Roger,
Small, generic LCD screens could
be produced for pennies, or at most, a few dollars as you can now
purchase a 40" smart HD TV receiver for $300-$400.
It's a matter of checking what a simple cellphone costs these days. Two years
ago I got my latest one, an old-style dumbphone in clamshell style. That one has
two displays, a monochromatic one outside and a pretty decent color display
inside. The whole phone cost like $30, including shipping from China, and that's
a price that wasn't subventioned by a phone company! So the displays really must
be cheap, when bought in the quantity a cellphone make buys them.
> How many
transistors used in SS rigs over the last two decades are no longer
available?
That's not a problem, because essentially any transistor can be replaced by a
different one. But the problem does exist with specific ICs. A famous (or
rather, infamous) case is the DDS chips of the Kenwood TS-450, 690, 850, that
seem to rot from the inside out due to some fabrication mistake. Those ICs are
specific, discontinued, and presently unavailable except perhaps from someone
who has a few stockpiled, and sells them at a very stiff price. And there is
nothing that can replace them in a plug-in fashion. One would have to cook a new
board with a different DDS chip and a MCU or other circuit to translate the
commands, to revive any of these radios whose DDS chips went bad.
Mine went bad in time, when I still could get replacements without the
fabrication mistake, so I'm fine in this regard. But I know of several hams who
have dead radios of these models, and no way to fix them.
However, HRD and other Graphical interfaces can replace most of the
front panel, let alone the individual displays on today's rigs. If
using HRD you might not even notice a failed, non essential display.
It's true, but when you tie a radio to a computer, it's getting twice as
expensive, 5 times larger and heavier, and the power consumption is 10 times
higher. So it's really good to be able to operate a radio without an external
computer!
And now, let's go to really interesting matters!
Warren,
** It seems to me that it's probably much easier to optimally implement
pre-distortion in a DDC/DUC (digital up-conversion / digital
down-conversion) software defined radio than in other radios. There are
simply very few places that errors can creep into the required
processing. The required precision and accuracy increase exponentially
as the desired reduction in IMD increases. So, having few error sources
and the benefit of double-precision floating point become important.
What does "double-precision" mean in this case? 32 bits, 64 bits, or how much?
To have errors down 60dB, even 16 bit should be OK, for a single operation. But
I wonder how many math operations are involved in a radio's whole processing.
That surely calls for more bits of resolution in each operation!
I saw that a DSP chip with integrated CODEC, aimed at mid level HiFi
applications, has a 56 bit processor! They strive to put any errors about 100dB
down from the peak signal.
** 50V LDMOS amplifiers are probably the "most correctable" solid state
amps. Tube type amps also correct very well. 13.8V amps are more
difficult due to "memory effects."
What memory effects do you mean here? Dielectric absorption, thermal effects, or
what?
** No problem to correct an entire amplifier chain, at legal limit. No
extra hardware or software is required. One just feeds back a sample of
the output from the last stage to calculate the correction.
That's the nicest thing about SDRs. Once you have the interfaces to the analog
world up and running, and a good chunk of processing power, you can do pretty
much _anything_ at no additional cost.
** You cannot successfully correct by pre-distorting the MIC input to a
radio UNLESS you have VERY wide bandwidth from the MIC through the
entire transmitter. The IMD frequencies that you want to correct must be
within the bandpass of the correction path.
Here you caught me in a shaky position. It's where I touch the limits of my
present theoretical knowledge about the matter. If I set up an amplifier that
corrects amplitude nonlinearities, with a loop bandwidth of 30kHz, does this
mean that any amplitude-error-caused IMD more than 30kHz away from the center
frequency will not be corrected at all? But that could still be quite useful,
given that IMD so far away from the center frequency should anyway be pretty low.
At Ham Radio Friedrichshafen this past June, I gave a talk (approx. 30
min.) on the openHPSDR solution for pre-distortion. It's posted on the
openHPSDR web site. If any are interested, here's a link:
"*Warren Pratt,*NR0V, 2014.Digital Predistortion linearizes RF
amplifiers <http://video.openhpsdr.org/HRF2014/PureSignal1.2.mp4>(MP4)"
Is the contents of that video available in written form? Due to internet
connection limitations, I cannot download videos...
I hope this helps explain a little more about this technology and sparks
more interest in finding ways to reduce IMD!
It does! For several years I have been wanting to get seriously into DSP and
really do something myself in the area, but never have found the entry door.
Warren, can you perhaps suggest a practical, inexpensive way to set up a kind of
DSP breadboard, that would allow me to mount a processor, suitable A/D, D/A
sections, and then go along getting my feet wet programming it? So far my only
attempts at incorporating DSP into my own projects has been by basic digital
filtering functions in low frequency applications. Mostly power line frequency.
And implemented in integer math, on 8-bit PICs!
Years ago I tried my hand with a DSP-93 kit that I got for free, but never found
out how to even start doing something useful with it.
Roger seems to be in the same boat I am.
Manfred
========================
Visit my hobby homepage!
http://ludens.cl
========================
_______________________________________________
Amps mailing list
Amps@contesting.com
http://lists.contesting.com/mailman/listinfo/amps
|