Simple low pass filter in fixed point

Question

I have a simple circuit setup to read the light level via an LDR into an Arduino. I'm trying to implement a simple low pass filter to data read in. How best to tackle this given that analogRead() returns an unsigned int.

I have tried to implement a simple fixed point representation but am unsure if this is the correct approach.

Here's a code snippet:

#define WLPF 0.1
#define FIXED_SHIFT 4

ldr_val = ((int)analogRead(A0)) << FIXED_SHIFT;
 while (true) {
    int newval = (int)analogRead(A0) << FIXED_SHIFT;
    ldr_val += WLPF*(newval - ldr_val);
    Serial.println(ldr_val >> FIXED_SHIFT, DEC);
}

Note the resolution of the ADC is 10 bits and I am working with an 8-bit Arduino Micro.

Answer 1

I'm paraphrasing from the book "Musical Applications of Microprocessors" by Hal Chamberlin, page 438:

If you allow large numbers in the accumulator, then you can make a first-order low-pass filter with one multiplication and some right-shifts.

  out = accum >> k
  accum = accum - out + in

Choose 'k' to change the cutoff frequency. The more shifts, the lower the low-pass cutoff, but the larger the value in the accumulator. With a 10-bit value from analog_read(), you can easily right-shift 4 places, and still have 2 bits of headroom in the accumulator (as @datafiddler noted above).

Cypress has some app-notes for their PSOC chips with similar equations, and using shifts. I remember one had a nice table that related number of shifts to the cutoff frequency. The approximate cutoff frequency is the sampling frequency divided by 2-pi times the gain factor:

f0 ~ fs / (2 pi a)

where 'a' is that power of two.

Keep smoothin' those signals!

Answer 2

On a device with no FPU rather then multiplying by 0.1 (which in any case make this a floating not fixed point implementation) you should divide by 10:

#define WLPF_DIV 10

...

ldr_val += (newval - ldr_val) / WLPF_DIV;

However division on an 8 bit processor is often expensive (although probably dwarfed by the execution time of Serial.println() in the loop - but that is a different issue). Instead it is more efficient to select a power of two so that the division can be performed with a right-shift.

#define WLPF_SHIFT 3  // divide by 8

...

ldr_val += (newval - ldr_val) >> WLPF_SHIFT ;

The use of signed int is problematic since right-shift of a signed type is undefined behaviour. In this case this can be resolved by changing the code to:

#define WLPF_DIV 8

... 

ldr_val += (newval - ldr_val) / WLPF_DIV ;

The compiler will most likely spot the power-of-two constant and generate the code using an arithmetic-shift-right in any case. However you would probably do better to reconsider the data type.

You still have a right-shift in the Serial.println() call, but that too could by replaced with a divide-by-16:

#define WLPF_DIV 8
#define FIXED_MUL  16

ldr_val = (int)analogRead(A0) * FIXED_MUL  ;

for(;;)
{
    int newval = (int)analogRead(A0) * FIXED_MUL ;
    ldr_val += (newval - ldr_val) / WLPF_DIV 
    Serial.println(ldr_val / FIXED_MUL, DEC);
}

Non-deterministic output of the data on a per sample basis is not going to make for a very accurate filter and will dominate the timing in any case so you have little control over the frequency response and it will not be stable. It also makes the previous performance optimisations rather pointless. You may want to think about that if it is important in your application - but that is a different question.

Answer 3

Stick with integer arithmetics:

#define WLPF 9

filtered = ((long)filtered * WLPF + newValue) / (WLPF + 1);