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One important factor is the load the attenuator places on the amp: there is agreement that it should be like that of a guitar speaker, and we will discuss that more later, but first let's look at the impedance of a couple of speakers. First is one of my favorite speakers, the no longer produced Eminence Red Fang, an Alnico speaker. The most frequently shown plot is the magnitude of the impedance versus frequency. I have made some measurements with the speaker in a Line 6 open back cabinet, shown in the first attachment.
The measurement technique is very much like what I use for guitar pickups: A resistor its placed between one speaker terminal and ground, and the other terminal its driven with a voltage. This voltage to ground is measured as is the voltage across the resistor. The instrument is an inexpensive recording interface attached to a computer. The waveform used is a Golay complementary sequence. Cross spectral analysis is performed.
The most noticeable feature is the low frequency resonance; the magnitude I measured is lower than the one published by Eminence. This is probably a function of damping introduced by the open back cabinet. The next most noticeable feature is the rise with frequency. One could look at this and might be confident that this is a result only of the inductance of gate speaker coil.
However, there is more to it than that. The real (the apparent resistance as a function of frequency) and imaginary (the apparent inductance as a function of frequency) parts are shown in the next attachment.
Now we see that the rise in impedance is a result of both inductance and increasing resistance. The latter is probably a result of eddy current losses in the metal parts.
The next question is what are all those little (maybe not so important) features? Are they the result of the measurements technique, including the cabinet, or are they a function of the driver? So here are the results for another speaker, a Celestion GP12-80. I wanted to measure a Celestial Blue, but it turns out that it did not survive Maria).
The overall impedance is very similar; some of the small bumps are similar, some are not. Thus we have a mixture of measurement and speaker effects.
When I get to the next post, it will be about why we need to load the amp and what we need to do th get a scaled copy of the voltage across the load.
The measurement technique is very much like what I use for guitar pickups: A resistor its placed between one speaker terminal and ground, and the other terminal its driven with a voltage. This voltage to ground is measured as is the voltage across the resistor. The instrument is an inexpensive recording interface attached to a computer. The waveform used is a Golay complementary sequence. Cross spectral analysis is performed.
The most noticeable feature is the low frequency resonance; the magnitude I measured is lower than the one published by Eminence. This is probably a function of damping introduced by the open back cabinet. The next most noticeable feature is the rise with frequency. One could look at this and might be confident that this is a result only of the inductance of gate speaker coil.
However, there is more to it than that. The real (the apparent resistance as a function of frequency) and imaginary (the apparent inductance as a function of frequency) parts are shown in the next attachment.
Now we see that the rise in impedance is a result of both inductance and increasing resistance. The latter is probably a result of eddy current losses in the metal parts.
The next question is what are all those little (maybe not so important) features? Are they the result of the measurements technique, including the cabinet, or are they a function of the driver? So here are the results for another speaker, a Celestion GP12-80. I wanted to measure a Celestial Blue, but it turns out that it did not survive Maria).
The overall impedance is very similar; some of the small bumps are similar, some are not. Thus we have a mixture of measurement and speaker effects.
When I get to the next post, it will be about why we need to load the amp and what we need to do th get a scaled copy of the voltage across the load.
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