning about Arduino and I have a question about your article on “Secrets of Arduino PWM”.
Your example says
pinMode(3, OUTPUT);
pinMode(11, OUTPUT);
TCCR2A = _BV(COM2A1) | _BV(COM2B1) | _BV(WGM20);
TCCR2B = _BV(CS22);
OCR2A = 180;
OCR2B = 50;
What I am confused about is previously you stated that that these examples set the clock divisor to 64. Is there a bit inversion in the writes to an AVR register?
Your line TCCR2B = _BV(CS22); would set the TCCR2B register to 00000100b.
Is there something I’m missing here?
Thanks in advance for your response.
Monty
Would you mind elaborating a bit more on how someone could use the sound card and a program such as xoscope to help debug this sort of thing? Do you mean by plugin a speaker to the arduino pin, getting it close to the computer mic and using such a software to graph the wave?
Thanks once again.
I was using the default 490 Mhz arduino analogWrite PWM and was getting horribly low torque with some small DC motors on low duty cycles. Changed it to 30Hz and now its way better, still runs smooth.
Cassiano, with a sound card oscilloscope, you connect the signal directly to the sound card through a resistor to reduce the current. There are details at http://www.ehow.com/how_2278973_use-sound-card-oscilloscope.html
The reason I am writing this comment is the following: It took me almost 6 hours till I found out (mainly in sheer desperation) that the order of setting the timer control registers TCCR2* and the output compare registers OCR2* seems to matter! If you assign an OCR before setting the corresponding TCCR the timer simply doesn't start counting.
As for debugging PWM, I think proteus ISIS is a good tool for that purpose. Proteus has a virtual osilloscope, see my post(in chinese, sorry):
http://coopermaa2nd.blogspot.com/2011/05/proteus-pwm.html
http://smacula.blogspot.com/2011/04/creating-variable-frequency-pwm-output.html
#define _BV(x) (1 << x)
see http://194.81.104.27/~brian/microprocessor/BVMacro.pdf
properly.. Thanks in advance!
If you read my article: http://www.smacula.co.uk/2011/04/creating-variable-frequency-pwm-output.html
You can actually go as low as 15Hz. I have not tried to go that low myself though, but don't see why it would not work.
Your article has been a great help, but now I am working on an Arduino Micro with an ATMEGA 32u4 processor.
All I want to do is get phase-correct PWM at the highest possible frequency on 3 pins.
Will these 2 lines do that?
TCCR1B = _BV(CS00); // change the PWM frequencey to 31.25kHz - pins 9 & 10
// timer 0B : pin 3 & 11
TCCR0B = _BV(CS00); // change the PWM frequencey to 31.25 kHz - pin 3 & 11
please let me know, if you can, by relying to my id at gmail.
Cheers,
Bob
Thank you for your library!
I modified it a bit to work with Hitachi air conditioning. But there is one momnet I can not understand. I had to increase the buffer to 600 (RAWBUF 600). But then I try to read I can read only 532 byte. While there is still 8 :( In what may be another reason of not getting all the data from the console?
Thank you! And excuse me for my english!
As Mitch Deoudes, said, "The version of this article posted at arduino.cc is missing all of the diagrams except the first one." This is still true. If you could figure out how to get the diagrams added back into the article on arduino.cc (http://arduino.cc/en/Tutorial/SecretsOfArduinoPWM) that would be great!
Thanks!
Gabriel Staples
http://electricrcaircraftguy.blogspot.com/
Since posting my last question to you, I've learned that you can turn a PWM signal into a true analog output by using an R-C filter (ex: Resistor of 10k and Capacitor of 0.1uF). I'm now guessing that you are using an R-C analog filter to turn a high-freq PWM output into a true analog signal....just like a DAC (Digital to Analog Converter). Is this correct? If so, what freq are you using, and what R-C values are you using on your filter?
In either case, for anyone who wants to see an example of this, see pgs. 217-219 of Simon Monk's book "Programming Arduino Next Steps: Going Further with Sketches." Figure 13-4 on the bottom of pg. 217 shows the R-C filter with R=10k and C=100nF (0.1uF), feeding a PWM-generated signal into an Oscilloscope, as a filtered analog signal. Figure 13-5 on pg. 219 shows the actual 1KHz wave form (a sine wave) produced by the Arduino Uno with a 10KHz PWM signal sent through this analog filter. The top sine wave is the input signal to the Arduino, as created by a nice signal generator, and the bottom sine wave (a little rougher looking), is the signal that the Arduino generated itself, again, using a 10KHz PWM signal going through that simple R-C filter. This is very cool! An R-C filter like that is only a few cents, and now you have a true analog output using a cheap Arduino! For anyone wanting to see these pages, they are viewable on Amazon here, by clicking the book image to look inside: http://www.amazon.com/Programming-Arduino-Next-Steps-Sketches/dp/0071830251.
Have fun!
~Gabriel
http://electricrcaircraftguy.blogspot.com/
http://www.ncbi.nlm.nih.gov/pubmed/24689560
please help any help would be gretly appreciated
kind regards, Mike from Mannheim, Germany
I need some help from you on my the same task.
I need to generate 4 independent PWM signals with fixed frequency of 25Khz.
I am currently using UNO. I have implemented the same code which was in this blog, setting the same PRESCALE and OUTPUT COMPARE REG for a test.
As UNO is ATMEGA 328, the FAST PWM should work on this too having same CS values.
I did not get any waveform at the desired PIN. Do you suggest me work on any other board?
Need some inputs, so that i can move in that direction.
Thank you in advance.
SAFWAN
Thanks, Dick van Fulpen, Houten (NL)
Thanks, Dick van Fulpen, Houten (NL)
I hope that helps. Good luck!
~Gabriel Staples
http://electricrcaircraftguy.blogspot.com/
pinMode(3, OUTPUT);
pinMode(11, OUTPUT);
pinMode(6, OUTPUT);
pinMode(5, OUTPUT);
pinMode(9, OUTPUT);
pinMode(10, OUTPUT);
TCCR2A = _BV(COM2A1) | _BV(COM2B1) | _BV(WGM21) | _BV(WGM20);
TCCR2B = _BV(CS22);
TCCR1A = _BV(COM1A1) | _BV(COM1B1) | _BV(WGM11) | _BV(WGM10);
TCCR1B = _BV(CS22);
TCCR0A = _BV(COM0A1) | _BV(COM0B1) | _BV(WGM01) | _BV(WGM00);
TCCR0B = _BV(CS22);
OCR2A = 180;
OCR2B = 50;
OCR1A = 180;
OCR1B = 50;
OCR0A = 180;
OCR0B = 50;
s0bes@mail.ru
s0bes68@gmail.com
Based on your info I am expecting to use Timer 2 for the Phase Correct ( ensuring A or B can have a true 0% DS output. ( I am using an H Bridge) - So for 1/2 cycle A will go from 0 to 100% and back with B at 0%.
So the questions is...As the timer is running, I do my calculation and come up with the next pulse DS and I have to write this to the OCR2A and B - whaile the output is active - does this work? - or will this reset the timer and start the pulse all over?
- I am guessing this is more in the guts of the register management for the 328 - the DS says they are double buffered, and I would assume this means you can write to them while the timer is running ( in one pulse period) -
Do I have this correct?
Can you give more instruction to make a oscilloscope from a sound card?
If this is important to you and you can't figure it out based on this and similar articles, nor can you find the solution elsewhere, contact me and I'll give you the source code with a solution to do exactly what you asked for above within 24~48 hrs of receiving $200 in my paypal account for the service. Seriously, this is not a scam. I don't sell hours, I sell expertise. You may not be needing this service that bad, in which case it won't hurt my feelings any if you don't contact me. One caveat, however: for 250kHz PWM you can only have a resolution of 64 instead of 256. If this meets your need, hit me up! You'll have working code with proof of functionality via oscilloscope screen shots I'll send you in no time.
Ken, if you have any problem with me posting this post on your website here, please contact me and let me know and I'll remove it.
Thank, It have helped me a lot.
I am having trouble trying to setup multiple interrupts, where might I find more info on that?