# Linear interpolation in direct digital synthesis

I'm working on a microcontroller DDS project in C and am having some trouble figuring out how to compute a linear interpolation to smooth the output values. The program as it stands now
uses the top 8 bits of a 24 bit accumulator as an index to an array of 8 bit output values. I need to come up with a function that will take the middle and lower byte of the accumulator and generate a value in between the "previous" and "next" value in the array. This would be straightforward enough on fast hardware, but since I'm using a microcontroller I really need to avoid doing any floating point operations or divisions!

With those restrictions, I'm not certain of a way to go about getting an 8 bit interpolated value from my two 8 bit input numbers and the lower 2 byes of the accumulator, which represents the "distance" between the two input values. Thanks in advance for any advice!

CLARIFICATION

DDS = Direct Digital Synthesis

in DDS a waveform is generated from a lookup table using a phase accumulator. The phase accumulator usually contains an integer component and a fractional component. The integer component is used as an index into the lookup table. In simple DDS implementations the fractional part is ignored, but for higher quality output the fractional component is used to interpolate (usually just linear interpolation) between adjacent lookup table values. For the above question we are looking at how to efficiently perform this linear interpolation between two lookup table values for a given fraction, f, where `0 <= f < 1`.

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What is a DDS? –  Prof. Falken Oct 11 '10 at 11:35
DDS = Direct Digital Synthesis - used for waveform generation in audio/radio/communications/etc –  Paul R Oct 11 '10 at 11:59

Assuming you have a table of waveform values (either one quadrant or four quadrants, it doesn't matter) then one possible optimisation is to store the delta values betwen successive table values. I.e. if you have e.g. `N = 256` and a waveform table `LUT[N]` then you also have a table of delta values, `LUT_delta[N]`. The relationship between the two precomputed tables is `LUT_delta[i] = LUT[i+1] - LUT[i]`. So instead of looking up two consecutive table values, `LUT[i]` and `LUT[i+1]`, subtracting these to get the delta, then doing the interpolation, you just look up the first table value, `LUT[i]`, and the delta, `LUT_delta[i]` and then calculate the interpolated value. This requires the same number of table lookups, but fewer math operations. You should be able to do the interpolation with a single multiply-accumulate instruction if you're using a DSP, otherwise it's a multiply + scale + add on a general purpose CPU. Also if you interleave the `LUT` and `LUT_delta` values you may be able to look up `LUT[i]` and `LUT_delta[i]` with a single read and then unpack the two values.

Pseudo-code:

``````extract integer LUT index, i, from accumulator // just need a shift for this
extract fractional part of accumulator, f // mask or subtract to get f
get p = LUT[i] // lookup waveform value
get delta = LUT_delta[i] // lookup delta
calculate p_interp = p + p_delta * f // single multiply-accumulate instruction on most DSPs - need scaling on general purpose CPUs
``````
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I'm probably not understanding you correctly - but with a 24 bit accumulator wouldn't that mean I'd have to store a delta value for all 2^16 increments between each point in my table? If I had that kind of space I would've just stored the table at higher resolution and not bothered with interpolation! :) –  Bitrex Oct 11 '10 at 12:23
@Bitrex - no if you have an N point table (e.g. N = 256) then you just need a second N point table for the deltas, where `LUT_delta[i] = LUT[i+1] - LUT[i]`. –  Paul R Oct 11 '10 at 12:37
Ah, I see. I think I have enough room for a table that size! –  Bitrex Oct 11 '10 at 12:44
@Bitrex: you might want to benchmark first, without the second table, and then only consider this optimisation if you really need it. Use powers of 2 for table size etc, as another poster said. Also note that the delta values need to be signed (unless you're just using a single quadrant table). –  Paul R Oct 11 '10 at 12:50

To make linear interpolation without doing division, you should make sure that your denominator is a power of 2.

value(x) = previous,
value(x+1) = next value(x + dx) = previous + (next - previous) * dx

Your question is, how do I compute dx ? The trick is to have your interpolation index (the 16 low bit of your accumulator) computed so that the maximum value (dx = 1) is a power of two :

``````value(x + dx) = previous + ((next - previous) * index) / 1024
``````

Here, you have computed your step value, so that the maximum step is 1024 and corresônds to dx=1. Index = 512 is for dx=0.5 etc...

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I see, so in my case with a 24 bit accumulator using the top 8 bits as an index (2^16 step value) the division should be by 2^16 or a 16 bit right shift. –  Bitrex Oct 11 '10 at 12:29
Yes, the problem being that you must be able to store (next - previous)*2^16 in your computation. –  shodanex Oct 11 '10 at 13:02

If you want better precision, i'd suggest checking the lower bits of the accumulator first. For example, if we want 4 output values instead of 1:

``````Acc += 0x2000;
uint lower_bits = Acc & 0xffff;
int rl = LUT[ Acc >> 16];
int rh = LUT[(Acc >> 16) + 1];
if (lower_bits < 0x4000)
return rl;
if (lower_bits < 0x8000)
return (rl * 3 + rh) >> 2;
if (lower_bits < 0xC000)
return (rl + rh) >> 1;
return (rl + rh * 3) >> 2;
``````
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If you really need the speed, check out AVR assembler.

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Linear interpolation between two values, a and b is (a+b)/2.

This is easy in simple hardware and involves no division or floating point.

Divide-by-2 == shift right one bit.

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That only interpolates the mid-point - for the above question you probably need to interpolate an arbitrary point. –  Paul R Oct 11 '10 at 11:55
"Arbitrary"? The mid-point seems as arbitrary as any other point. –  S.Lott Oct 11 '10 at 12:26
@S.Lott: if you read the question he's doing DDS with a phase accumulator - the fractional part of the phase accumulator determines the point between two values at which you need to interpolate. As for "arbitrary", my dictionary says: 2. Mathematics (of a constant or other quantity) of unspecified value. –  Paul R Oct 11 '10 at 12:46
@Paul R: "generate a value in between the "previous" and "next" value in the array" Somehow doesn't mean "midpoint"? Interesting. Do you think the question should be updated to supply this missing piece of the puzzle? –  S.Lott Oct 11 '10 at 20:05
@S.Lott: I think the OP is probably assuming (wrongly) that most people on SO will be familiar with DDS and phase accumulators. –  Paul R Oct 11 '10 at 20:56
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