Hi,
I hope you'll pardon me for putting my reply to your post as of
6/8/2004 10:37 PM here, because my cable newsgroup connection is not
letting me send messages out, its going to look a little out of order.
Okay, then use the 1R5 pentagrid and be done with it. That
worked fine for Motorola and Hallicrafters in the old days.
That's a definite possibility. I won't mind using a pentagrid
converter if there is really nothing better for glass.
My question is simply to ask whether "21rst century"
topologies for silicon such as DBM, Gilbert cell, or commutating
mixer might help make hotter equipment than the original designers
of the tubes intended.
However, if all topologies including pentagrid basically deliver
the same performance, than you are right: I should stick with
simple and be done with it.
Lacking that humongous EMP simulator, I don't know how you
are going to check the EMP-withstanding qualities you want.
Let's assume that someone living in a city, suburb, or large town
is going to be quite dead if they live in the same range as something
that could kill a tube (unless of course it was a "coldbringer" EMP
warhead). Let's posit that vacuum tubes are still more surviveable
than semiconductors, all else being equal.
1. You've never outlined the necessity of the double-balance in a
mixer. The non-balanced type has worked fine in the original
WW2 "handie-talkie" and on into the BC-1000 VHF manpack
transceiver and lots of battery-operated consumer radios.
Unbalanced mixers were used in the Korean War era PRC-8
series using subminiature battery tubes. For both the Tx and
Rx sections. Also the PRC-6 handy-talky, also VHF.
2. A balanced mixer of any kind is not necessarily a relief from
spurious responses. The choice of frequencies to mix will do
that...for any mixer type. Note: The intermodulation products
are a different situation and depend on the characteristics of
the mixer.
okay...
4. Designing a circuit using battery powered, directly-heated
filaments as a differential pair is going to be difficult...unless you
have a separate "A" battery supply for that differential pair.
Since the cathodes ARE the filaments, not separate as in
indirectly-heated tubes, those cathode-filaments are going to
be elevated or, if run near common, will require a "B-" supply
for the long-tailed pair's large "cathode" resistor.
But a 1.5 volt "AA" alkaline battery is cheap enough if I need a
seperate filament.
5. Battery packs are almost in the unobtanium category except
for the single, lower voltage variety. You could use DC-DC
converters but those are now all solid-state and that doesn't
meet the "EMP requirement." Electro-mechanical vibrators
could generate the higher B+ (or B-) but those are terribly
inefficient, short-lived, and get bulky with transformers that
must be at low AC frequencies. Primary batteries such as
the carbon-zinc variety don't last long, maybe several years
if kept very cold to slow down the internal chemistry...all those
being made 30 to 40 years ago are now NG.
B+ will likely be 4-6 9V alkaline batteries in series... cheap in bulk
at Target.
6. You CAN use techniques for suppressing ESD (electrostatic
discharge) to protect from EMP effects, then go ahead and
work with solid-state devices with some assurance of
surviveability. But, you MUST know the EMP characteristics
and do a thorough design task analysis on every part. Anyone
using battery-filament tubes should do the same thing although
I haven't any idea if anyone has done that.
Anything to which I can apply common sense or overkill to? I can't
possibly
hope for this to be Cold War equipment, I'm only just looking for some
kind of edge.
The Eternal Squire
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