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Im trying to make a simple RPM meter using an ATMega328.

I have an encoder on the motor which has 306 interrupts per rotation (as the motor encoder has 3 spokes which interrupt on rising and falling edge, the motor is geared 51:1 and so 6 transitions * 51 = 306 interrupts per wheel rotation ) , and I am using a timer interrupting every 1ms, however in the interrupt it set to recalculate every 1 second.

There seems to be 2 problems. 1) RPM never goes below 60, instead its either 0 or RPM >= 60 2) Reducing the time interval causes it to always be 0 (as far as I can tell)

Here is the code

    int main(void){

        int temprpm = leftRPM;
        printf("Revs: %d \n",temprpm);

    return 0;

ISR (INT0_vect){



    if(counter == 1000){

        int tempticks = ticksM1;
        leftRPM = ((tempticks - lastM1)/306)*1*60;
        lastM1 = tempticks;
        counter = 0;    



Anything that is not declared in that code is declared globally and as an int, ticksM1 is also volatile.

The macros are AVR macros for the interrupts.

The purpose of the multiplying by 1 for leftRPM represents time, ideally I want to use 1ms without the if statement so the 1 would then be 1000

share|improve this question
strive for a minimal example. that's a lot of unnecessary code and undefined macros.... – Karoly Horvath Apr 3 '14 at 17:53
It would be easier to read with fewer blank lines. – Keith Thompson Apr 3 '14 at 18:03
Updated, the macros are AVR macros for defined an ISR – binarysmacker Apr 3 '14 at 18:19
leftRPM will be 0, or 60, or 120, or 180, ... – pmg Apr 3 '14 at 18:43
up vote 3 down vote accepted

For a speed between 60 and 120 RPM the result of ((tempticks - lastM1)/306) will be 1 and below 60 RPM it will be zero. Your output will always be a multiple of 60

The first improvement I would suggest is not to perform expensive arithmetic in the ISR. It is unnecessary - store the speed in raw counts-per-second, and convert to RPM only for display.

Second, perform the multiply before the divide to avoid unnecessarily discarding information. Then for example at 60RPM (306CPS) you have (306 * 60) / 306 == 60. Even as low as 1RPM you get (6 * 60) / 306 == 1. In fact it gives you a potential resolution of approximately 0.2RPM as opposed to 60RPM! To allow the parameters to be easily maintained; I recommend using symbolic constants rather than magic numbers.




    if(counter == MILLISEC_PER_SAMPLE)

        int tempticks = ticksM1;

        leftCPS = tempticks - lastM1 ;

        lastM1 = tempticks;

        counter = 0;    


Then in main():


If you want better that 1RPM resolution you might consider

int temprpm_x10 = (leftCPS * SAMPLES_PER_MINUTE) / (ENCODER_COUNTS_PER_REV / 10) ;

then displaying:

printf( "%d.%d", temprpm / 10, temprpm % 10 ) ;

Given the potential resolution of 0.2 rpm by this method, higher resolution display is unnecessary, though you could use a moving-average to improve resolution at the expense of some "display-lag".

Alternatively now that the calculation of RPM is no longer in the ISR you might afford a floating point operation:

float temprpm = ((float)leftCPS * (float)SAMPLES_PER_MINUTE ) / (float)ENCODER_COUNTS_PER_REV ;
printf( "%f", temprpm ) ;

Another potential issue is that ticksM1++ and tempticks = ticksM1, and the reading of leftRPM (or leftCPS in my solution) are not atomic operations, and can result in an incorrect value being read if interrupt nesting is supported (and even if it is not in the case of the access from outside the interrupt context). If the maximum rate will be less that 256 cps (42RPM) then you might get away with an atomic 8 bit counter; you cal alternatively reduce your sampling period to ensure the count is always less that 256. Failing that the simplest solution is to disable interrupts while reading or updating non-atomic variables shared across interrupt and thread contexts.

share|improve this answer
I think im getting a bit confused. Let me see if im right first, geared 51 and 6 counts per back shaft revs gives 306 counts per front shaft revs (back shaft is straight from motor). So tickdifference/306. Then multiply by 1000 as its inside a 1ms interupt to get per second number then multiply by 60 for RPM. After testing it seems like 1ms is just too quick for the actual encoder as it sometimes only sees a change of 0 (need to work out if this is right!) so inside the ISR if statement for 25 counter counts. So now instead of multiplication by 1000 its only 40, after simplifying leftCPS*400 ? – binarysmacker Apr 3 '14 at 19:05
(leftCPS*40)/6 I mean sorry – binarysmacker Apr 3 '14 at 19:13
@binarysmacker: with respect division, yes a power of two is ideal, but the value is determined by your encoder resolution. You could tweak the sample time (use a value other than 1000) to compensate for that, but it would be an optimisation at the expense of readability perhaps. – Clifford Apr 3 '14 at 19:41
No! Do the feedback in CPS - your feedback loop does not care about the error signal units, whatever the range and resolution of the input, it is compensated for by the control-loop coefficients. You rather convert your set-point from RPM to CPS (or whatever your error signal units are), not the otherway around. In raw counts you have a very high resolution input, converting to RPM even at 0.2 RPM throws that away. See my answer to… – Clifford Apr 3 '14 at 20:10
This may be of use too: – Clifford Apr 3 '14 at 20:28

It's integer division. You would probably get better results with something like this:

leftRPM = ((tempticks - lastM1)/6);
share|improve this answer
or enforce float division and then round – Andrey Apr 3 '14 at 17:53
For best effect, take the 60 out too: leftRPM = (tempticks - lastM1)/60; – Deduplicator Apr 3 '14 at 17:55
@Deduplicator: Good idea. Done. – Fred Larson Apr 3 '14 at 17:56
If you decide to use float conversions to perform the division make sure that's OK to do in an ISR. Often there are special considerations for floating point operations in an ISR. – Michael Burr Apr 3 '14 at 18:12
@binarysmacker: I am unfairly blamed ;-) - I edited the text to match the code - it was the code that was wrong however! Should have raised a comment first perhaps? I suspect this answer used the code rather than the question text in any case, so the edit may not have changed this answer in any case. – Clifford Apr 3 '14 at 19:59

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