@LuisMendo classical text book: amazon.com/Pattern-Recognition-Learning-Information-Statistics/…

Even more classical-y: amazon.com/Pattern-Classification-Pt-1-Richard-Duda/dp/…

Duda & Hart is the one I learned from in college. Bishop I used in teaching.

Stork was added in the 2nd edition. Duda and Hart wrote the first edition.

Why is the Kimdle edition $160 and the hardcover version $90 new?

@CrisLuengo Thank you!

@CrisLuengo I'll remember that if I ever decide to learn this shit

@AndrasDeak--СлаваУкраїні mast.hpc.social/@ProjectPhysX/112118756527384582

@AndrasDeak--СлаваУкраїні IEEE FP is convenient, but it certainly is not efficient.

@CrisLuengo Efficient in what sense?

FYI: 1-rep voting coming to SO

Unvolunteered, nice

At least this will solve the HNQ issue :P

@flawr It wastes a lot by having so many different NaNs, and two zeros. In a 64-bit FP it doesn’t matter much. In a 4-bit FP it becomes painfully obvious.

Ah yes, I wasn't aware that there are so many ways to get NaNs:)

Many years ago U talked to someone at a conference that designed a different FP representation that is much more efficient. He showed how you can get so much better precision out of calculations and so on. I understand chip manufacturers don’t want to change their designs for this, but you’d think that if you introduce a 4-bit FP processor you’d look for a better FP representation?

Here it is: POSIT — en.m.wikipedia.org/wiki/Unum_(number_format)

But at that 4 bits I must say it doesn't really "feel" like floating point numbers anymore:)

@CrisLuengo No more negative zeros? Heresy!

From a quite level-headed guy

@flawr yeah, it looks like you could get more precision if you used signed integers… Does a NN even need NaN? The only thing you then have left is the overflow marker. A signed integer with saturation arithmetic would be much better.

The Open Compute Project specifies FP4 as sign, 1 mantissa and 2 exponent bits, no Inf or NaN. That gives you +/- [0, 0.5, 1, 1.5, 2, 3, 4, 6].

There’s also a “radix-4 FP4 format”: sign, 3 exponent, and 0 mantissa bits. That gives probably +/- [0, 0.25, 0.5, 1, 2, 4, 8, 16]? Limits depending on how the exponent offset is defined.

No, the radix-4 FP4 format uses 4 as a radix, not 2. Duh! It does +/- [0, 1/64, 1/16, 1/4, 1, 4, 16, 64]. Neat!

Still the minus 0 though… I prefer two’s complement.