Operating Instructions
PSW-2
Self-Powered Subwoofer
Patents Pending
Copyright © 1997, Meyer Sound Laboratories, Inc.
All rights reserved
Part #: 05.047.033.01 Rev A
The PSW-2 can withstand continuous voltages up to
275 V and allows any combination of voltage to GND
(i.e. Neutral-Hot-GND, Hot-Hot-GND). Continuous
voltages higher than 275 V may damage the unit.
Introduction
The Meyer PSW-2 self-powered subwoofer contains
independent amplifier and control electronics for two
15” drivers in a compact enclosure. The PSW-2 has the
following acoustical specifications:
The PSW-2 uses a NEMA L6-20P or IEC 309 male power
inlet and satisfies UL, CSA, and EC safety standards.
Voltage Requirements
Frequency Response
Dynamic Range
±4 dB 35 – 120 Hz
> 110 dB
The PSW-2 operates safely and without audio disconti-
nuity if theAC voltage stays within either of two operating
windows: 85–134 V or 165–264 V, at 50 or 60 Hz. After
applying AC power, the proper operating voltage is
automatically selected, but the system is muted. During
the next three seconds, the primary fan turns on, the
main power supply slowly ramps on, the green Active
LED on the user panel illuminates, and the system is
enabled to pass audio signals.
Phase Response
±30° 50 – 145 Hz
The PSW-2 is identical in size to, and matches well with
the Meyer MSL-4. The PSW-2 also operates efficiently
with the Meyer MTS-4 or CQ™ Series self-powered
speakers, and can be used in any system requiring
additional low frequency power.
The PSW-2’s integrated design improves durability and
reliability, eliminates amplifier racks, and simplifies setup
and installation. The trapezoidal shape facilitates the
creation of speaker arrays that maximize the coverage
area for the size of the array. Rigging hardware is provided
to safely suspend the PSW-2 in elevated installations.
TROUBLESHOOTING NOTE: If the Active LED does
not illuminate or the system does not respond to audio
input after ten seconds, remove AC power. Electronics
technicians with access to a test bench can contact
Meyer Sound to receive The Meyer Sound Self-Powered
Series MP-2 and MP-4 Field Verification Procedure
(part # 17.022.066.01). This service document contains a
series of tests to verify that the power supply and ampli-
fier are functioning properly. Other users should contact
Meyer Sound or an authorized service center.
The PSW-2 can be equipped to operate with the Remote
Monitoring System (RMS) network and software
application. RMS displays signal and power levels,
driver and cooling fan status, limiter activity, and
amplifier temperature for all speakers in the network
on a Windows-based PC.
If the voltage decreases below the lower bound of either
operating range (brown-out), the supply uses stored
energy to continue functioning briefly. The unit turns off
if the voltage does not increase above the threshold
before the storage circuits are depleted. The time that the
PSW-2 continues to operate during brown-out depends
on how low the voltage drops and the audio source level
during this period.
AC Power
If the voltage fluctuates within either operating range,
automatic tap selection stabilizes the internal operating
voltage. This tap selection is instantaneous and there are
no audible artifacts. If the voltage increases above the
upper bound of either range, the power supply turns off
rapidly, preventing damage to the unit.
When AC power is applied to the PSW-2, the Intelligent
AC™ supply automatically selects the correct operating
voltage, allowing the PSW-2 to be used internationally
without manually setting voltage switches. The Intelligent
AC supply performs the following protective functions
to compensate for hostile conditions on the AC mains:
Ifthe PSW-2shuts down due to either low or high voltage,
the power supply automatically turns on after three
seconds if the voltage has returned to either normal
operating range. If the PSW-2 does not turn back on after
ten seconds, removeAC power and refer to the TROUBLE-
SHOOTING NOTE above.
•
suppresses high voltage transients up to several
kilovolts
•
filters common mode and deference mode radio
frequencies (EMI)
•
•
sustains operation during low voltage periods
provides soft-start power-up, which eliminates
high inrush current
NOTE: We recommend that the supply be operated at
least a few volts away from the upper and lower bounds
of the operating windows to avoid brown-out and
possible shut-down.
3
Safety Issues
Current Requirements
Pay close attention to these important electrical and
safety issues.
The PSW-2 presents a dynamic load to the AC mains
which causes the amount of current to fluctuate between
quiet and loud operating levels. Since different types of
cables and circuit breakers heat up (and trip) at varying
rates, it is essential to understand the types of current
ratings and how they correspond to circuit breaker
and cable specifications.
Use a power cord adapter to drive the PSW-2
from a standard 3-prong outlet (NEMA 5-15R;
125 V max).
The maximum continuous RMS current is the maximum
RMS current over a duration of at least 10 seconds. It is
used to calculate the temperature increase in cables,
which is used to select cables that conform to electrical
code standards. It is also used to select the rating for
slow-reacting thermal breakers.
earth
ground
chassis
ground
The maximum burst RMS current is the maximum RMS
current over a one second duration. It is used to select
the rating for most magnetic breakers.
The PSW-2 requires a grounded outlet. Always
use a grounding adapter when connecting to
ungrounded outlets.
The maximum instantaneous peak current during burst
is used to select the rating for fast-reacting magnetic
breakers and to calculate the peak voltage drop in long
AC cables according to the formula
Vpkdrop = Ip k x Rtotal cable
Use the table below as a guide to select cables and circuit
breakerswith appropriateratingsfor your operatingvoltage.
Do not use a ground-lifting adapter or cut the
AC cable ground pin.
PSW-2 Current Ratings
115 V 230 V 100 V
Max. Continuous RMS
Max. Burst RMS
8 ARMS 4 ARMS 10 ARMS
15 ARMS 8 ARMS 18 ARMS
22 APEAK 11 APEAK 25 APEAK
Keep all liquids away from the PSW-2 to avoid hazards
from electrical shock.
Do not operate the unit if the power cables are frayed or
broken.
Max. Peak During Burst
Tie-wrap anchors on the amplifier chassis provide strain
relief for the power and signal cables. Insert the plastic
tie-wraps through the anchors and wrap them around
the cables.
The minimum electrical service amperage required by a
system of Meyer speakers is the sum of their maximum
continuous RMS currents. We recommend allowing an
additional 30% above the minimum amperage to prevent
peak voltage drops at the service entry.
TROUBLESHOOTING NOTE: In the unlikely case that
the circuit breakers trip (the white center buttons pop
out), do not reset the breakers! Contact Meyer Sound for
repair information.
4
A single source can drive multiple PSW-2s with a paral-
leled input loop, creating an unbuffered hardwired
loop connection. Make certain that the source equipment
can drive the total load impedance presented by the paral-
leled input circuit. For example, since the input impedance
of a single PSW-2 is 10 kΩ, cascading 20 PSW-2s
produces a balanced input impedance of 500 Ω. If a 150 Ω
source is used, the 500 Ω load results in a 2.28 dB loss.
Power Connector Wiring Conventions
Use the following AC cable wiring diagram to create
international or special-purpose power connectors:
brown = hot
blue =
neutral
yellow/green =
earth ground
(chassis)
Amplification and Protection
Circuitry
AC cable color code
If the colors referred to in the diagram don't correspond
to the terminals in your plug, use the following guidelines:
Each driver in the PSW-2 is powered by one channel
of the Meyer MP-2, a 1240 W amplifier (620 W/ channel)
utilizing complementary power MOSFET output stages
(class AB/ H). The following sections discuss the MP-2’s
limiting circuitry and the two-fan cooling system.
•
•
•
Connect the blue wire to the terminal marked
with an N or colored black.
Connect the brown wire to the terminal marked
with an L or colored red.
Connect the green and yellow wire to the terminal
marked with an E (or
green and yellow).
) or colored green (or
TruPower™ Limiting System
Conventional limiters assume that the resistance of a
speaker remains constant and set the limiting threshold
by measuring voltage only. This method is inaccurate
because the speaker’s resistance changes in response to
the frequency content of the source material and thermal
variations in the speaker ’s voice coil and magnet.
Conventional limiters begin limiting prematurely, which
under-utilizes system headroom and deprives the speaker
of its full dynamic range.
Audio Input
The PSW-2 presents a 10 kΩ balanced input impedance
to a three-pin XLR connector wired with the following
convention:
Pin 1 — 220 kΩ to chassis and earth ground (ESD clamped)
Pin 2 — Signal
The TruPower limiting (TPL) system accounts for varying
speaker impedance by measuring current, in addition to
voltage, to compute the power dissipation and voice coil
temperature. TPL improves performance before and
during limiting by allowing the speaker to produce its
maximum SPL across its entire frequency range. TPL
also extends the lifetime of the drivers by controlling the
temperature of the voice coil.
Pin 3 — Signal
Differential Inputs
Case — Earth (AC) ground and chassis
Shorting an input connector pin to the case can
form a ground loop and cause hum.
When the safe continuous power level is exceeded, a
single limiter engages, affecting both amplifier channels
equally. TPL activity is indicated by the Sub Limit LED
on the user panel. The limiter ceases operation when the
power level returns to normal and does not affect the
signal when the LED is inactive.
Pins 2 and 3 carry the input as a differential signal; their
polarity can be reversed with the input polarity switch
on the user panel. If the switch is in the up position,
pin 2 is hot relative to pin 3, resulting in a positive
pressure wave when a positive signal is applied to pin 2.
Use standard audio cables with XLR connectors for
balanced signal sources.
TROUBLESHOOTING NOTE: If abnormal noise (hum,
hiss, popping) is produced from the loudspeaker, dis-
connect the audio source from the speaker. If the noise
stops, then the problem is not within the loudspeaker;
check the audio input and AC power.
5
The PSW-2 performs within its acoustical specifications A foam insert filter, in combination with the entire front
and operates at a normal temperature if the TPL LED is grill surface, acts as an air filter for the cooling system.
on for no longer than two seconds, and off for at least Despite the filtering, extensive use or a dusty operating
one second. If the LED remains on for longer than three environment can allow dust to accumulate along the
seconds, the PSW-2 is hard limiting with these negative path of the airflow, preventing normal cooling. We
consequences:
recommend periodically removing the grill, filter, and
amplifier module and using a vacuum cleaner to clear
dust from the grill, filter, fans, and heatsinks. Make sure
that the air ducts are clear and that there is at least six
inches clearance for exhaust behind the cabinet.
•
•
•
Increasing the input level will not increase the
volume.
The system distorts due to clipping and nonlinear
driver operation.
cooling
fans
The life-span of driver and amplifier components is
reduced because they are subjected to excessive
heat.
The TPL LED can indicate an imbalance in a system of
speakers by functioning like a spectrum analyzer. If
speakers in a subwoofer, mid-bass, or mid-hi subsystem
begin to limit before reaching the required operating
level for the entire system, then that subsystem needs to
be supplemented with additional speakers.
air
power
supply
heatsinks
air
NOTE: Although the TPL limiters exhibit smooth sonic
characteristics, we do not recommend using them for
intentional compression effects. Use an outboard
compressor/limiter to compress a mixed signal.
A variable-speed primary fan runs continuously with an
inaudible operating noise of 22 dBA at 1 m at its slowest
speed. The speed of the primary fan begins increasing
when the temperature of the heatsinks reaches 42°C.
The fan reaches full speed at 62°C and is barely audible
near the cabinet, even without an audio signal.
Driver Excursion Clamp
The drivers in the PSW-2 are protected from over-
excursion by an excursion clamping circuit that does
not have attack or release time constants. The circuit
provides instantaneous braking for the drivers without
the pumping effects commonly produced by compressor/
limiters.
In the unusualevent that the heatsink temperature reaches
74°C, the secondary fan turns on; it turns off when the
temperature decreases to 68°C. The secondary fan is
audible at close proximity without an audio signal and
turns on in response to
•
•
•
primary fan failure (check its status immediately);
accumulation of dust in the cooling system path;
The circuit uses sophisticated filters to minimize the
distortion normally caused by clamping and clipping.
As the PSW-2’s input signal is increased past the
clamping point, the output signal remains at a fixed
level, protecting the drivers and minimizing negative
sonic effects. The PSW-2 operates safely if the Exc. Clamp
LED is on for no longer than two seconds, and off for at
least one second.
a prolonged period of high source levels in hot
temperatures or direct sunlight;
•
driver failure.
TROUBLESHOOTING NOTE:In the highly unlikely event
that the secondary fan does not keep the temperature
below 85°C, the PSW-2 automatically shuts down until
AC power is removed and reapplied. If the PSW-2 shuts
down again after cooling and reapplying AC power,
contact Meyer Sound for repair information.
Fans and Cooling System
The PSW-2 uses a forced-air cooling system with two
fans to prevent the amplifiers from overheating. The
fans draw air in through ducts on the front of the cabinet,
over the heatsinks, and out the rear of the cabinet. Since
dust does not accumulate in the amplifier circuitry, its
life-span is increased significantly.
6
Rigging
Configuration, Placement,
and Polarity
The PSW-2 weighs 162 lb (73.5 kg). The maximum rec-
ommended load for a single cabinet with aircraft pan
fittings is 600 lb (273kg). This working load is based on a
5:1 safety factor. The PSW-2 has six rigging brackets
(three on top and bottom). Each bracket is capable of
supporting the full working load of the cabinet.
Designing a full-range system requires an understanding
of how subwoofers respond when grouped together,
how they interact with nearby walls and floors, and how
their location in a system affects the choice ofpolarity to use
for other speakers. These topics are introduced as back-
ground for the section Full-Range Systems.
There are four types of interchangeable rigging brackets,
each fastened by six Phillips screws:
Configuration
•
•
•
•
aircraft pan fittings (ring and stud)
3/ 8”-16 nut plates
A single subwoofer has an essentially omnidirectional
coverage pattern. A horizontal line with two adjacent
subs narrows the horizontal coverage area, without
changing the vertical coverage, compared to one sub. A
vertical stack of two subs narrows the vertical coverage
without changing the horizontal coverage. In both cases,
there is 3 to 6 dB SPL of on-axis addition.
M-10 x 1.5 metric nut plates
blank plates (if no rigging brackets are requested)
NOTE: Units with nut plates are rated for the weight of
one cabinet only.
Increasing the size of the horizontal or vertical array
from two to three subs further narrows the respective H
or V coverage without changing the corresponding V or
H coverage. Both the vertical and horizontal three-sub
arrays provide approximately 10 dB SPL addition more
than one sub.
rigging brackets
three on top, three on bottom
Increasing the number of subs in the horizontal or vertical
array increases the corresponding H or V directional
control and the system SPL. A properly designed vertical
array steers low frequencies to include balconies and
upper tiers but avoids unnecessary interaction with the
ceiling; a horizontal array focuses low frequencies for
the longer throw distances required by large venues.
Handles are for carrying only.
Do not use them for rigging!
!
Rigging load ratings assume a straight tensile pull and
that the cabinet is in new condition with aircraft pan
fittings. If the preceding conditions are not met, or the
rigging is worn or damaged, the load ratings can be
reduced significantly. Inspect the rigging hardware
regularly and replace worn or damaged components
immediately.
The three-by-two array (below left) narrows the H and V
coverages, and produces 10 to 15 dB SPL more than a
single sub. Combining the vertical and horizontal arrays
in an L-configuration (below right)provides more on-axis
SPL and directional control than the three-by-two array.
The cabinet, exposed electronic circuitry, and drivers can
receive protective treatment that permits safe use in wet
conditions. Additionally, a rain hood can be fitted to
shield cables and electronics. Do not install a unit outdoors
without weather protection!Contact Meyer Sound for more
information.
NOTE: All Meyer Sound products must be used in accor-
dance with local, state, federal, and industry regulations.
It is the owner’s and/or user’s responsibility to evaluate
the reliability of any rigging method for their application.
Rigging should be done only by experienced professionals.
Both the three-by-two group and L-configuration increase
the SPL and directional control.
7
We recommend using the Meyer LD-1A Line Driver to
integrate different types of Meyer self-powered speakers
Placement
One of the most important factors governing subwoofer into a complete system. The LD-1A has two channels
response is their placement relative to adjacent surfaces. equipped to control a full-range main system, and six
Subwoofers gain significant power by coupling, or loading, auxiliary channels for down-fill, front-fill, and delay
with nearby floors and walls. Half-space loading describes systems. The LD-1A maintains signal integrity for long
a speaker coupling with one surface. Subs placed on cable paths and provides the following useful functions:
the floor benefit from half-space loading, while flown
•
The Lo Cut switch activates a high-pass filter
(160 Hz, –12 dB/ oct, Q = 0.8) that performs a
crossover function for the Mid-Hi output.
subs in free-space (without a nearby wall or ceiling) do
not. In general, subs in half-space generate twice the
SPL (+6 dB) compared to the same number in free-space.
•
The DS-2 & Sub Crossover switch (channels 1 and
2 only) activates a crossover network optimized
for the DS-2P when used with the PSW-2 or 650-P.
With the switch in, frequencies below 80 Hz are
sent to the Sub output (for the 650-P), and above
80 Hz to the DS-2 output. When the subwoofer is
used without the DS-2P, the switch should be out,
which sends a full-range signal to both the DS-2
and Sub outputs.
It can be beneficial to fly subwoofers, despite the lack of
half-space loading. Placing subwoofers within a flown
cluster of mid-hi speakers creates a smooth frequency
image because the subs are not separated by the distance
from the cluster to the floor.
NOTE: SPL values refer to an on-axis measurement
position. The actual SPL addition and narrowing of
coverage varies with frequency and depends on the
distance between cabinets, loading conditions, and
room acoustics.
•
•
The DS-2 φ and Sub φ switches (channels 1 and 2
only) toggle the polarity for the DS-2 and Sub
outputs.
Polarity
The Mid-Hi, DS-2, and Sub outputs (channels 1
and 2 only) each have their own gain control and
mute switch.
The cabinets in the Full-Range Systems section are in a
close-proximity coplanar orientation, unless otherwise
stated. Separating a mid-hi speaker from a subwoofer
by more than 5 ft may require setting the speakers to
opposite polarities to compensate for the propagation
delay from each speaker to the designated listening or
measurement position.
POLARITY NOTE: The polarity for Meyer self-powered
speakers may be reversed using the input polarity switch
on the user panel. The LD-1A also allows polarity reversal
with the DS-2 φ and Sub φ switches for speakers
connected to the DS-2 and Sub outputs. When making
polarity decisions in applications that include the LD-1A,
check the state of all polarity switches.
In a coplanar orientation, externally amplified Meyer
subwoofers require the opposite polarity setting to all
Meyer self-powered speakers.
Full-Range Systems
Measurement and System
Integration Tools
Meyer Speaker Types
The following Meyer speakers are mentioned in the
example applications.
It is essential that even the most carefully assembled
sound systems be analyzed with precise measurement
tools. We recommend using the Meyer SIM® System II
Sound Analyzer and CP-10 Parametric Equalizer to
MSL-4 Self-powered mid-hi speaker
CQ Series Self-powered mid-hi speaker
MTS-4 Self-powered full-range speaker
650-P Self-powered subwoofer
•
•
•
assist the process of choosing and configuring
speakers;
USW-1 Externally amplified subwoofer
measure propagation delays between subsystems
to set the correct polarity and delay times;
The Meyer self-powered speakers listed above have a
loop connection to send the input signal to another
speaker. Full-range signals may be applied to all Meyer
self-powered subwoofers because they have built-in
active crossovers that filter mid-hi frequencies.
measure and equalize variations in frequency
response caused by the acoustical environment
and the placement and interaction of speakers.
8
The CH 1 Mid-Hi output drives the MSL-4 with the Lo
Cut filter in. The CH 1 Sub and DS-2 outputs drive the
650-Ps and PSW-2s with the DS-2 & Sub Crossover
switch out, which sends a full-range signal with inde-
pendent level control to each speaker.
PSW-2 and MSL-4
The PSW-2 is compatible with the MSL-4, CQ, and MTS-4.
However, since the LF (low frequency) response for each
speaker overlaps with the PSW-2, the system frequency
response exhibits a rise in the range 65– 120 Hz (MSL-4),
40–120 Hz (CQ), and 30–120 Hz (MTS-4). It is important
to emphasize that the speakers are in phase in this
region. The rise can be corrected using the Meyer CP-10
Parametric Equalizer, if desired.
MSL-4 and
PSW-2
flown in
same cluster
CH 1 Mid-Hi
LD-1A
Line Driver
CH 1 Input
CH 1 DS-2
CH 1 Sub
MSL-4
PSW-2
input
loop
CP-10 EQ
(1 Channel)
650-P
subwoofer
on the floor
Set the MSL-4 and PSW-2 to the same polarity. The polarity
for the 650-P depends on the distance of the measurement
position relative to the subwoofers and the flown cluster.
Set the MSL-4 and PSW-2 to the same polarity.
LD-1A with PSW-2 and MSL-4
PSW-2 and USW-1
Activating the Lo Cut filter on the LD-1A for the CH 1
Mid-Hi output also eliminates the LF rise caused by the
overlap between the MSL-4 and PSW-2. Although a
typical MSL-4 : PSW-2 ratio is 2:1, CH 1’s Sub and Mid-
Hi level controls allow the ratio to vary while maintain-
ing control of the spectral balance of the system.
Although it is preferable to employ the PSW-2 in a
completely self-powered system, the PSW-2 can be used
with the USW-1 externally amplified subwoofer if:
•
the B-2EX CEU is set to the maximum output
level;
•
•
the USW-1’s amplifier is set to 26 dB gain;
the PSW-2 is set to the opposite polarity to the
USW-1 amplifier.
MSL-4
CH 1 Mid-Hi
LD-1A
CH 1 Input
Line Driver
CP-10 EQ
PSW-2
PSW-2
CH 1 Sub
Set the MSL-4 and PSW-2 to the same polarity.
B-2EX
CEU
Amplifier
USW-1
LD-1A with Flown PSW-2 and MSL-4;
650-P on the Floor
level control 26 dB gain
at maximum
Including subwoofers in a flown cluster provides a smooth
frequency image because the low and mid-hi frequencies
are produced from speakers located close together. The
identical dimensions of the PSW-2 and MSL-4 allow them
to be easily flown together.
Set the PSW-2 to the opposite polarity to the USW-1
amplifier.
POLARITY NOTE: It is advisable to check the polarity of
adjacent PSW-2 and USW-1 cabinets by following the
instructions in the Verifying Driver Polarity section on
page 10.
9
Driver Polarity in the Same Loudspeaker
Driver Troubleshooting
A cabinet with two identical drivers receiving the same
input signal produces an extremely low amplitude output
signal if the polarity of the drivers is reversed. Use the
following test procedure to verify the polarity between
drivers in the same loudspeaker:
The Remote Monitoring System (RMS)is the best method
to query the status of the drivers in a system before and
during the performance. RMS monitors peak power,
peak voltage, and average voltage (VU) for each amplifier
channel, allowing immediate detection and muting for
drivers with open or shorted voice coils, with minimal
disruption to the system. Contact Meyer Sound for more
information about RMS.
1. Place a measurement microphone 3 ft from the
front of a loudspeaker that is known to be wired
correctly, at the mid-point between the two drivers.
2. Connect a signal source to the loudspeaker and
note the frequency response and overall level.
In the absence of RMS, several methods can be employed
to obtain information about the state of the drivers.
3. Place a measurement microphone 3 ft from the
front of the loudspeaker with unknown polarity,
at the mid-point between the two drivers.
Troubleshooting with TPL
4. Connect a signal source to the loudspeaker and
note the frequency response and overall level.
The TPL LED can indicate serious driver problems, if
interpreted correctly. If one PSW-2 in a system exhibits
substantially more TPL activity than others receiving
the same audio signal, then one or both drivers in that
unit may have a short circuit. This is a potentially
dangerous condition for the electronics; shut the PSW-2
down immediately.
This driver is180° out of phase
The TPL circuit does not activate if there is no power
dissipation in the driver, regardless of the input signal
level. Therefore, if all PSW-2s in a system receiving the
same audio signal exhibit TPL activity except one, then
that unit may have an open voice coil; disconnect it and
contact Meyer Sound for repair information.
Drivers with correct
polarity cause acoustic
addition
Drivers with reverse
polarity cause acoustic
cancellation
The polarity is correct if the frequency response
remains constant for both tests, with the same overall
level. Broadband cancellation (decreased overall level)
for the cabinet being tested indicates polarity reversal.
Driver Replacement
To determine whether a driver is functioning properly,
or replace a damaged driver, contact Meyer Sound to
obtain the Low Driver Inspection and Evaluation
Procedure for Self-Powered Series Products (part #
17.010.120.01).
Polarity Between Adjacent Loudspeakers
Use the following test procedure to verify the polarity
between adjacent loudspeakers of the same type:
1. Position two loudspeakers adjacent to each other.
2. Place a measurement microphone 3 ft from the
speakers on the axis between them.
Verifying Driver Polarity
3. Connect a signal source to one speaker and note the
frequency response and overall level.
Incorrect driver polarity impairs system performance
and may damage the drivers. All Meyer loudspeakers
are shipped with the drivers in correct alignment. How-
ever, if the driver or circuit wiring has been removed or
disassembled in any loudspeaker in a system for any
reason, it is essential to check the polarity between
drivers in the same cabinet and between adjacent loud-
speakers.
4. Apply the same signal to the second speaker with
the first speaker still connected.
The polarity is correct if the frequency response remains
constant with a significant increase in amplitude. Broad-
band cancellation indicates polarity reversal.
NOTE: Checking the polarity of more than two adjacent
cabinets in one test may damage the drivers in the
cabinet with reversed polarity.
NOTE: Since polarity reversal causes excessive driver
excursion at high source levels, use moderate levels for
these tests.
10
!
Safety Summary
English
Français
•
•
To reduce the risk of electric shock, disconnect the loud-
speaker from the AC mains before installing audio cable.
Reconnect the power cord only after making all signal
connections.
•
•
Pour réduire le risque d’électrocution, débrancher la
prise principale de l’haut-parleur, avant d’installer le
câble d’interface allant à l’audio. Ne rebrancher le bloc
d’alimentation qu’après avoir effectué toutes les connections.
Connect the loudspeaker to a two-pole,three wire ground-
ing mains receptacle. The receptacle must be connected to
a fuse or circuit breaker. Connection to any other type of
receptacle poses a shock hazard and may violate local
electrical codes.
Branchez l’haut-parleur dans une prise de courant à 3
dérivations (deux pôles et la terre). Cette prise doit être
munie d’une protection adéquate (fusible ou coupe-circuit).
Le branchement dans tout autre genre de prise pourrait
entraîner un risque d’électrocution et peut constituer une
infraction à la réglementation locale concernant les
installations électriques.
•
•
•
•
Do not install the loudspeaker in wet or humid locations
without using weather protection equipment from Meyer
Sound.
•
•
Ne pas installer l’haut-parleur dans un endroit où il y a de
l’eau ou une humidité excessive.
Do not allow water or any foreign object to get inside the
loudspeaker. Do not put objects containing liquid on, or
near, the unit.
Ne pas laisser de l’eau ou tout objet pénétrer dans l’haut-
parleur. Ne pas placer de r´cipients contenant un liquide
sur cet appareil, ni à proximité de celui-ci.
To reduce the risk of overheating the loudspeaker, avoid
exposing it to direct sunlight. Do not install the unit near
heat emitting appliances, such as a room heater or stove.
•
•
Pour éviter une surchauffe de l’haut-parleur, conserver-la
à l’abri du soleil. Ne pas installer à proximité d’appareils
dégageant de la chaleur tels que radiateurs ou appareils
de chauffage.
This loudspeaker contains potentially hazardous volt-
ages. Do not attempt to disassemble the unit. The unit
contains no user serviceable parts. Repairs should be
performed only by factory trained service personnel.
Ce haut-parleur contient des circuits haute tension
présentant un danger. Ne jamais essayer de le démonter.
Il n’y a aucun composant qui puisse être réparé par
l’utilisateur.Toutes les réparations doivent être effectuées
par du personnel qualifié et agréé par le constructeur.
Deutsch
Español
•
•
Um dieGefahr eineselektrischen Schlagesaufein Minimum
zu reduzieren, den Lautsprecher vom Stromnetz trennen,
bevor ggf. ein Au d io-Schnittstellensignalkabel
angeschlossen wird. Das Netzkabel erst nach Herstellung
aller Signalverbindungen wieder einstecken.
•
•
Para reducir el riesgo de descarga eléctrica, desconecte de
la red el altoparlante antes de instalar el cable de
señalización de interfaz de la segnale. Vuelva a conectar el
conductor flexible de alimentación solamente una vez
efectuadas todas las interconexiones de señalizatción.
Der Lautsprecher an einegeerdetezweipoligeDreiphasen-
Netzsteckdose anschließen.Die Steckdose muß mit einem
Conecte elaltoparlante a un tomacorriente bipolar y trifilar
con neutro de puesta a tierra. El tomacorriente debe estar
conectado a la protección de derivación apropiada (ya sea
un fusible o un disyuntor). La conexión a cualquier otro
tipo de tomacorriente puede constituir peligro de descarga
eléctrica y violar los códigos eléctricos locales.
geeigneten
Abzw eigschu tz (Sicheru ng od er
Leistungsschalter) verbunden sein. Der Anschluß der
unterbrechungsfreien Stromversorgung an einen anderen
Steckdosentyp kann zu Stromschlägen führen und gegen
die örtlichen Vorschriften verstoßen.
•
•
No instale el altoparlante en lugares donde haya agua o
humedad excesiva.
•
•
Der Lautsprecher nicht an einem Ort aufstellen, an dem
sie mit Wasser oder übermäßig hoher Luftfeuchtigkeit in
Berührung kommen könnte.
No deje que en el altoparlante entre agua ni ningún objeto
extraño. No ponga objetos con líquidos encima de la
unidad ni cerca de ella.
Darauf achten, daß weder Wasser noch Fremdkörper in
das Innere den Lautsprecher eindringen. Keine Objekte,
d ie Flü ssigkeit enthalten, au f od er neben d ie
unterbrechungsfreie Stromversorgung stellen.
•
•
Para reducir el riesgo de sobrecalentamiento, no exponga
la unidad a los rayos directos del sol ni la instale cerca de
artefactos que emiten calor, como estufas o cocinas.
•
•
Um ein Überhitzen dem Lautsprecher zu verhindern, das
Gerät vor direkter Sonneneinstrahlung fernhalten und
nicht in d er N ähe von w ärm eabstrahlend en
Haushaltsgeräten (z.B. Heizgerät oder Herd) aufstellen.
Este altoparlante contiene niveles de voltaje peligrosos en
potencia.No intente desarmar la unidad,pues no contiene
piezas que puedan ser repardas por el usuario. Las
reparaciones deben efectuarse únicamente por parte del
personal de mantenimiento capacitado en la fábrica.
Im Inneren diesem Lautsprecher herrschen potentiell
gefährliche Spannungen. Nicht versuchen, das Gerät zu
öffnen.Es enthält keine vom Benutzer reparierbaren Teile.
Rep aratu ren d ü rfen nu r von au sgebild etem
Kundenienstpersonal durchgeführt werden.
11
Controls and Connectors
!
WARNINGS:
THIS PRODUCT MUST BE GROUNDED
This surface may reach high temperatures while in use.
To ensure proper operation, allow at least inches
6
Mains AC inlet
clearance from this surface and adequate ventilation.
To reduce the risk of electric shock do not remove cover.
No operator serviceable parts inside.
Mains circuit
breakers
Refer servicing to qualified personnel.
To reduce the risk of fire or electric shock
do not expose this appliance to rain or moisture.
Tie-wrap anchor
ATENCIÓN
:
ACCESO INTERNO SOLO
AUTORIZADO
A
PERSONAL TÉCNICO CALIFICADO
PSW-2
ACHTUNG
:
GEHÄUSE NICHT ÖFFNEN WARTUNG
UND REPARATUR NUR DURCH ELEKTROFACHKRÄFTE
Driver Excursion Clamp
Sub Limit (red)
Exc. Clamp
SUB Limit
ATTENTION ENTRETIEN ET REPARATIONS
:
INTERNES NE SONT AUTORISEES QU'AU
PERSONNEL TECHNIQUE QUALIFIÉ
Active
/
Speaker Fault
UK WARNING: THIS APPARATUS MUST BE EARTHED.
NO OPERATOR SERVICEABLE PARTS INSIDE.
REFER SERVICING TO QUALIFIED PERSONNEL
THIS PRODUCT MUST BE GROUNDED
Input Polarity
PUSH
Power LED (green/red)
Input polarity switch
2
3
+
+
!
10K
Balanced
Ω
Auto-Voltage Select
WARNINGS:
This surface may reach high tea
95-125V
50-60Hz
~
208-235V~
50-60Hz
To ensure proper operation, all
1400W RMS MAX 1400W RMS MAX
clearance from this surface and q
To reduce the risk of electric sh
No operator serviceable parts i
qualified personnel.
1
ESD
220K
Case
Ω
2
2
1
1
To reduce the risk of fire or elec
this appliance to rain or moistu
3
3
Earth / Chassis
Signal input and
loop connectors
ATENCIÓN: ACCESO INTEO
Network
A
PERSONAL TÉCNICO CALIA
Input
Loop
ACHTUNG: GEHÄUSE NI
WARTUNG UND REPARATU
ELEKTROFACHKRÄFTE
Remote Monitoring
System panel
(if RMS is installed)
ATTENTION: ENTRETIEN
INTERNES NE SONT AUTORI
TECHNIQUE QUALIFIÉ
Meyer Sound, Berkeley, CA. USA
Remote Monitoring System
UK WARNING: THIS APPT
NO OPERATOR SERVICEABLE T
SERVICING TO QUALIFIED PERN
y
in
Auto-Voltage e
8A RMS
20A Peak
2
3
1
+
~
+
95-125
50-60Hz
PUSH
700W RMS
Rear User Panel shown with the optional
Remote Monitoring System (RMS) panel
E
E
ssis
ssis
2
1
2
1
3
3
Made by:Meyer Sound,Berkeley,Ca. U.S.A.
European Office:
Meyer Sound Europe
14, Long Barn Lane,
Reading, Berkshire,
England RG2 7SZ
Meyer Sou
ISTED
U
® L
3K59
C
MMERCIAL
O SYSTEM
Loop
Input
European User Panel with
IEC 309 connector
Dimensions
All units in inches
Front
Side
Top
30.0"
13.0"
21.25"
22.0"
10.6"
21.25"
13.2"
36.0"
13.4"
14.0"
30.3"
5.5"
7.5°
Contact Information
Meyer Sound Germany
Gmbh
Meyer Sound Laboratories, Inc.
2832 San Pablo Avenue
Carl Zeiss Strasse 13
56751 Polch, Germany
Telephone: 49.2654.9600.58
Berkeley, California 94702
Telephone:510 - 486 - 1166
FAX:
510 - 486 - 8356
FAX:
49.2654.9600.59
E-mail: [email protected]
12
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