Counting Pulses Method 'Tachometer'

[carl]

Hi All,

I am a bit stuck, and hope you can help.
I am trying to measure accurate RPM (within 1%) when using a 13ppr quad encoder (so 52 edge detection per revolution). Max speed is 2000rpm. min Speed TBD.

I have tried the 'timing method' and 95% of the time it is within 1% (even with averaging algorithms), however I cannot improve on this, and so I thought that I would try the 'counting method' to see if any improvement was possible. Also I need to detect direction later on, so the counting method (with Ttelmah's encoder detection code) is likely to be preferable.

My results are more than 10% off with the counting method i.e. when encoder rotating at 2000rpm, the reading is 2200rpm. Can anyone suggest anything or see any obvious errors below?

The environmental factors are good (encoder, connected motor, receiver etc) as they have already been fully tested using the timing method.

the code is here:

[temtronic]

hmm....
RPM = (((sensor_pulses/0.5)/52) * 60 ); //Calculate RPM: sensor_pulses / 0.5s / 52 * 60

perhaps it's a 'math thing'.
multiplying(*2) then dividing(by 52) then multiplying(times 60) seems 'silly' to me and possibly prone to errors.
I'm pretty sure you can simplify the equation to a more 'robust' algorithm.

just thinking...it might be worth a few minutes to recode/recompile/retest and report back.....


Jay

[rnielsen]

You didn't say if you need to know the direction of the encoder's rotation. If you don't, and the encoder has an index signal available, You could simply count the index pulse which would only happen once per revolution...

Ronald

[carl]

Thanks for replying.

Simplifying the maths doesn't make any difference.
Initially i just transmitted the 'sensor_pulses' alone, so no maths at all, and then this value was plugged into the rpm equation (manually with calculator), and the result is exactly the same.

The circuit design is already done, so ideally i do not want to make any hardware changes. Direction detection is required, but i can look at that later, however this does mean that the quad detection firmware (currently commented out) will be required.

I know i could use an index as the 'tick' instead of the timer, but the encoder design does not include an index, hence the reason for using the timer. and would it make a difference anyway?

I think trying to work out why the 'sensor_pulses' value is out is the key, but i can't work it out.

[asmboy]

what var type results from an int16 /.5 ??

does the compiler optimize the .LST file to treat it as a binary *2
or is it float ??

i too am puzzled by the multi-constant mess-o-math Jay metioned.

[PCM programmer]

Your rpm is 10% longer than it should be. What thing in your code is
associated with the number 10 ? Answer: Your loop counter.
Look closely at that. Is it really counting off 10 interrupts before it sets
meas_done=true ?

[Mike Walne]

Try changing this

[carl]

Preview
PostPosted: Wed Nov 19, 2014 3:13 am Post subject:
Hi PCM,

I will look into it, but potentially what could be the issue?

Could the two interrupts be in conflict?
so if the program is already in the int_rb routine, and the int_timer fires, would it go and do that interrupt (nested interrupts sort of), or would it be missed (or delayed) therefore increasing the time (so 0.5s becomes 0.55 etc)
I suppose, I could prioritise the timer interrupt (never done this before), so that the timer will always fire first, (even at the expense of missing a pulse, assuming the error is tolerable).

I will look into it and get back to you thanks.

ASM/Jay it is not the maths or type cast, as the result ended up being the same, when I only viewed 'sensor_pulses' alone. but I agree with your point and will type cast correctly when it is required (and simplify the equation) thanks

Hi Mike,

yes obvious plan thanks - I will try it.

Carl

[carl]

Its way out!

changed the loops to 'one' = tick every 49.92mS.
sensor_pulses = 180 at 2000rpm.

plugging 180 into the equation gives:

RPM = ((180/0.04992) / 52) * 60
RPM = 4160

either my count is way out for some reason, or the formula above is incorrect?

EDIT: sorry, if loops = 1, then that = tick every 100ms.
so:

RPM = ((180/0.09984) / 52) * 60
RPM = 2080.

Which is better (under 5%), and indicates that the 'loops' is going wrong somewhere when I increase the loops to 10 or 20. But this is exactly the opposite of what it is supposed to do isn't it (accumulated counts over longer time period = better resolution).

[PCM programmer]

You can investigate this three ways:

1. Look at the #int_timer2 routine and mentally check how many
interrupts it takes before meas_done goes TRUE.

2. Using a lined piece of paper, write down each interrupt, and the value
of loops after the interrupt has occurred, and when meas_done goes TRUE.

3. Strip your program down and test the loop frequency in hardware.
Sync on a pulse inside the isr with your oscilloscope (assuming your
scope has a built-in frequency counter. Mine does). I get about 1.8 Hz.
Your code expects 2.0 Hz. What do you have to do, to make it run at 2.0 Hz ?

[carl]

Hi PCM,

Thanks so much for replying.
whilst you have written this, I have worked it out.

The way I was using the formula was incorrect.

I thought that 1 loop meant one timer period = 49.98ms
however 1 loop is 2 x timer periods
3 loops is 4 x timer periods etc

results measured and then recalculated as below:

Loops sensor_counts Equation RPM
0 94 (94/0.05/52 * 60) 2169
1 180 (180/0.1/52 * 60) 2076
2 266 (266/0.15/52 * 60) 2046
5 524 (524/0.3/52 * 60) 2015
10 961 (961/0.55/52 * 60) 2016
20 1824 (1824/1.05/52 * 60) 2004


So the resolution increases, when the time capture is increased
Of course the drawback here is increased refresh rate, but I can alter this by increasing the encoder PPR to say 50ppr (200 edges). Wouldn't this have the same effect as extended time capture?

Thanks, I can now move onto figuring out how to detect the direction and transmit it along with the RPM at the same time - nice!

Thanks
Carl

[PCM programmer]

Your theory is that your loop doesn't run at 20 Hz (49.98ms period).
I made a test program to test your theory. The following program
produces a pulse on my scope that syncs at 20.017 Hz.

[carl]

Hi PCM,

Let me have a think about this tomorrow - thanks for all your help as always.

[Mike Walne]

[carl]

thanks mike,

totally understand and agree.
the logic is not correct. will look at this again tomorrow.

carl