Ashly Electronic Amplifier none User Manual

A CLOSER LOOK AT CROSSOVERS

IMTRODUCTION

The bulk of this instruction manual is concerned with helping a sound system
operator to get his system set up and running, and to answer the questions
"how do I plug it in" and "where should I set the front panel controls." For

those

who

want

more

information

about

the

design

and

application

of

crossovers, this section may be a good starting place, covering such topics as

the

need

for

crossovers,

characteristics

of

filters

used

in

audio,

limitations

of passive crossovers, solutions offered by biamplification, and more detailed

information regarding correct speaker alignment. The information offered here

is only an introduction to the subject, since an in-depth discussion would

certainly fill dozens of books.

As you read this, please try to always keep in mind that your crossover is
only one part of a sound system, and that the electrical performance of a
crossover,

although

predictable

and

well

behaved,

will

almost

never

be

accurately

reflected

in

the

acoustic

performance

of

a

speaker

array.

Also,

there is no "best" approach to reproducing music through loudspeakers; there
are a variety of methods in popular use, and each method has attendant
problems and benefits which make it suitable for a particular application.

WHY USE CROSSOVERS?

The ideal speaker system would use a single small loudspeaker to reproduce the
entire

audible

sound

spectrum

at

any

desired

power

level.

It

would

be

inexpensive, easy to hook up, and have a wel1-controlled coverage pattern that

would

not

vary

significantly

with

frequency.

Unfortunately,

such

a

speaker

does not exist. Perhaps the closest approximation we have is the single­
driver headphone,

which can reproduce most of the audio spectrum fairly

accurately.

When

any

larger

amount

of

volume

is

required,

it

becomes

necessary to move greater amounts of air and larger speakers are required.

For a given loudness, reproduction of low frequencies will demand greater
changes in air pressure than high frequencies, and so will require a greater

surface area in contact with the air. A speaker capable of good low-frequency
response,

then,

will

be

relatively

large.

This

characteristic

does

not

favor

good high frequency response, however, since the sheer physical mass of the
large speaker inhibits the rapid back-and-forth movement required to reproduce
high frequencies. A speaker suitable for reproducing high frequencies should
be

light

and

small.

This

disparity

between

low

and

high

frequency

requirements gets worse as the frequency response extremes and power demanded
of a system get larger.

If one speaker cannot satisfy all requirements, then the solution must be to

use

two

speakers,

each

suited

to

a

particular

portion

of

the

frequency

spectrum, and let each do its own job. This neatly solves one problem but

instantly creates several new ones. First of all, if the woofer and tweeter

are both wired in parallel and hooked up to a high power amplifier, there's a
good chance that the tweeter will be destroyed. The tweeter will attempt to

reproduce low frequency information fed to it, but its cone will not allow the

long back and forth excursions necessary for lower frequencies, and so the
excess pov/er being fed to the tweeter will be dissipated in its voice coil as
heat, eventually ruining it. Secondly, if the woofer and tweeter are not well
matched in terms of their sensitivity, then one range of frequencies will be

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