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Crossovers

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Title: Crossovers


1
Crossovers
  • Manual Reference Pages 222 227

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What is a Crossover?
  • Audio crossovers are a class of electronic
    filters designed specifically for use in audio
    applications
  • Crossovers serve the purpose of splitting an
    audio signal into separate frequency bands which
    can be handled by individual loudspeaker drivers
    optimized for those bands.

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What is a Crossover?
  • They are generally described according to the
    number of frequency bands available (two-way,
    three-way and four-way).

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How it works
  • It uses bandwidth limiting filters to separate
    the input signal into multiple outputs, each of
    which has a steep cut-off below and/or above its
    range (24dB/octave is typical). In some, the
    cut-off slope (and in some of those, even the
    type of filter Bessel/Butterworth/Linkwitz-Riley,
    etc.) is user-determined.

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3 types of crossover filters
  • High-pass
  • Low-pass
  • Band-pass

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  • A high-pass filter will block low frequencies
  • A low-pass will block high frequencies
  • A band-pass will block low and high frequencies
    below and above crossover points.

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Slope
  • Slope is expressed as decibels per octave.
  • The rate of attenuation for every octave away
    from the crossover frequency
  • Crossovers do not block undesired frequencies
    completely (unless you are using digital
    crossovers)
  • Crossovers cut frequencies progressively
  • A crossover "slope" describes how effective a
    crossover is in blocking frequencies

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Slope
  • A 6dB per octave crossover reduces signal level
    by 6dB in every octave starting at the crossover
    point.

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- 6db
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- 6db
- 12db
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- 6db
- 12db
- 18db
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- 6db
- 12db
- 18db
- 24db
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  • 1st order filters have a 6 dB/octave slope
  • 2nd order filters have a 12 dB/octave slope
  • 3rd order filters have an 18 dB/octave slope
  • 4th order filters have a 24 dB/octave slope
  • 5th order filters have a 48 dB/octave slope

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- 6db
- 12db
- 18db
- 24db
- 48db
500hz
250Khz
125hz
1Khz
63hz
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Crossover Point
  • The nominal dividing line between frequencies
    sent to two different speaker drivers.
  • In a crossover network, the frequency at which
    the audio signal is directed to the appropriate
    driver (low frequencies to the woofer, high
    frequencies to the tweeter).
  • The single frequency at which both filters of a
    crossover network are down 3dB.
  • The frequency at which an audio signal is
    divided.

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Cutoff Frequency
  • The "corner point" of a filter, usually the point
    where the response is down -3dB compared to the
    midband signal level.
  • The signal frequency output of a filter that
    marks the transition from no attenuation to
    attenuation. Usually it is defined as the point
    at which the amplitude of the signal is reduced
    by 3 dB after passing through the filter.

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  • There is 1 crossover point in a 2 way crossover
  • There are 2 crossover points in a 3 way crossover
  • There are 3 crossover points in a 4 way crossover

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Types of Filters
  • Butterworth filter
  • Chebyshev filter
  • Linkwitz-Riley (L-R) filter
  • Elliptic filter
  • Bessel filter
  • Legendre filter
  • Gaussian filter

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Butterworth filter
  • It is designed to have a frequency response which
    is as flat as mathematically possible in the
    passband

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Linkwitz-Riley filter
  • The filters are usually designed by cascading two
    Butterworth filters, each of which has -3 dB gain
    at the cut-off frequency. The resulting
    Linkwitz-Riley filter has a -6 dB gain at the
    cutoff frequency. This means that summing the
    low-pass and high-pass outputs, the gain at the
    crossover frequency will be 0 dB, so the
    crossover behaves like an all-pass filter, having
    a flat amplitude response with a smoothly
    changing phas response. This is the biggest
    advantage of L-R crossovers compared to
    Butterworth crossovers

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Linkwitz-Riley filter
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2 Types of Crossovers
  • Active
  • Passive

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Passive
  • Passive crossovers are usually built into speaker
    cabinets (typically in the form of a printed
    circuit board with one or more capacitors and/or
    resistors and/or inductors mounted on it)
  • A passive crossover appears in the circuit after
    the amplifiers, and divides the signal that then
    goes to your speakers.
  • A passive crossover has no power, ground, or
    turn-on leads and are rather inexpensive. But,
    they tend to be inefficient and can even add some
    distortion.

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Advantages of Passive Crossovers
  • Less Amplification needed compared to active
  • Less Expensive
  • No ac power required to operate nothing to turn
    on.

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Disadvantages of Passive Crossovers
  • Less Efficient
  • More Distortion
  • Fixed crossover point
  • No level control for individual frequency ranges

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Active Crossover
  • Active crossovers usually come in the form of a
    19" 1U rack-mounted box with knobs or buttons and
    some sort of menu display on the front. Some -
    usually with system-specific EQ settings, delay
    and limiting functions - are described as
    controllers.

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Active Crossover
  • Most active crossovers allow adjustment of the
    crossover points, as well as independent control
    of the output level of each frequency band.
  • An active, or electronic, crossover does its job
    pre-amp (taking the signal directly from the
    mixer before it gets to the amplifier)
  • Needs an external power source.

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Active Crossover
  • Active crossovers give you control over which
    frequencies you want to use as the crossover
    points for bass mid and treble
  • Some active crossovers allow you to customize the
    crossover slope as well as the crossover point
  • Because they filter frequencies before the signal
    is amplified, active crossovers ensure that the
    amp gives its full attention to the filtered
    signal, which is very efficient

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BSS
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ASHLY
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RANE
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Advantages of Active Crossovers
  • Selectable Crossover Points
  • Level Control of each band
  • Better system efficiency
  • Driver Delay control
  • Less Distortion
  • Signal is not affected as much as with passive
    crossovers, since everything is done at low
    voltages.

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Disadvantages of Active Crossovers
  • Need separate amps for each band of frequencies
  • Increasing systems expense dramatically
  • More complex setup

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Active Passive
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How To Choose Crossover Points
  • Choose your crossover points and crossover slopes
    by consulting the frequency response measurement
    on your speaker specs.
  • The frequency response is the range of
    frequencies that the speaker can successfully
    reproduce.
  • The frequency response of two separate speakers
    (woofer and midrange, for example) must overlap a
    little, or you will hear a "gap" in the sound.
  • The crossover point appears within this overlap

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Typical Crossover Points
  • Two way ( 1.6 khz )
  • Three way ( 125 hz 1.6 Khz )
  • Four way ( 80 hz 250 hz 1.6 Khz )

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18 Driver
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12 Driver
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1" Line Array High Frequency Driver
  • Freq. Range - 500Hz to 20kHz

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DSP
  • Digital Signal Processor

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Digital Crosovers
  • Also known as loudspeaker management systems
  • Give us complete control of all elements of loud
    speaker system including EQ, Crossover points,
    Delay, Compression, Limiting, all in one unit.
  • Storable programs and setups ie stereo 4 way or
    4 x 2way etc.
  • BSS Omni Drive is one example of this type of unit

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  • Many processes that would traditionally be
    achieved by using many
  • units can now be incorporated into one crossover
    system providing an integrated
  • solution.
  • A digital unit is not simply a crossover it is a
  • complete Loudspeaker Management System
  • As well as the crossover, functions are
  • provided for limiting, time delay and
  • equalisation.
  • Because the unit is completely
  • controlled by a microprocessor, each unit
  • can store many programs internally.
  • The same DSP can be used
  • for many different speaker configurations
  • Perhaps the most important

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Behinger DCX2496
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XTA Loudspeaker Management
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XTA Loudspeaker Management
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LAKE PROCESSOR
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LAKE PROCESSOR
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