Measuring Inductance with the MFJ-259

> -----Original Message-----
>
> As I build my second K2, I want to try to measure the inductance of the
> toroids with my MFJ-259. The MFJ manual has instructions on how
> to do this.
> Essentially one builds a series LC circuit and measures the resonant
> frequency and then calculates the inductance.
>
> Has anyone tried this and have any tips or tricks to pass on?
>
> Am I correct in assuming I can adjust the value of inductance on a toroid
> slightly by compressing or expanding the spacing between turns?
> If so what
> can I use to hold the turns in place. Friction is probably good
> enough, but I
> wonder about a few drops of something like Q-Dope. Comments?
>
> 73,
> Darrell
>

> As I build my second K2, I want to try to measure the inductance of the
> toroids with my MFJ-259. The MFJ manual has instructions on how to do this.
> Essentially one builds a series LC circuit and measures the resonant
> frequency and then calculates the inductance.
>
> Has anyone tried this and have any tips or tricks to pass on?
>
> Am I correct in assuming I can adjust the value of inductance on a toroid
> slightly by compressing or expanding the spacing between turns? If so what
> can I use to hold the turns in place. Friction is probably good enough, but
> I wonder about a few drops of something like Q-Dope. Comments?
>
> 73,
> Darrell

> Well, it seems now that I am receiving contradictory information.
> Specifically
> that compressing the turns on a toroid will raise the inductance.
>
> What is the real scoop. Does compressing or expanding the spacing of
> the
> winding on a toroid change the inductance? Or just the distributed
> capacitance of the toroid? Or is this much more complex than I would
> have
> expected?

> -----Original Message-----
>
> Well, it seems now that I am receiving contradictory information.
> Specifically
> that compressing the turns on a toroid will raise the inductance.
>
> What is the real scoop. Does compressing or expanding the spacing of the
> winding on a toroid change the inductance? Or just the distributed
> capacitance of the toroid? Or is this much more complex than I would have
> expected?
>
>

>
> Eric, KE6US wrote:
>
> I don't have your experience or background, Ron, but the L-meter is
> measuring inductance indirectly and ignoring the presence of distributed
> capacitance. Maybe it isn't as negligible at the frequency of the meter as
> you think.
>
> But in the end, it doesn't really matter. The real test is how a
> particular
> toroid reacts in the circuit it was intended for. If adjusting the turns
> spacing changes circuit resonance, then...it changes circuit resonance.
> That's the result we would have been looking for. Hi.
>
> --------------------------
>
> I'm fond of saying that the only dumb question is the question
> not asked, so
> your question is an excellent one, Eric. As for lots of experience, for me
> that's too often just an opportunity to remember more things incorrectly.
>
> About your question, my L-meter evaluates inductance using a low-frequency
> square wave at about 60 kHz that goes to a differentiator consisting of a
> 200 ohm resistor in series with the unknown inductance. The
> waveform at the
> junction of the resistor and inductor is a series of spikes at
> the frequency
> of the input square wave. The spikes decay at a rate proportional to the
> time constant of the resistor and inductor. This decay rate is converted
> into a voltage in a simple logic circuit.
>
> The ARRL Handbook has featured this circuit in a number of
> editions. It's a
> simple and surprisingly accurate meter, depending upon the quality of the
> inductors used to calibrate it.
>
> The way the circuit works means that any significant capacity in parallel
> with the inductor would tend to cancel the effect of the
> inductor, and make
> the inductance value displayed read lower than it really was, not higher.
>
> Again, at the bench I tested that conclusion by adding capacitors in
> parallel with the inductor. Sure 'nuf, adding capacitance decreased the
> reading. Recall that squeezing the turns together raised the test inductor
> value read on the meter from 3.1 to 3.3 uH. Now I added fixed capacitors
> across the inductor to simulate added distributed capacitance caused by
> squeezing them together. Adding 10 pf of capacitance across the
> inductor had
> zero effect on the reading. Adding 33 pf across the inductor *lowered* the
> reading by 0.1 uH. We're dealing with a very small toroid in this
> test whose
> inter-turn capacitance isn't going to be as much as 2 or 3 pf
> when squeezed
> together.
>
> So I'm confident that the added capacitance by squeezing the
> turns together
> is not what is causing my L-meter to show increased inductance.
> If anything,
> the capacitance would tend to cause the L-meter to show lower inductance.
>
> Ron AC7AC
>
>

> -----Original Message-----
>
> Yes, I think you may be absolutely right, Don. I measured a maximum effect
> of 9% in the one example I tested - a random core lying on my
> bench that had
> about a dozen turns on it. That agrees with your experience of
> finding up to
> a 10% change available.
>
> I saw your suggestion before, and it certainly sounds plausible.
> I wonder if
> something else might be at work here too. Or perhaps I'm looking the same
> effect you are in a different way. Here's my thought. The increased
> inductance/turn of the toroid compared to ordinary air-wound
> coils is caused
> by the very high permeability of the core compared to air. That makes the
> inductance fairly independent of the spacing between turns since
> spacing the
> turns hardly reduces the magnetic flux in the core that is
> available to each
> turn. But I wonder if crowding the turns together doesn't
> slightly increase
> the inductance by providing a lower permeability path for the
> magnetic flux,
> since the distance the flux must travel along the toroid before it passes
> through all the turns of the coil is shorter. In other words, the same
> effect one sees by using closer spacing in an air wound coil, only much,
> much less due to the efficient magnetic path provided by the core.
>
> Does the formula you are using account for a reduction of flux density
> around the distance of the torus due to the losses in the core, or does it
> assume a constant flux at all points?
>
> It's always interesting when experiment fails to support
> predictions. True,
> it most often turns out to be an invalid experiment that causes
> that result,
> but I can't see the problem here, especially considering that the
> effect of
> added distributed capacitance has an inverse effect on the reading on this
> type of 'meter'.
>
> Ron AC7AC
>
>
> -----Original Message-----
> From: W3FPR - Don Wilhelm [mailto:[hidden email]]
> Sent: Monday, August 29, 2005 9:22 PM
> To: Ron D'Eau Claire; [hidden email]
> Subject: RE: [Elecraft] OT: Effect of Compression and
> ExpansionontheInductanceof Toroids?
>
>
> Ron,
>
> I have the same inductance meter, and it does a good job because it does
> measure using the LR time constant rather than frequency, but 'physics is
> physics', and with a true toroidal inductor, there is still no
> dependency on
> the turns spacing (the math says so).
>
> Now, for the practical side of things, I do believe that your results (and
> others with similar findings) deviate from the 'classic physics' treatment
> of the ideal (ignoring practical behavior) - and when the toroid turns are
> irregular (not evenly spaced around the circumference of the
> core), there is
> some part of that coil behaving as a solenoidal inductor where
> turns spacing
> IS a factor.
>
> Remember that a toroid is simply a solenoidal coil formed into a
> circle with
> the ends of the coil meeting.  This ideal toroid has equal turns
> spacing all
> the way around.
>
> So my current conclusion is -- IF the toroid is equally spaced around the
> core, the inductance is not dependent on the spacing of the turns, BUT, if
> the turns are compressed anywhere around the core, additional factors rear
> their ugly heads because the inductor is a combination of a
> solenoidal coil
> and a toroid coil, and the math becomes quite complex - just how much of
> each effect depends on just how much deviation from an ideal toroid shape
> exists in the configuration at hand.
>
> In a frequency dependent tuned circuit, how much of the frequency shift is
> due to the inter-turn capacitance or a change in inductance is
> (to me) only
> a matter of curiosity - the plain fact is that some change in the resonant
> frequency (or inductance) can be achieved by changing the turns
> spacing, but
> we all know that the adjustment range is small - the really big
> determining
> factor is simply the number of turns.
>
> As an example, I often improve the 10/12 meter Low Pass Filter
> characteristics of a KPA100 by squeezing the toroid turns "just the right
> way", but I determine what is the 'right way' by monitoring the impedance
> with my MFJ259B as I do it.  Sometimes it is 'this way', while other times
> it is 'that way' - the batch to batch change in the permeability of the
> cores likely accounts for more variation than the turns spacing
> itself. BTW,
> this change does not really help the KPA100 output, but it
> improves the base
> K2 10 meter efficiency at 10 watts or lower when the KPA100 is installed.
>
> The overall inductance change that I have experienced is about
> 10%, so that
> is within the normal design tolerances using 10% resistors and
> capacitors -
> so except for satisfaction of the curiosity factor, I would say
> just to wind
> the toroids with the proper number of turns, and 'tweak' them
> in-circuit as
> required and as close as is permitted by your measurement capability.
>
> 73,
> Don W3FPR
>
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