Impedance issues and microphones – Manley TNT MICROPHONE PREAMPLIFIER User Manual

Perhaps it is because those near opposite characters of

the two circuits, that when combined or blended the

audible benefits and strengths of each prevail, while

the weaknesses of each are minimized. Of course, the

better each circuit is optimized, the closer they tend to

meet in the middle (transparency). Perhaps it is because

the approach of respecting both voltage and current; it

results in a form of optimal power transfer. Optimal

power transfer is a very old topic in electronics and

it relates to the old 600 ohm impedances pro audio

inherited from the telephone industry and the 75 ohm

terminations we need to be concerned with for word

clock and video lines. Maybe with complex sources,

there is valuable information carried both in voltage

and in current and maybe most mic pre inputs are

not as simple as a basic resistor. In other words, to

some degree a typical microphone is a complex source

(especially dynamic, ribbon and transformer coupled

condenser mics) and a typical mic preamp input may

also be a complex load (especially if it is transformer

coupled) and the cable and connections between

the two might also be viewed as a combination of

resistance, capacitance, inductance and distance. So

maybe it is all too complex to grasp without some

serious computer modelling, but maybe it can be easy

enough just to hear in some situations - and we’ll leave

that up to you.

We would like to speculate that one of the complexities

that you might experience will be cable length. While

we were designing the TNT we noticed excess high

frequency sibilance coming in at the highest impedance

settings. We finally traced it to the mic cables that we

were using. If we doubled the length, the problem

doubled and if we used a very short cable the problem

disappeared. And the problem wasn’t apparent at low

impedance settings. OK but why? Here is where we

have to speculate.

At low Z settings, it may be akin to our old 600

ohm terminated lines that pro audio inherited from

the telephone industry. And that standard was set up

to reduce echoes in early long distance lines. It also

resembles the 50 ohm or 75 ohm terminated lines

used for video and word clock where cable reflections

impact high frequencies. Normally we don’t consider

audio frequency cable reflections to be a concern

because they don’t seem to affect the 20 kHz

frequency response or square waves on our ‘scopes.

So our speculation might be a question. How far do

these cable reflections need to decay (in dBs given

that -60 dB is 1/1000) before they do not intersect

with our abilities to perceive transients? Or how many

microseconds of reflections and down to what dB?

Just use a shorter cable.

Impedance Issues and Microphones

OK, the above might be a bit of technical mumbo-

jumbo and what you really want to know is what to

expect and listen for when you change the impedance

switch in your session. Simply, at very high impedance

settings, there are usually a little more highs. At low

impedance settings, with dynamic and ribbon mics

the bottom often tightens up. In the middle impedance

settings, the preamp may sound closest to what you

have grown to expect with that mic because most mic

preamps are medium impedance and typically 1000 –

3000 Ohms.

With high impedance settings, one may be affecting

the mic and cable in a few ways. First, with

transformer coupled mics like most dynamic, ribbon,

and tube condenser mics, one might be setting up a

high frequency peak in the mic’s transformer that may

have been intended for 1 kOhm to 3 kOhm preamp

impedances. The opposite is also common, where very

low impedances may cause the transformer to roll-off

highs earlier than the designer intended (yeah, but its

your mic and your session, so choose the setting with

your ears). The other effect goes back to that rambling

about cables and time domain effects. Listen carefully

for excessive sibilance and what might be described

as an artificial harshness, and what perhaps the most

finely honed ears will hear as time-smearing in the top

octaves. This effect is directly related to cable type

and length, and once you lock into it, you can prove it

by doubling (or halving) the cable length. Even better

is moving the TNT into the studio once you have your

settings, and using a 4 to 8 foot cable from the mic to

the preamp. It seems puny low level mic signals are

more fragile to these effects than hotter line level (and

robust line driver driven) signals but we don’t know

why. Give it a try. If this seems a bit inconvenient for

level tweaks, add a simple passive variable attenuator

(fader or pot) in the control room near your converter

(if it has inconvenient input level adjustments) if you

are a purist, or use the compressor or EQ gain controls,

if you’re not. The TNT has quite a bit of headroom

(except in 60’s / 70’s mode) so there won’t be much

chance of overloading it and the real thing to keep an

eagle eye on is the analog to digital converter at the

end of the chain.

Away from the extremes, the 2K (2000 Ohms) setting

represents the standard impedance of most mic

preamps and what most microphones are designed to

drive. In other words, its safe, and maybe a bit ‘vanilla’

and this isn’t a bad thing. The 600 ohm setting is also

pretty safe and may have some advantages because

it gets closer to a 50/50 blend of voltage and current

mode preamps.

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