Bits & Bytes

There's been quite a few mentions of 1024 and 2048
resolution on here lately, and the general consensus
seems to be that the bigger the numbers, the better!

It ain't necessarily so, and I hope the following
explanation will clarify matters......

Any modern digital system (ie PCM or 2.4 GHz) breaks the
information it has to transmit down into binary numbers.
If you have an 8-bit system, it can represent 256
discrete steps. A 9-bit system can represent 512 steps.
A 10-bit system can represent 1024 steps, and an 11-bit
system will do 2048.

These "steps" are the smallest possible increment that
the system can resolve. You cannot make the system
respond to a change smaller than one of these "steps".

So what does this mean in practice?

Well, an 8-bit system with 256 discrete steps means that
the servo cannot possibly move by less than 1 part in
256 of its travel, or just under 1/2%. Similarly, a 9-
bit system will resolve 1 part in 512, or about 0.2%. By
the time you get to 11-bit systems you are talking about
a resolution of about .05%!

Now can anyone show me a servo that can resolve 0.05%?

No? Well, how about 0.2%? Perhaps if you were to pay a
small fortune, a brand new servo might just resolve that
amount, but it probably wouldn't manage it after a few
flights!

And what about linkages? How many of us can build a
linkage with less than 0.2% slop in it? When was the
last time you got hold of your paddles and gave them a
waggle (if you'll pardon the expression!)? Most of us
are lucky to get it down below 5%!!!

So in short, there is absolutely no point in going for
these ludicrous resolutions - or is there?

Well, internally - within the system - there is.

Everytime you mix a couple of functions together, you
also add their potential errors together. For example,
if you mix two channels equally, and each channel has a
resolution of 1%, the mixed output will only have a
resolution of 2%. When you are doing complex mixing - as
with eCCPM - the resolution of the final mix will be
lowered dramatically. So yes, you want to do all the
arithmetic at a high resolution, so that the final
output still falls within acceptable limits.

But there is absolutely NO POINT in *transmitting* that
level of resolution, because 1) the servos just aren't
that accurate and 2) neither are the linkages attached
to them!

So is there any downside to transmitting high resolution
data? Well certainly on 35 MHz, yes!

A 35 MHz channel is only 10 KHz wide. The more data you
try and stuff down it, the SLOWER you have to transmit
it! PCM already suffers from quite a high level of
latency due to the fact that once the data is received
it has to be checked for corruption, and then translated
into something the servos understand (PPM). This is why
on all PCM systems, there is a tiny but observable lag
between moving the stick and the servo moving. And the
more bits you use, the longer that lag gets!

The problem is much less significant at 2.4 GHZ, where
you have over 10 times the bandwidth available. But it
is still a total waste of effort because neither the
servos nor the linkages can possibly resolve that level
of accuracy!

So don't get too hung up on the numbers game! It doesn't
mean quite what you may think!

That is not to say that 2048 systems may not have other
benefits that the manufacturers have added, such as
additional data integrity checks. But it won't help to
improve the resolution of the controls in practice, and
it may even slow things down!