# The math behind Apple's Speak here example

I have a question regarding the math that Apple is using in it's speak here example.

A little background: I know that average power and peak power returned by the AVAudioRecorder and AVAudioPlayer is in dB. I also understand why the RMS power is in dB and that it needs to be converted into amp using `pow(10, (0.5 * avgPower))`.

My question being:

Apple uses this formula to create it's "Meter Table"

``````MeterTable::MeterTable(float inMinDecibels, size_t inTableSize, float inRoot)
: mMinDecibels(inMinDecibels),
mDecibelResolution(mMinDecibels / (inTableSize - 1)),
mScaleFactor(1. / mDecibelResolution)
{
if (inMinDecibels >= 0.)
{
printf("MeterTable inMinDecibels must be negative");
return;
}

mTable = (float*)malloc(inTableSize*sizeof(float));

double minAmp = DbToAmp(inMinDecibels);
double ampRange = 1. - minAmp;
double invAmpRange = 1. / ampRange;

double rroot = 1. / inRoot;
for (size_t i = 0; i < inTableSize; ++i) {
double decibels = i * mDecibelResolution;
double amp = DbToAmp(decibels);
double adjAmp = (amp - minAmp) * invAmpRange;
}
}
``````

What are all the calculations - or rather, what do each of these steps do? I think that `mDecibelResolution` and `mScaleFactor` are used to plot 80dB range over 400 values (unless I'm mistaken). However, what's the significance of `inRoot`, `ampRange`, `invAmpRange` and `adjAmp`? Additionally, why is the i-th entry in the meter table "`mTable[i] = pow(adjAmp, rroot);`"?

Any help is much appreciated! :)

-

It's been a month since I've asked this question, and thanks, Geebs, for your response! :)

So, this is related to a project that I've been working on, and the feature that is based on this was implemented about 2 days after asking that question. Clearly, I've slacked off on posting a closing response (sorry about that). I posted a comment on Jan 7, as well, but circling back, seems like I had a confusion with var names. >_<. Thought I'd give a full, line by line answer to this question (with pictures). :)

So, here goes:

``````//mDecibelResolution is the "weight" factor of each of the values in the meterTable.
//Here, the table is of size 400, and we're looking at values 0 to 399.
//Thus, the "weight" factor of each value is minValue / 399.

MeterTable::MeterTable(float inMinDecibels, size_t inTableSize, float inRoot)
: mMinDecibels(inMinDecibels),
mDecibelResolution(mMinDecibels / (inTableSize - 1)),
mScaleFactor(1. / mDecibelResolution)
{
if (inMinDecibels >= 0.)
{
printf("MeterTable inMinDecibels must be negative");
return;
}

//Allocate a table to store the 400 values
mTable = (float*)malloc(inTableSize*sizeof(float));

//Remember, "dB" is a logarithmic scale.
//If we have a range of -160dB to 0dB, -80dB is NOT 50% power!!!
//We need to convert it to a linear scale. Thus, we do pow(10, (0.05 * dbValue)), as stated in my question.

double minAmp = DbToAmp(inMinDecibels);

//For the next couple of steps, you need to know linear interpolation.
//Again, remember that all calculations are on a LINEAR scale.
//Attached is an image of the basic linear interpolation formula, and some simple equation solving.
``````

``````    //As per the image, and the following line, (y1 - y0) is the ampRange -
//where y1 = maxAmp and y0 = minAmp.
//In this case, maxAmp = 1amp, as our maxDB is 0dB - FYI: 0dB = 1amp.
//Thus, ampRange = (maxAmp - minAmp) = 1. - minAmp
double ampRange = 1. - minAmp;

//As you can see, invAmpRange is the extreme right hand side fraction on our image's "Step 3"
double invAmpRange = 1. / ampRange;

//Now, if we were looking for different values of x0, x1, y0 or y1, simply substitute it in that equation and you're good to go. :)
//The only reason we were able to get rid of x0 was because our minInterpolatedValue was 0.

//I'll come to this later.
double rroot = 1. / inRoot;

for (size_t i = 0; i < inTableSize; ++i) {
//Thus, for each entry in the table, multiply that entry with it's "weight" factor.
double decibels = i * mDecibelResolution;

//Convert the "weighted" value to amplitude using pow(10, (0.05 * decibelValue));
double amp = DbToAmp(decibels);

//This is linear interpolation - based on our image, this is the same as "Step 3" of the image.
double adjAmp = (amp - minAmp) * invAmpRange;

//This is where inRoot and rroot come into picture.
//Linear interpolation gives you a "straight line" between 2 end-points.
//rroot =  0.5
//If I raise a variable, say myValue by 0.5, it is essentially taking the square root of myValue.
//So, instead of getting a "straight line" response, by storing the square root of the value,
//we get a curved response that is similar to the one drawn in the image (note: not to scale).
}
}
``````

Response Curve image: As you can see, the "Linear curve" is not exactly a curve. >_<

Hope this helps the community in some way. :)

-

No expert, but based on physics and math:

Assume the max amplitude is 1 and minimum is 0.0001 [corresponding to -80db, which is what min db value is set to in the apple example : #define kMinDBvalue -80.0 in AQLevelMeter.h]

minAmp is the minimum amplitude = 0.0001 for this example

Now, all that is being done is the amplitudes in multiples of the decibel resolution are being adjusted against the minimum amplitude: