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"Tom Bruhns" Wrote:
(Avery Fineman) wrote in message ... ... Suffice to say that a square wave cannot be used with a passive diode doubler; all the energy is contained in the short transition times and that is rarely enough to be worth it. ?? Lots of energy in the fundamental; filter to extract the fundamental and feed it to your full-wave rectifier doubler. Efficiency can be high if the filter does not cause dissipation in the source at the harmonics. Tom, look at it this way... Draw the square wave, assuming capacitive coupling so it has a zero crossing. Then draw the same signal but invert the negative going half to positive, which is what the full wave diode doubler would do. You wind up with a positive voltage, but with VERY narrow negative spikes. So, a square wave into a diode doubler will produce only a small amount of the second harmonic. You'd be better off running the input square wave through a lowpass of some sort and then doubling it. Given a sine wave input, there is a fair amount of negative going signal and that is what produces the high energy content of the second harmonic. Jim Pennell N6BIU |
On Sat, 21 Feb 2004 12:28:11 +0000, Paul Burridge
wrote: On Sat, 21 Feb 2004 03:20:07 -0800, Roy Lewallen wrote: Tom Bruhns wrote: . . . . . . Seems like step recovery diodes are not in as great favor as they once were, since there are generally better ways to generate higher order harmonics. . . . Getting a bit off-topic here, but as of a few years ago, we were using step recovery diodes to generate the step in high speed TDR systems, and to generate the strobe for the sampling gate in high speed sampling scopes. Rise times were on the order of 7 - 15 ps (bandwidth up to 50 GHz or so), limited primarily by circuitry external to the diodes. SRDs replaced tunnel diodes in earlier generations of instruments. I've been out of touch with that class of instruments for a few years now -- do you know if something has replaced the SRD for generating fast steps, or just for harmonic generation? What's a doubler based on the good old 1N4148 good for, top end frequency-wise? made some experiments 10-15 years ago with doublers to 144Mc/s, and they probably would work on at least 200Mc. Best experience with a BFR90 amplifier following the 'rectifier', see http://home.online.no/~la8ak/c13.htm It was important with certain dc load following the diodes and some bias current Another interesting multiplier used for 100kc calibrator - on vhf - described in UKW Berichte uses quad nand schmidt trigger, where the input signal is splitted - one part to a nand input and the other to 3x nand gates connected as inverters and connected to the second input of the nand-gate such that the truth table said constant logic high output, but a very thin spike occured because of the transition time delay 73 JM ---- Jan-Martin, LA8AK, N-4623 Kristiansand http://home.online.no/~la8ak/ |
On Sat, 21 Feb 2004 12:28:11 +0000, Paul Burridge
wrote: On Sat, 21 Feb 2004 03:20:07 -0800, Roy Lewallen wrote: Tom Bruhns wrote: . . . . . . Seems like step recovery diodes are not in as great favor as they once were, since there are generally better ways to generate higher order harmonics. . . . Getting a bit off-topic here, but as of a few years ago, we were using step recovery diodes to generate the step in high speed TDR systems, and to generate the strobe for the sampling gate in high speed sampling scopes. Rise times were on the order of 7 - 15 ps (bandwidth up to 50 GHz or so), limited primarily by circuitry external to the diodes. SRDs replaced tunnel diodes in earlier generations of instruments. I've been out of touch with that class of instruments for a few years now -- do you know if something has replaced the SRD for generating fast steps, or just for harmonic generation? What's a doubler based on the good old 1N4148 good for, top end frequency-wise? made some experiments 10-15 years ago with doublers to 144Mc/s, and they probably would work on at least 200Mc. Best experience with a BFR90 amplifier following the 'rectifier', see http://home.online.no/~la8ak/c13.htm It was important with certain dc load following the diodes and some bias current Another interesting multiplier used for 100kc calibrator - on vhf - described in UKW Berichte uses quad nand schmidt trigger, where the input signal is splitted - one part to a nand input and the other to 3x nand gates connected as inverters and connected to the second input of the nand-gate such that the truth table said constant logic high output, but a very thin spike occured because of the transition time delay 73 JM ---- Jan-Martin, LA8AK, N-4623 Kristiansand http://home.online.no/~la8ak/ |
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"Jim Pennell" wrote in message link.net...
"Tom Bruhns" Wrote: .... ?? Lots of energy in the fundamental; filter to extract the fundamental and feed it to your full-wave rectifier doubler. .... So, a square wave into a diode doubler will produce only a small amount of the second harmonic. You'd be better off running the input square wave through a lowpass of some sort and then doubling it. Right on, Jim. "Filter to extract the fundamental and feed it [the fundamental] to your full-wave rectifier doubler." Of course, third harmonic mixed with fundamental gives you second and fourth, etc., so there's a hint that the harmonics could be useful if the phases were right. What do you get if you feed a mixer a square wave in one port, and the same square wave delayed by 1/4 period into the other port? Cheers, Tom |
"Jim Pennell" wrote in message link.net...
"Tom Bruhns" Wrote: .... ?? Lots of energy in the fundamental; filter to extract the fundamental and feed it to your full-wave rectifier doubler. .... So, a square wave into a diode doubler will produce only a small amount of the second harmonic. You'd be better off running the input square wave through a lowpass of some sort and then doubling it. Right on, Jim. "Filter to extract the fundamental and feed it [the fundamental] to your full-wave rectifier doubler." Of course, third harmonic mixed with fundamental gives you second and fourth, etc., so there's a hint that the harmonics could be useful if the phases were right. What do you get if you feed a mixer a square wave in one port, and the same square wave delayed by 1/4 period into the other port? Cheers, Tom |
Paul Burridge wrote in message . ..
What's a doubler based on the good old 1N4148 good for, top end frequency-wise? Thanks to Jan-Martin for his reference to some actual experiments. But in reply to Paul, I'd ask: Do you understand how the "full-wave rectifier doubler" works, basically? (Ideal waveforms and all that.) Do you have a data sheet for the 1N4148? What items from the data sheet do you suppose might limit the useful frequency? Can you make an estimate, based on the data sheet numbers? What would you do in a design to extend the frequency range for a given diode characteristic? For example, what does diode capacitance do to circuit operation? What does reverse recovery do? In the full-wave frequency doubler circuit, what does the input impedance look like, assuming an ideal transformer, when one diode is forward biased and the other is reverse-recovering? Can you think of parts to add to cause that to not be so much of a problem (assuming it is a problem)? Thinking about this sort of thing is useful not only in figuring out what to expect, at least ball-park, but also in getting better performance out of someone else's circuit and/or understanding its limitations. Cheers, Tom |
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