Meyer Sound Portable Speaker M2D User Manual

OPERATING INSTRUCTIONS  
M SERIES  
M2D Compact Curvilinear Array Loudspeaker  
M2D-Sub Compact Subwoofer  
Keep these important operating instructions.  
Download from Www.Somanuals.com. All Manuals Search And Download.  
SYMBOLS USED  
These symbols indicate important safety or operating features in this booklet and on the chassis:  
Dangerous voltages: risk of  
electric shock  
Important operating  
instructions  
Frame or chassis  
Masse, châssis  
Protective earth ground  
Terre de protection  
Pour indiquer les risques  
résultant de tensions  
dangereuses  
Pour indequer important  
instructions  
Zu die gefahren von  
gefährliche spanning zeigen  
Zu wichtige betriebs-  
anweisung und unter-  
haltsanweisung zeigen  
Rahmen oder chassis  
Armadura o chassis  
Die schutzerde  
Para indicar voltajes  
peligrosos.  
Instrucciones importantes  
de funcionamiento y/o  
manteniento  
Tierra proteccionista  
IMPORTANT SAFETY INSTRUCTIONS  
1
Read these instructions.  
11. Only use attachments/accessories specified by Meyer  
Sound.  
2. Keep these instructions.  
3. Heed all warnings.  
12. Use only with the caster rails or rigging specified by  
Meyer Sound, or sold with the loudspeaker. Handles  
are for carrying only.  
4. Follow all instructions.  
5. Do not use this loudspeaker near water.  
6. Clean only with dry cloth.  
CAUTION: Rigging should only be done by  
experienced professionals.  
7. Do not block any ventilation openings. Install  
in accordance with Meyer Sound's installation  
instructions.  
13. Unplug this loudspeaker during lightning storms or  
when unused for long periods of time.  
8. Do not install near any heat sources such as radiators,  
heat registers, stoves, or other apparatus that produce  
heat.  
14. Refer all servicing to qualified service personnel.  
Servicing is required when the loudspeaker has been  
damaged in any way, such as when the power-supply  
cord or plug has been damaged; liquid has been  
spilled or objects have fallen into the loudspeaker;  
rain or moisture has entered the loudspeaker;  
the loudspeaker has been dropped; or when for  
undetermined reasons the loudspeaker does not  
operate normally.  
9. Do not defeat the safety purpose of the grounding-  
type plug. A grounding type plug has two blades and  
a third grounding prong. The third prong is provided  
for your safety. If the provided plug does not fit into  
your outlet, consult an electrician for replacement of  
the obsolete outlet.  
10. Protect the power cord from being walked on  
or pinched, particularly at plugs, convenience  
receptacles, and the point where they exit from the  
loudspeaker. The AC mains plug or appliance coupler  
shall remain readily accessible for operation.  
iii  
Download from Www.Somanuals.com. All Manuals Search And Download.  
SAFETY SUMMARY  
English  
-
-
Ne pas laisser de l’eau ou tout  
objet pénétrer dans l’haut-parleur.  
Ne pas placer de r´cipients  
Haushaltsgeräten (z.B. Heizgerät  
oder Herd) aufstellen.  
Im Inneren diesem Lautsprecher  
herr-schen potentiell gefährliche  
Spannungen. Nicht versuchen,  
das Gerät zu öffnen. Es  
enthält keine vom Benutzer  
reparierbaren Teile. Reparaturen  
dürfen nur von ausgebildetem  
Kundenienstpersonal durchgeführt  
werden.  
-
To reduce the risk of electric  
shock, disconnect the loudspeaker  
from the AC mains before installing  
audio cable. Reconnect the power  
cord only after making all signal  
connections.  
-
contenant un liquide sur cet  
appareil, ni à proximité de celui-ci.  
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.  
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  
-
Connect the loudspeaker to a  
two-pole, three-wire grounding  
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.  
-
Español  
-
Para reducir el riesgo de descarga  
eléctrica, desconecte de la red  
de voltaje el altoparlante antes de  
instalar el cable de señal de audio.  
Vuelva a conectar la alimentacion  
de voltaje una vez efectuadas  
todas las interconexiones de  
señalizacion de audio.  
Conecte el altoparlante 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.  
No instale el altoparlante en  
lugares donde haya agua o  
humedad excesiva.  
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.  
-
-
Do not install the loudspeaker  
in wet or humid locations  
without using weather protection  
equipment from Meyer Sound.  
Do not allow water or any  
réparé par l’utilisateur. Toutes les  
réparations doivent être effectuées  
par du personnel qualifié et agréé  
par le constructeur.  
foreign object to get inside the  
loudspeaker. Do not put objects  
containing liquid on or near the  
unit.  
Deutsch  
-
-
Um die Gefahr eines elektrischen  
Schlages auf ein Minimum zu  
reduzieren, den Lautsprecher  
vom Stromnetz trennen, bevor  
ggf. ein Audio-Schnittstellensign  
alkabel angeschlossen wird. Das  
Netzkabel erst nach Herstellung  
aller Signalverbindungen wieder  
einstecken.  
Der Lautsprecher an eine  
geerdete zweipolige Dreiphasen-  
Netzsteckdose anschließen.  
Die Steckdose muß mit einem  
geeigneten Abzweigschutz  
(Sicherung oder Leistungsschalter)  
verbunden sein. Der Anschluß  
der unterbrechungsfreien  
Stromversorgung an einen  
anderen Steckdosentyp kann  
zu Stromschlägen führen und  
gegen die örtlichen Vorschriften  
verstoßen.  
Der Lautsprecher nicht an einem  
Ort aufstellen, an dem sie mit  
Wasser oder übermäßig hoher  
Luftfeuchtigkeit in Berührung  
kommen könnte.  
Darauf achten, daß weder  
Wasser noch Fremdkörper in  
das Innere den Lautsprecher  
eindringen. Keine Objekte, die  
Flüssigkeit enthalten, auf oder  
neben die unterbrechungsfreie  
Stromversorgung stellen.  
Um ein Überhitzen dem  
-
-
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.  
This loudspeaker contains  
potentially hazardous voltages. Do  
not attempt to disassemble the  
unit. The unit contains no user-  
serviceable parts. Repairs should  
be performed only by factory-  
trained service personnel.  
-
-
-
Français  
-
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.  
-
-
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.  
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.  
-
-
-
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.  
-
Lautsprecher zu verhindern,  
das Gerät vor direkter  
Sonneneinstrahlung fernhalten  
und nicht in der Nähe von  
wärmeabstrahlenden  
-
Ne pas installer l’haut-parleur dans  
un endroit où il y a de l’eau ou une  
humidité excessive.  
iv  
Download from Www.Somanuals.com. All Manuals Search And Download.  
CONTENTS  
v
Download from Www.Somanuals.com. All Manuals Search And Download.  
INTRODUCTION  
INTRODUCTION  
HOW TO USE THIS MANUAL  
As you read this manual, you’ll find figures and diagrams  
to help you understand and visualize what you’re reading.  
You’ll also find numerous icons that serve as cues to flag  
important information or warn you against improper or  
potentially harmful activities. These icons include:  
A NOTE identifies an important or useful  
piece of information relating to the topic  
under discussion.  
Figure i.1. M2D compact curvilinear array loudspeaker  
The M2D loudspeaker gives you the flexibility to tailor  
vertical coverage by varying the number and splay of  
cabinets in the array while maintaining a constant 90  
degrees of horizontal coverage. For high frequencies, the  
M2D loudspeaker utilizes Meyer Sound’s patented REM™  
ribbon emulation manifold to couple a single compression  
driver with a 1.5-inch exit (4-inch diaphragm) to a horn  
with 90-degree constant-directivity horizontal coverage.  
(The vertical coverage of the array depends upon the array  
length and curvature). The M2D loudspeaker’s mid-low  
section comprises two high-power 10-inch drivers with  
lightweight neodymium magnet assemblies housed in a  
compact, vented trapezoidal enclosure.  
A TIP offers a helpful tip relevant to the topic  
at hand.  
A CAUTION gives notice that an action can  
have serious consequences and could cause  
harm to equipment or personnel, delays, or other  
problems.  
In addition, to assure the smoothest response in the critical  
midrange, the M2D loudspeaker incorporates a complex  
crossover design. At the lowest frequencies, both 10-inch  
drivers combine to reproduce powerful, coherent bass,  
while in the mid frequencies the crossover feeds only one  
of the two drivers. This ingenious technique eliminates  
interference between the drivers that would otherwise occur  
at shorter wavelengths near the crossover frequencies.  
INTRODUCING THE M2D AND M2D-SUB  
LOUDSPEAKERS  
As part of Meyer Sound’s M Series, the M2D compact  
curvilinear array loudspeaker and M2D-Sub compact  
subwoofer bring numerous advantages to mid-sized venues  
that require tight vertical pattern control with long throw.  
Self-powered, with QuickFly® rigging and Meyer Sound’s  
RMS™ remote monitoring system as standard, the M2D  
and M2D-Sub loudspeakers can be deployed as a self-  
contained system or configured along with other Meyer  
Sound loudspeakers in more complex systems.  
The companion M2D-Sub subwoofer (Figure i.2), designed  
specifically to work with the M2D, extends overall system  
power bandwidth and frequency range down to 28 Hz.  
Operating at a frequency range of 60 Hz to 16 kHz, the  
M2D loudspeaker’s compact enclosure (Figure i.1) is  
designed specifically for vertical curvilinear arrays of up to  
16 cabinets having 0- to 7-degree splay between units in  
1-degree increments.  
Figure i.2. M2D-Sub compact subwoofer  
1
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
INTRODUCTION  
With an operating frequency range of 28 Hz to 160 Hz,  
the dual 15-inch M2D-Sub loudspeaker complements the  
M2D loudspeaker in reinforcement applications requiring  
extended low-frequency headroom.  
The M2D and M2D-Sub loudspeakers are fitted with  
Meyer Sound’s RMS remote monitoring system, allowing  
the full range of operating parameters to be monitored  
continuously over a network using a Windows® computer.  
In addition, both loudspeakers are supported by the Meyer  
Sound MAPP Online® multipurpose acoustical prediction  
program for easy and accurate system design. The MAPP  
Online prediction program allows quick prediction of  
coverage, frequency response, impulse response and  
maximum output of arrayed loudspeakers, and more.  
The M2D-Sub loudspeaker affords 138 dB SPL peak output  
capability. It employs two Meyer Sound ferrofluid cooled,  
back-vented drivers each featuring a 4-inch voice coil with  
a lightweight neodymium magnet structure. Each driver is  
rated to handle 1200 AES watts.  
NOTE: Power handling is measured under  
AES standard conditions: Transducer driven  
continuously for two hours with band-limited noise  
signal having a 6 dB peak-average ratio.  
NOTE: See Chapter 4, “Remote Monitoring  
System,” and Chapter 5, “System Design  
and Integration Tools,” for more information about  
the RMS monitoring system and the MAPP Online  
prediction program.  
An integral two-channel class AB/H complementary  
MOSFET amplifier provides very high burst capability,  
and Intelligent AC performs automatic voltage selection,  
allowing the unit to accommodate worldwide mains  
voltages without manually setting a voltage switch.  
NOTE: Read this entire manual carefully  
before configuring and deploying your M2D  
and M2D-Sub system. In particular, pay careful  
attention to the sections about safety issues.  
Integral peak and rms limiters featuring Meyer Sound’s  
TruPower® limiting technology protect M2D-Sub  
components from over-excursion and over-heating while  
assuring minimal power compression and maximum peak  
headroom.  
Information and specifications are applicable as of the date  
of this printing. Updates and supplementary information are  
posted on the Meyer Sound web site at:  
You may contact Meyer Sound Technical Support at:  
Tel: +1 510 486.1166  
Fax: +1 510 486.8356  
2
Download from Www.Somanuals.com. All Manuals Search And Download.  
CHAPTER 1  
CHAPTER 1: POWER REQUIREMENTS  
The M2D and M2D-Sub loudspeakers represent advanced  
technology with equally advanced power capabilities.  
Understanding power distribution, voltage and current  
requirements, as well as electrical safety issues, is critical  
to their safe operation and deployment.  
CAUTION: Ensure that you select the  
correct power plug for the AC power in the  
area in which you use your loudspeaker.  
When AC power is applied to the M2D or M2D-Sub  
loudspeaker, the Intelligent AC power supply automatically  
selects the correct operating voltage, allowing the  
loudspeakers 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:  
AC POWER  
The M2D and M2D-Sub loudspeakers use a PowerCon®  
3-pole AC mains system with locking connectors to  
prevent accidental disconnection or a multipin VEAM™  
male power connector (Figures 1.1, 1.2 and 1.3).  
Suppresses high-voltage transients up to several  
kilovolts  
 
Filters common mode and difference mode radio  
frequencies (EMI)  
Sustains operation temporarily during low-voltage  
periods  
Provides soft-start power-up, which eliminates high  
inrush current  
PowerCon connector  
Figure 1.1. M2D user panel with PowerCon connector  
AC Power Distribution  
Refer servicing to qualified personnel.  
To reduce the risk of fire or electric shock  
do not expose this appliance to rain or moisture.  
PowerCon connector  
All amplifier modules and directly associated audio  
equipment (mixing consoles, processors, etc.) must  
be connected to the AC power distribution in a proper  
manner, preserving AC line polarity and connecting earth  
ground such that all grounding points are connected to a  
single node or common point using the same cable gauge  
as the neutral and line(s) cable(s).  
ATENCI”N: ACCESO INTERNO SOLO  
AUTHORIZADO  
A
PERSONAL T…CNICO CALIFICO  
ACHTUNG: GEHUSE NICHT OFFENE WARTUNG  
UND REPARATUR NUR DURCH ELEKTROFCHKRAFTE  
ATTENTION: ENTRETIENET REPARATIONS  
INTERNES NE SONT AUTORISEES QU'AU  
PERSONNEL TECHNIQUE QUALIFI…  
U.K. WARNING: THIS APPARATUS MUST BE EARTHED.  
NO OPERATOR SERVICEABLE PARTS INSIDE.  
REFER SERVICING TO QUALIFIED PERSONNEL.  
Auto-Voltage Select  
95-125V  
50-60Hz  
~
208-235V~  
50-60Hz  
1400W RMS MAX 1400W RMS MAX  
Operational Voltage Range:  
Turn on 85V~ Turn off 134V~  
Turn on 165V~ Turn off 264V~  
Improper grounding connections between loudspeakers  
and the rest of the audio system may produce noise, hum  
and/or serious damage to the input/output stages in the  
system’s electronic equipment.  
Meyer Sound, Berkeley, CA USA  
Figure 1.2. M2D-Sub user panel with PowerCon connector  
CAUTION: Before applying AC to any  
Meyer Sound self-powered loudspeaker, be  
sure that the voltage potential difference between  
neutral and earth ground is less than 5 volts AC.  
line (brown)  
ground (green/yellow)  
neutral (blue)  
Figure 1.3. Optional VEAM multipin connector power pin-out  
3
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 1  
Figure 1.4 shows a sample three-phase AC distribution  
system, with the load between loudspeakers distributed  
among the three phases and all of the loudspeakers  
connected to common neutral and earth ground points.  
 
�  
 
 
�  
�  
�  
�  
���  
�  
 
�  
�  
 
���  
���������������������  
���  
 
��  
���  
 
�  
 
 
 
 
 
 
 
 
 
 
�  
 
 
 
 
����  
�������������������  
����  
�������������������  
����  
�������������������  
�����  
 
�  
�  
��  
�  
Figure 1.4. A sample AC power distribution block diagram  
CAUTION: Continuous voltages higher than  
265 volts can damage the unit.  
TIP: Since M2D and M2D-Sub loudspeakers  
do not require a dedicated Neutral, and can  
tolerate elevated voltages from ground, they can  
be connected between line-line terminals in a 120  
volts 3-phase Wye system. This results in 208 volts  
AC betweens lines (nominal) and will therefore draw  
less current for the same output power compared  
to operating the loudspeaker from 120 volts AC  
(line- neutral). Make sure that the voltage remains  
within the recommend operating window. The  
ground terminal must always be used for safety and  
the line-to-ground voltage should never exceed 250  
volts AC (typically there will be 120 volts AC from  
line to ground in the above example).  
Figure 1.5. VIM-3 (top) and VIM-4 (bottom) modules  
Use the AC cable wiring diagram below (Figure 1.6) to cre-  
ate international or special-purpose power connectors:  
Power Connector Wiring  
The M2D and M2D-Sub loudspeakers require a grounded  
outlet. It is very important that the system be properly  
grounded in order to operate safely and properly.  
Figure 1.6. AC cable color code  
If the colors referred to in the diagrams don’t correspond to  
the terminals in your plug, use the following guidelines:  
If your M2D or M2D-Sub loudspeaker is fitted with the  
VEAM multipin connector, see the Meyer Sound document  
VEAM Cable Wiring Reference (part number 06.033.113)  
for the wiring conventions and pin-outs for AC, audio, and  
RMS connections.  
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.  
Meyer Sound offers two VIMs (VEAM interface module)  
for simple, all-in-one RMS, audio and power distribution  
using VEAM multi-conductor cables. As shown in Figure  
1.5, the VIM-4 module consists of four VEAM connectors  
and 8-amp breakers for the M2D loudspeaker; the VIM-  
3 consists of three VEAM connectors and 10-amp  
breakers for the higher-current M2D-Sub loudspeaker.  
Both modules feature a single-phase IEC309 32-amp rear  
connector.  
Connect the green and yellow wire to the terminal  
marked with an E or colored green or green and yellow.  
The M2D and M2D-Sub loudspeakers use different  
amplifiers to accommodate power requirements for their  
drivers, hence they have different voltage and current  
requirements. The M2D uses a UX-M2D amplifier while the  
M2D-Sub uses an HP-2/M2D-Sub amplifier.  
4
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 1  
VOLTAGE AND CURRENT REQUIREMENTS  
M2D Voltage Requirements  
M2D Current Requirements  
Each M2D loudspeaker requires approximately 3 A rms max  
at 115 volts AC for proper operation. This allows up to five  
M2D loudspeaksers to be powered from one 15 A breaker.  
The M2D loudspeaker operates safely and without audio  
discontinuity if the AC voltage stays within the operating  
window of 90 to 265 volts AC, at 50 to 60 Hz.  
The M2D loudspeaker presents a dynamic load to the AC  
mains, which causes the amount of current to fluctuate  
between quiet and loud operating levels. Since different  
cables and circuit breakers heat up at varying rates, it is  
essential to understand the types of current ratings and how  
they correspond to circuit breaker and cable specifications.  
The M2D can withstand continuous voltages up to 265  
Volts and allows any combination of voltage to GND (that is  
neutral-line-ground or line-line-ground).  
The maximum long-term continuous current is the maximum  
rms current during a period of at least ten seconds. It is  
used to calculate the temperature increase in cables, in  
order to select a cable size and gauge that conforms to  
electrical code standards. It is also used to select the rating  
for slow-reacting thermal breakers.  
CAUTION: Continuous voltages higher than  
265 volts may damage your M2D.  
After applying AC power, the system is muted while the  
circuitry charges up and stabilizes. During the next two  
seconds the following events occur:  
The burst current is the maximum rms current during a  
period of approximately one second, used to select the  
rating for most magnetic breakers and to calculate the peak  
voltage drop in long AC cables according to the formula:  
1. The power supply fan turns on.  
2. The main power supply slowly ramps on.  
3. The green On/Temp LED on the User Panel lights up,  
indicating that the system is enabled and ready to pass  
audio signals.  
V pk (drop)= I pk x R (cable total).  
The ultimate short-term peak current is used to select the  
rating for fast-reacting magnetic breakers.  
CAUTION: If the On/Temp LED does not  
illuminate or the system does not respond  
to audio input after ten seconds, remove AC power  
immediately. Verify that the voltage is within the  
proper range. If the problem persists, please contact  
Meyer Sound or an authorized service center.  
Use Table 1.1 below as a guide when selecting cable gauge  
size and circuit breaker ratings for your operating voltage.  
Table 1.1: M2D Current Ratings  
Current Draw  
115 V AC  
230 V AC  
100 V AC  
Max. long-term 3.1 A rms  
continuous  
1.6 A rms  
3.6 A rms  
If voltage drops below the low boundary of its safe  
operating range (brownout), the M2D loudspeaker  
uses stored energy to continue functioning briefly, and  
shuts down only if voltage does not rise above the low  
boundary before storage circuits are depleted. How long  
the loudspeaker will continue to function during brownout  
depends on the amount of voltage drop and the audio  
source level during the drop.  
Burst current  
3.2 A rms  
1.6 A rms  
2.9 A pk  
3.7 A rms  
6.7 A pk  
Ultimate short- 5.8 A pk  
term peak  
Idle current  
0.35 A rms  
0.35 A rms  
0.35 A rms  
NOTE: For best performance, the AC cable  
voltage drop should not exceed 10 volts, or  
If the voltage increases above the upper boundary, the unit  
may be damaged.  
10 percent at 115 volts and 5 percent at 230 volts.  
Make sure that even with the AC voltage drop the  
AC voltage always stays in the operating windows.  
NOTE: It is recommended that the supply be  
operated in its rated voltage window at least  
The minimum electrical service amperage required by an  
M2D system is the sum of each loudspeaker’s maximum  
continuous rms current. An additional 30 percent above  
the minimum amperage is recommended to prevent peak  
voltage drops at the service entry.  
a few volts away from the turn on/off points. This  
ensures that AC voltage variations from the service  
entry, or peak voltage drops due to cable runs, do not  
cause the amplifier to cycle on and off. It also keeps  
high voltage from damaging the power supply.  
5
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 1  
If the M2D-Sub loudspeaker shuts down due to either low  
or high voltage, its power supply automatically turns on  
after three seconds if the voltage has returned to either  
normal operating window. If the M2D-Sub does not turn  
back on after ten seconds, remove AC power immediately  
(see previous Caution).  
M2D-Sub Voltage Requirements  
The M2D-Sub loudspeaker operates safely and without  
audio discontinuity if the AC voltage stays within either of  
two operating windows at 50 or 60 Hz:  
85 to 134 volts  
165 to 264 volts  
NOTE: It is recommended that the supply  
be operated in the rated voltage windows at  
least a few volts away from the turn on/off points.  
This ensures that that AC voltage variations from the  
service entry – or peak voltage drops due to cable  
runs – do not cause the amplifier to cycle on and off.  
CAUTION: Continuous voltages higher than  
264 volts can damage the unit.  
After applying AC power, the proper operating voltage is  
automatically selected, but the system is muted. During the  
next three seconds the following events occur:  
M2D-Sub Current Requirements  
1. The primary fan turns on.  
The M2D-Sub loudspeaker presents a dynamic load to the  
AC mains, which causes the amount of current to fluctuate  
between quiet and loud operating levels. Since different  
cables and circuit breakers heat up at varying rates, it is  
essential to understand the types of current ratings and how  
they correspond to circuit breaker and cable specifications.  
2. The main power supply slowly ramps on.  
3. The green Active LED on the User Panel lights up,  
indicating that the system is enabled and ready to pass  
audio signals.  
CAUTION: If the Active LED does not  
illuminate or the system does not respond  
to audio input after ten seconds, remove AC power  
immediately. Verify that the voltage is within the  
proper range. If the problem persists, please contact  
Meyer Sound or an authorized service center.  
The maximum long-term continuous current is the maximum  
rms current during a period of at least ten seconds. It is  
used to calculate the temperature increase in cables, in  
order to select a cable size and gauge that conforms to  
electrical code standards. It is also used to select the rating  
for slow-reacting thermal breakers.  
The burst current is the maximum rms current during a  
period of approximately one second, used to select the  
rating for most magnetic breakers and to calculate the peak  
voltage drop in long AC cables according to the formula:  
If voltage drops below the low boundary of either safe  
operating range (brownout), the M2D-Sub loudspeaker uses  
stored energy to continue functioning briefly, and shuts  
down only if voltage does not rise above the low boundary  
before the M2D-Sub loudspeaker’s storage circuits are  
depleted. How long the loudspeaker will continue to  
function during brownout depends on the amount of voltage  
drop and the audio source level during the drop.  
V pk (drop)= I pk x R (cable total).  
The ultimate short-term peak current is used to select the  
rating for fast-reacting magnetic breakers.  
Use Table 1.2 below as a guide when selecting cable gauge  
size and circuit breaker ratings for your operating voltage.  
If the voltage increases above the upper boundary of  
either range, the power supply rapidly turns off, preventing  
damage to the unit.  
Table 1.2. M2D-Sub Current Ratings  
Current Draw  
115 V AC  
230 V AC  
100 V AC  
Max. long-term 8.8 A rms  
continuous  
4.4 A rms  
10 A rms  
NOTE: If 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.  
Burst current  
19 A rms  
9.5 A rms  
20 A pk  
22 A rms  
45 A pk  
Ultimate short- 39 A pk  
term peak  
Idle current  
1.2 A rms  
0.6 A rms  
1.3 A rms  
6
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 1  
NOTE: For best performance, the AC cable  
voltage drop should not exceed 10 volts, or  
10 percent at 115 volts and 5 percent at 230 volts.  
Make sure that even with the AC voltage drop the  
AC voltage always stays in the operating windows.  
The minimum electrical service amperage required by  
the M2D-Sub system is the sum of each loudspeaker’s  
maximum continuous rms current. An additional 30 percent  
above the minimum amperage is recommended to prevent  
peak voltage drops at the service entry.  
CAUTION: In the unlikely event that the  
circuit breakers trip (the white center buttons  
pop out), disconnect the AC power cable. Do not  
reset the breakers with the AC connected. Contact  
Meyer Sound for repair information.  
CAUTION: The M2D and M2-Sub  
loudspeakers require a ground connection.  
Always use a grounded outlet and plug.  
7
Download from Www.Somanuals.com. All Manuals Search And Download.  
CHAPTER 1  
8
Download from Www.Somanuals.com. All Manuals Search And Download.  
CHAPTER 2  
CHAPTER 2: AMPLIFICATION AND AUDIO  
The M2D and M2D-Sub loudspeakers use sophisticated  
AUDIO INPUT  
amplification and protection circuitry to produce  
consistent and predictable results in any system design.  
This chapter will help you understand and harness the  
power of the M2D and M2D-Sub amplifier and audio  
systems.  
The M2D and M2D-Sub loudspeakers present a 10 kOhm  
balanced input impedance to a three-pin XLR connector  
with the following connectors:  
Pin 1 — 220 kOhm to chassis and earth ground (ESD  
clamped)  
The rear panels of the M2D and M2D-Sub loudspeakers  
(Figures 2.1 and 2.2) provide AC connection, audio input,  
loop out and an interface to the RMS communications  
module.  
Pin 2 — Signal ( + )  
Pin 3 — Signal ( - )  
Case — Earth (AC) ground and chassis  
Pins 2 and 3 carry the input as a differential signal; pin  
2 is hot relative to pin 3, resulting in a positive pressure  
wave when a positive signal is applied to pin 2. Pin 1 is  
connected to earth through a 220 kOhm, 1000 pF, 15 V  
clamp network. This ingenious circuit provides virtual  
ground lift for audio frequencies, while allowing unwanted  
signals to bleed to ground.  
 
��  
 
Use standard audio cables with XLR connectors for  
balanced signal sources. Make sure that pin 1 (shield) is  
always connected on both ends of the cable. Telescoping  
grounding schemes are not recommended.  
CAUTION: Ensure that all cabling carrying  
signals to M2D or M2D-Sub loudspeakers  
in an array is wired correctly: Pin 1 to Pin 1, Pin 2  
to Pin 2, and so forth, to prevent the polarity from  
being reversed. Any number of loudspeakers —  
even one in the array — with reversed polarity will  
result in severe degradation in frequency response  
and coverage.  
Figure 2.1. The user panel of the M2D loudspeaker  
Audio signals can be daisy-chained using the loop output  
connector on the user panel (Figure 2.3). A single source  
can drive multiple M2D or M2D-Sub loudspeakers with a  
paralleled input loop, creating an unbuffered hard-wired  
loop connection.  
WARNINGS:  
THIS PRODUCT MUST BE GROUNDED  
This surface may reach high tempuratures white in use.  
To ensure proper operation, allow at least  
6
inches  
clearance from this surface and adequate ventilation.  
To reduce the risk of electric shock do not remove cover.  
No operator or serviceable parts inside.  
Refer servicing to qualified personnel.  
To reduce the risk of fire or electric shock  
do not expose this appliance to rain or moisture.  
ATENCI”N: ACCESO INTERNO SOLO  
 
AUTHORIZADO  
A
PERSONAL T…CNICO CALIFICO  
ACHTUNG: GEHUSE NICHT OFFENE WARTUNG  
UND REPARATUR NUR DURCH ELEKTROFCHKRAFTE  
ATTENTION: ENTRETIENET REPARATIONS  
INTERNES NE SONT AUTORISEES QU'AU  
PERSONNEL TECHNIQUE QUALIFI…  
��  
U.K. WARNING: THIS APPARATUS MUST BE EARTHED.  
NO OPERATOR SERVICEABLE PARTS INSIDE.  
REFER SERVICING TO QUALIFIED PERSONNEL.  
Auto-Voltage Select  
95-125V  
50-60Hz  
~
208-235V~  
50-60Hz  
1400W RMS MAX 1400W RMS MAX  
Operational Voltage Range:  
Turn on 85V~ Turn off 134V~  
Turn on 165V~ Turn off 264V~  
Figure 2.3. M2D and M2D-Sub user panel audio input connectors  
Meyer Sound, Berkeley, CA USA  
Figure 2.2. The user panel of the M2D-Sub loudspeaker  
9
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 2  
When driving multiple loudspeakers in an array, make  
certain that the source device can drive the total load  
impedance presented by the paralleled input circuit of the  
array. The audio source must be capable of producing  
a minimum of 20 dB volts (10 volts rms into 600 ohms)  
in order to produce the maximum peak SPL over the  
operating bandwidth of the loudspeaker.  
one of the two drivers while correcting the phase shift at  
low frequencies for proper addition with the other driver.  
This technique eliminates interference between the high-  
frequency and low-frequency drivers that would otherwise  
occur near the crossover frequency, and maintains optimal  
polar and frequency response characteristics.  
To reproduce high frequencies, the M2D employs Meyer  
Sound's patented REM ribbon emulation manifold to  
couple a constant-directivity horn to a compression driver  
with a 1.5-inch exit (4-inch diaphragm). REM controls the  
output of the driver and introduces it to the horn throat  
within a three-inch path length, dramatically minimizing  
distortion. This unique horn design produces a coherent  
wave front that is characteristic of, but much more  
powerful than, a large ribbon driver.  
To avoid distortion from the source, make sure the source  
equipment provides an adequate drive circuit design  
for the total paralleled load impedance presented by  
the array. The input impedance for a single loudspeaker  
is 10 kOhms: if n represents the number of M2D/M2D-  
Sub loudspeakers in an array, paralleling the inputs of n  
loudspeakers will produce a balanced input load of 10  
kOhms divided by n.  
NOTE: Most source equipment is safe for  
driving loads no smaller than 10 times the  
source’s output impedance.  
CAUTION: All Meyer Sound loudspeakers  
are shipped with the drivers in correct  
alignment. However, if a driver needs to be  
replaced, make sure the replacement is reinstalled  
with the correct polarity. Incorrect driver polarity  
impairs the system performance and may damage  
the drivers.  
For example, cascading an array of 10 units consisting of  
M2D and/or M2D-Sub loudspeakers produces an input  
impedance of 1000 ohms (10 kOhms divided by 10). The  
source equipment should have an output impedance of  
100 ohms or less. This is also true when connecting M2D/  
M2D-Subs in parallel (loop out) with other self-powered  
Meyer Sound loudspeakers.  
M2D AMPLIFICATION  
All three drivers in the M2D are powered by a two-channel  
proprietary Meyer Sound UX-M2D amplifier utilizing  
complementary MOSFET output stages (class AB/bridged)  
capable of delivering 700 watts total. The amplifier  
employs electronic crossover, phase, and frequency  
response correction filters – as well as protection circuitry  
– to process the audio signal. All the specific functions  
for the M2D are determined by the control card installed  
inside the amplifier; one channel of the amplifier drives the  
low and low-mid section of the M2D through the passive  
network while the other channel drives the high frequency  
section.  
CAUTION: Shorting an input connector pin  
to the case can form a ground loop and  
cause hum.  
TIP: If abnormal noises such as hiss and  
popping are produced by the loudspeaker,  
disconnect the audio cable from the loudspeaker.  
If the noise stops, then most likely the problem  
is not with the loudspeaker. Check the audio  
cable, source, and AC power for the source of the  
problem.  
M2D LIMITING  
Each channel of the amplifier has limiters that prevent  
driver over-excursion and regulate the temperature of the  
voice coil. Limiter activity for the high and low channels is  
indicated by two yellow Limit LEDs on the rear panel (the  
high-frequency limit LED is the top and the low-frequency  
limit LED is the bottom, as shown in Figure 2.4).  
M2D INTERCONNECTIONS  
For the low and low-mid frequencies, the M2D utilizes  
two 4-ohm, 10-inch cone drivers featuring lightweight  
neodymium magnet structures.  
A complex passive network connected between the  
amplifier and the drivers is used to ensure smooth  
response in the critical midrange. At the lowest  
frequencies, the two high-power, back-vented cone  
drivers combine to reproduce coherent low frequencies.  
In the mid frequencies, the passive network feeds only  
10  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 2  
Optional Fan Assembly Kit  
high-frequency  
LED (yellow)  
While convection cooling is adequate for most  
applications, in situations where the M2D loudspeaker is  
driven into continuous limiting under severe temperature  
conditions, or where ventilation is restricted, installation  
of an optional fan kit is recommended to maintain a safe  
operating temperature.  
low-frequency  
LED (yellow)  
Figure 2.4. The M2D loudspeaker’s limit LED indicators  
The easy-to-install fan, powered through the 24 V fan  
connector on the M2D loudspeaker’s user panel, blows  
air directly onto the heatsink. The fan speed increases as  
the heatsink temperature rises, which maintains a safe  
operating temperature with minimal fan noise. Contact  
Meyer Sound to order the fan kit.  
If the limit LEDs are on for no longer than two seconds,  
and off for at least one second, the M2D loudspeaker  
is performing within its acoustical specifications and  
operating at a normal temperature. If either LED remains  
on for longer than three seconds, this indicates that the  
particular channel is incurring hard limiting that can result  
in the following negative consequences:  
Increasing the input level will not increase the volume.  
The system distorts due to clipping and nonlinear  
driver operation.  
Unequal limiting between the low and high frequency  
drivers can alter the frequency response.  
The lifespan of the drivers is reduced because they are  
subjected to excessive heat.  
While the limiters protect the system under overload  
conditions and exhibit smooth sonic characteristics, it  
is recommended that you do not drive the M2D into  
continuous limiting.  
Power Supply Fan  
The power supply is cooled by a single small internal fan  
operates on low speed when the unit is first powered  
up. The fan increases speed as the system is driven  
with audio. Since the fan draws air in from and exhausts  
through the back of the cabinet, there must be at least  
6 inches of clearance behind the cabinet to allow an  
adequate air flow.  
NOTE: The limit LEDs indicate when the  
safe power level is exceeded. If an entire  
system of M2Ds begins to limit before reaching the  
required SPL, you should consider adding more  
loudspeakers to the array.  
The limiters cease operation when the level in the channel  
returns to normal. Limiters have no effect on the signal  
when the LED is inactive.  
M2D-SUB INTERCONNECTIONS  
The M2D-Sub loudspeaker utilizes two 4-ohm, 15-inch  
cone drivers. These drivers feature lightweight neodymium  
magnet structures. Each channel of the amplifier drives  
one low frequency driver.  
M2D AMPLIFIER COOLING SYSTEM  
The M2D loudspeaker employs a natural convection  
cooling system. A large aluminum heatsink is cooled by  
the air flowing over its fins.  
CAUTION: All Meyer Sound loudspeakers  
are shipped with the drivers in correct  
alignment. However, if a driver needs to be  
replaced, make sure the replacement is reinstalled  
with the correct polarity. Incorrect driver polarity  
impairs the system performance and may damage  
the drivers.  
If the temperature of the heatsink reaches 85°C (185°F),  
the On/Temp LED on the rear panel turns from green (On)  
to red (Temp) and the limiter threshold is lowered to a  
safe level to prevent the system from overheating. Under  
high temperature conditions the maximum output level is  
reduced 6 dB. When the heatsink temperature decreases  
to 75°C (167°F), the On/Temp LED changes from red to  
green and the limiter threshold returns to normal.  
11  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 2  
then go off for at least one second. If the LED remains  
on for longer than three seconds, this indicates that the  
amplifier is incurring hard limiting that can result in the  
following negative consequences:  
M2D-SUB AMPLIFICATION  
The M2D-Sub loudspeaker is powered by the Meyer  
Sound HP-2/M2D-Sub amplifier, a high-power two-  
channel amplifier. The amplifier utilizes complementary  
MOSFET output stages (class AB/H) capable of delivering  
2250 watts total. All the specific functions for the M2D-  
Sub loudspeaker such as crossover points, frequency and  
phase response, and driver protection are determined by  
the control card installed inside the amplifier.  
Increasing the input level will not increase the volume.  
The system distorts due to clipping and nonlinear  
driver operation.  
The lifespan of the drivers is reduced because they are  
subjected to excessive heat  
Each low-frequency driver is driven by a separate amplifier  
channel but is routed to one limiter; the Sub Limit LED on  
the user panel indicates TruPower limiting activity for the  
drivers. The Sub Limit LED indicates when the safe power  
level is exceeded (Figure 2.5).  
M2D-SUB LIMITING  
The M2D-Sub loudspeaker uses Meyer Sound’s advanced  
TruPower limiting system.  
Conventional limiters assume a constant loudspeaker  
impedance and therefore set the limiting threshold  
by measuring voltage only. However, this method is  
inaccurate, because the driver's impedance changes in  
response to the frequency content of the source material  
and thermal variations in the driver's voice coil and  
magnet. Consequently, conventional limiters begin limiting  
prematurely, which under-utilizes system headroom and  
lessens the driver's dynamic range.  
CAUTION: While the limiters protect  
the system under overload conditions  
and exhibit smooth sonic characteristics; we  
recommend that you do not drive the M2D-Sub  
loudspeaker into continuous limiting. If an entire  
system of M2D-Sub loudspeakers begins to limit  
before reaching the required sound pressure  
level, you should consider adding more M2D-Sub  
loudspeakers to the system.  
In contrast, TruPower limiting accounts for varying driver  
impedance by measuring current, in addition to voltage,  
to compute the actual power dissipation in the voice coil.  
TruPower limiting improves performance before and during  
limiting by allowing each driver to produce maximum SPL  
across its entire frequency range. In addition, TruPower  
limiting eliminates power compression when the system  
is operated at high levels for extended periods, and also  
extends the driver life cycle by controlling voice coil  
temperatures.  
M2D-Sub Excursion Clamp  
The drivers in the M2D-Sub are protected by an excursion  
clamping circuit that provides instantaneous braking  
for the drivers without the pumping effects commonly  
produced by compressor/limiters.  
The circuit uses sophisticated filters to minimize the  
distortion normally caused by clamping and clipping. As  
the M2D-Sub’s input signal is increased past the clamping  
point at each frequency, the output signal remains at a  
fixed level for that frequency, protecting the drivers and  
minimizing negative sonic effects. The Exc.Clamp LED,  
shown in Figure 2.5, illuminates when the maximum  
allowed peak voltage at each frequency is reached.  
This circuit works for all frequencies, not just very low  
frequencies where the drivers are more vulnerable to  
overexcursion.  
The actual power is monitored for each of the two  
amplifier channels. When the safe continuous power  
level is exceeded in any channel, the TruPower limiter  
controlling both amplifier channels engages. Limiting  
activity is indicated by the Sub Limit LED on the user  
panel (Figure 2.5).  
The limiters cease operation when the power level in the  
channel returns to normal. Limiters have no effect on the  
signal when the LED is inactive  
Figure 2.5. The M2D-Sub’s LED indicators  
The M2D-Sub loudspeaker performs within its acoustical  
specifications and operates at a normal temperature if the  
Sub Limit LED is lit for no longer than two seconds, and  
12  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 2  
The variable-speed primary fan runs continuously and is  
M2D-SUB AMPLIFIER COOLING SYSTEM  
inaudible at its slowest speed. The primary fan's speed  
increases when the heatsink reaches 42˚ C (108° F). The  
fan reaches full speed at 62˚ C (144° F) and is still barely  
audible near the cabinet, even without an audio signal.  
In the event that the heatsink temperature reaches 74˚ C  
(165° F), the secondary fan turns on and is clearly audible  
without an audio signal. The secondary fan turns on in  
response to:  
The M2D-Sub loudspeaker uses a forced-air cooling  
system with two fans to prevent the amplifier module  
from overheating. The fans draw air in through ducts  
on the front of the cabinet, over the heatsink, and out  
the rear of the cabinet (Figure 2.6). Because dust does  
not accumulate in the amplifier circuitry, its lifespan is  
increased significantly. The front grille helps to filter the air  
and should always be in place during operation.  
Primary fan failure (check status immediately)  
Very high signal levels over a prolonged period  
Accumulation of dust along the cooling path  
The secondary fan turns off when the temperature  
decreases to 68˚ C (154° F).  
NOTE: In the highly unlikely event that  
the secondary fan does not keep the  
temperature below 85˚ C (185° F), the M2D-  
Sub automatically shuts down until AC power is  
removed and reapplied. If the M2D-Sub shuts  
down again after cooling and reapplying AC power,  
contact Meyer Sound for repair information.  
Figure 2.6. Airflow through the M2D-Sub  
Despite the M2D-Sub loudspeaker's filtering, extensive  
use or a dusty operating environment can allow dust  
to accumulate along the path of the airflow, preventing  
normal cooling. To prevent this, you should periodically  
remove the grille frame and amplifier module and use  
compressed air to clear dust from the grille, fans, and  
heatsinks. Make sure that the air ducts are clear.  
CAUTION: When operating a weather-  
protected M2D-Sub loudspeaker always  
be sure the rain hood is fully open. Leaving the  
hood closed or partially open will limit the airflow  
through the amplifier, which could cause it to  
overheat and shut down.  
CAUTION: Be sure to unplug power to the  
unit before cleaning the amplifier.  
13  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 2  
14  
Download from Www.Somanuals.com. All Manuals Search And Download.  
CHAPTER 3  
CHAPTER 3: RMS REMOTE MONITORING SYSTEM  
The M2D and M2D-Sub loudspeakers are fitted standard  
with an RMS communication module installed in the rear of  
the loudspeaker. The RMS real-time networked monitoring  
system connects Meyer Sound self-powered loudspeakers  
with a Windows-based PC at the sound mix position or  
other remote location. Optional RMS software delivers  
extensive status and system performance data directly to  
you from every installed loudspeaker.  
This information is permanently retained on each RMS  
communication module and in the RMS database un-  
less you modify it. Speaker Titles can be modified at any  
time, allowing you to customize how you view the data.  
In addition, any M2D or M2D-Sub loudspeaker can be  
physically identified from RMS software by activating  
the Wink function – a Wink LED will illuminate the RMS  
communication module that corresponds to its Node Name.  
RMS allows you to monitor amplifier voltages, limiting  
activity, power output, temperature, fan and driver status,  
warning alerts, and other key data; data is updated two to  
five times per second.  
M2D and M2D-Sub loudspeakers are identified using the  
RMS software by activating the “service” function; an icon  
will show up on the RMS screen corresponding to its Node  
Name (Figure 3.2). This makes verifying Speaker Titles and  
speaker field labels easy, using the Wink or Service Button  
commands.  
NOTE: Optional Speaker Mute and Solo  
functions, helpful for acoustic setup or  
troubleshooting, are also available. An internal  
jumper must be installed in the RMS communication  
module in order to enable Mute and/or Solo  
functionality; the software also needs to be enabled  
for these functions.  
The M2D and M2D-Sub loudspeakers are shipped  
with these functions disabled. Once enabled,  
the jumper(s) can still be removed to eliminate  
any chance of an operator error (a muting error,  
for example) during a performance, and both  
functions can be controlled by software commands  
in any case. Also note that RMS does not control  
loudspeaker volume or AC power.  
Figure 3.2. RMS loudspeaker icons  
UNDERSTANDING THE RMS USER PANEL  
The RMS section of the user panel has three LEDs and two  
buttons (Figure 3.3).  
Loudspeakers are identified on the network by Node Names  
assigned during a one-time “commission” (Figure 3.1) into  
the RMS database that resides on your computer (as a part  
of the software).  
Figure 3.3. RMS section of the user panel  
The following sections describe their functions.  
Service LED (Red)  
When blinking once every two seconds, the Service LED  
indicates that the network hardware is operational, but the  
loudspeaker is not installed (commissioned) on the network.  
When a loudspeaker has been installed on the network  
the Service LED will be unlit and the Activity LED will flash  
continuously.  
NOTE: When continuously lit, the Service  
LED indicates that the loudspeaker has had  
Figure 3.1. Commissioning a loudspeaker using RMS  
a local RMS hardware failure. In this case, the RMS  
communication module may be damaged and you  
should contact Meyer Sound Technical support.  
15  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 3  
Service Button  
USER INTERFACE  
Pressing the Service button will display an icon on the  
corresponding loudspeaker display icon on the RMS  
screen. When used in combination with the Reset button,  
the communications module will be decommissioned from  
the network and the red Service LED will blink.  
The optional RMS software features an intuitive, graphical  
user interface. As mentioned earlier, each loudspeaker  
appears on your computer monitor as a “view” in the form  
of a status icon, bar graph meter, or text meter (numerical  
values), depending on your preferences.  
Each view contains loudspeaker identification information  
and data from the amplifier, controller, drivers and power  
supply of that particular unit. System status conditions  
cause changes in icon and bar graph indicators, alerting  
the operator to faults or excessive levels. The views are  
moveable and are typically arranged on the screen to reflect  
the physical layout of the loudspeakers. You can design a  
screen “panel” of icons or meters, as shown in Figure 3.4,  
and save it on your hard disk, with the panel conveniently  
named for a unique arrangement or performer.  
Wink LED (green)  
When lit, the Wink LED indicates that an ID signal  
has been sent from the host station computer to the  
loudspeaker. This is accomplished using the Wink button  
on the loudspeaker Icon, Meter or Text views in the RMS  
monitoring program.  
Reset Button  
If the loudspeaker installation pattern changes completely,  
a new screen panel can be built. If a different subset of  
already installed loudspeakers will be used for a subsequent  
show, only selected loudspeakers need to appear on the  
monitoring screen for that performance.  
Pressing the Reset button will cause the firmware code  
within the RMS card to reboot. However, the commissioning  
state of the communications module will not change (this  
is stored in flash memory). When used in combination with  
the Service button, the communications module will be  
decommissioned from the network and the red  
Service LED will blink.  
Acivity LED (Green)  
When the loudspeaker has been commissioned  
the Activity LED will flash continuously. When  
the Activity LED is unlit the loudspeaker has not  
been installed on the network.  
NOTE: The LEDs and buttons on  
the RMS section of the user panel  
shown in Figure 3.3 are used exclusively by  
RMS, and have no effect on the acoustical  
and/or electrical activity of the M2D/M2D-  
Sub loudspeaker itself – unless Mute or Solo  
is enabled at the module and from the RMS  
software.  
Figure 3.4. Sample RMS display panel  
NOTE: For more information on RMS, please  
refer to the RMS User Guide included with  
the software.  
16  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
CHAPTER 4: LINE ARRAYS AND SYSTEM INTEGRATION  
A line array, in the most basic sense, is a group of closely  
spaced loudspeakers arrayed in a straight line, operating  
with equal amplitude and in phase. Although line arrays  
have been used since the 1950s, line array systems that  
provide full bandwidth directivity are relatively new to the  
sound reinforcement industry.  
M2D loudspeaker’s REM technology provides very narrow  
coverage in order to:  
Minimize destructive interference between adjacent  
elements  
Maximize coupling to throw longer distances  
As more and more elements are arrayed in a vertical  
column, they throw mid- and high-frequency energy more  
effectively through coupling. The amount of energy can then  
be controlled using the relative splay between the elements.  
Gently curving a line array (no more than 7 degrees of  
splay between cabinets) can aid in covering a broader  
vertical area, while narrow angles provide a longer throw  
and coverage that more closely matches that of the low  
frequencies.  
HOW LINE ARRAYS WORK  
Line arrays achieve directivity through constructive and  
destructive interference. For example, consider one  
loudspeaker with a single 12-inch cone radiator in an  
enclosure. We know from experience that this loudspeaker’s  
directivity varies with frequency: at low frequencies it is  
omnidirectional; as the frequency increases (wavelength  
grows shorter), directivity narrows. Above about 2 kHz, it  
becomes too beamy for most applications, which is why  
practical system designs employ crossovers and multiple  
elements to achieve directivity across the audio band.  
NOTE: Radically curving a line array  
introduces problems. While a drastic angle  
can spread high frequencies over a larger area, low  
frequencies remain directional (the curvature change  
is trivial at long wavelengths), resulting in uneven  
coverage. In addition, a vertically narrow high-  
frequency pattern combined with large angles can  
produce hot spots and areas of poor high-frequency  
coverage.  
Stacking two of these loudspeakers one atop the other  
and driving both with the same signal results in a different  
radiation pattern. At common points on-axis, there is  
constructive interference, and sound pressure increases by  
6 dB relative to a single unit. At other points off-axis, path  
length differences produce cancellation, resulting in a lower  
sound pressure level. In fact, if you drive both units with  
a sine wave, there will be points where the cancellation is  
complete, which can be shown in an anechoic chamber.  
This is destructive interference, sometimes referred to as  
combing.  
Mid to Low Frequencies  
For the mid to low frequencies, array elements must be  
coupled together to narrow their vertical coverage and  
throw mid and low energy to the far field. As frequencies get  
lower and wavelengths get longer, the splay angle between  
cabinets has little effect. The number of array elements,  
however, is important: the more M2D loudspeakers used,  
the narrower the vertical beamwidth becomes.  
A typical line array comprises a line of loudspeakers  
carefully spaced so that constructive interference occurs  
on-axis of the array, and destructive interference (combing)  
is aimed to the sides. While combing has traditionally been  
considered undesirable, line arrays use combing to positive  
effect: Without combing, there would be no directivity.  
Adjusting Line Array Coverage  
THE M2D LINE ARRAY  
Regardless of the needs of your system design, fine-tuning  
coverage for a single M2D array will be dependent on three  
factors:  
The M2D loudspeaker employs a unique combination  
of drivers to enable you to optimize both coverage and  
directivity in an M2D system. To achieve optimal results, it’s  
critical to understand how these components work together.  
Number of Array Elements. Determining the number  
of elements to use is critical: Too few elements can  
drastically affect the uniformity of coverage of both SPL  
and frequency.  
High Frequencies  
Vertical Splay Angles. Changing the splay angles  
between array elements has a significant impact on  
vertical coverage, with the result that narrower vertical  
splay angles produce a higher Q vertical beamwidth,  
while wider splay lowers the Q at high frequencies.  
For high frequencies, the M2D loudspeaker provides a  
consistent beamwidth of coverage in both the vertical and  
horizontal planes. In the horizontal pattern of the array, the  
M2D loudspeaker’s horn works just as any wave guide does  
to produce wide coverage; in the vertical, however, the  
17  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
Horizontal Coverage. Horizontal coverage for a single  
array can be considered constant regardless of the  
number of array elements or the angles between them.  
Electronically Driving the Array  
Once the design (number of elements, vertical splay angles  
and horizontal splay angles between arrays) has been  
determined, you can effectively optimize the array by driving  
it with multiple equalization channels, or zones. Typically  
arrays are divided in two or three zones depending on  
the design and size of the array; to optimize EQ, different  
strategies are used for the low and high frequencies for long  
throws and short throws.  
TIP: The angle between two or more  
line arrays can also be changed to meet  
additional design requirements (for example, wall  
reflections).  
Given these factors, designing and deploying a line array  
system will typically have the following objectives:  
High-Frequency Equalization Strategies  
For the far field, air absorption plays a critical role. The  
farther the distance, the greater the attenuation at high  
frequencies. In this zone, very high frequencies generally  
need a boost to compensate for energy lost over distance;  
the gain needed is usually proportional to the distance and  
high-frequency air absorption.  
Even horizontal and vertical coverage  
Uniform SPL  
Uniform frequency response  
Sufficient SPL for the application  
In the near- to mid-field, the air absorption is not nearly  
as critical; in this zone, high frequencies need little or no  
additional gain.  
With two different technologies (low-frequency line array  
and high-frequency wave guide) built into each M2D  
cabinet, achieving these goals becomes a multi-step  
process, with different strategies for the lower and higher  
frequencies for long throws and short throws.  
TIP: If your M2D array uses a third zone for  
short throws, high frequencies there may  
need to be attenuated to avoid excess levels in the  
near field.  
NOTE: THE Meyer Sound MAPP Online  
prediction program, covered in greater detail  
later in Chapter 5, “System Design and Integration  
Tools,” enables you to make accurate and  
comprehensive predictions for optimal coverage(s)  
during the design phase.  
Low-Frequency Strategies  
Although the array can (and usually should) be zoned  
for implementing different equalization curves for high  
frequencies, similar or identical equalization should be  
maintained in all the low-frequency filters. Different low-  
frequency equalization settings in the same array will  
degrade the desired coupling effect.  
High-Frequency Design Strategies  
Planning for high-frequency coverage is a matter of fine-  
tuning the splay angles between cabinets while keeping  
an eye on the number of far-throwing elements in the  
array. The number of elements does not necessarily have a  
significant impact on SPL at high frequencies (it will at low  
frequencies), but can profoundly affect throw.  
For the same reason, gain tapering is not recommended  
for line arrays, since adjusting various zones with an overall  
amplitude control for each zone results in the following:  
1. Directionality decreases.  
For the far field, a smaller mechanical splay angle achieves  
superior throw through better coupling to compensate for  
energy lost over distance. In the near- to mid-field, larger  
splay angles increase vertical coverage.  
2. Low-frequency headroom decreases.  
3. The length of the line array column is effectively  
shortened.  
Low-Frequency Design Strategies  
TIP: The LD-3 compensating line driver was  
designed to implement both low- and high-  
frequency strategies with its array and atmospheric  
correction functions. The LD-3 line driver’s array  
correction function compensates for low-frequency  
build-up, while the atmospheric controls correct for  
the attenuation of sound in air at high-frequencies.  
For more information on the LD-3 line driver’s  
atmospheric and array correction features, please  
refer to the LD-3 datasheet, operating instructions  
While the wave guide provides isolated control over various  
mid to high-frequency coverage areas, the low-frequency  
section of an M2D line array still requires mutual coupling  
— with equal amplitude and phase — to achieve better  
directionality.  
Low frequency directionality is less dependant on the array’s  
relative splay angles and more dependent on the number of  
elements of the array. At low frequencies, the more elements  
in the array, the more directional the array becomes.  
18  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
Figures 4.1 shows a series of MAPP Online predictions  
based on an example M2D system design. In this case,  
small vertical splay angles on the upper part of the array  
are used to cover longer distances, while greater angles are  
used in the lower elements to increase vertical coverage for  
shorter distances.  
The block diagram (Figure 4.2) shows one method of driving  
this example array, along with additional fill loudspeakers  
and subwoofers (not in the MAPP Online predictions).  
Equalizers for each zone, as well as digital delays, provide a  
time adjustment to compensate for the various sub-systems  
if they are geometrically out of plane.  
CAUTION: This example is not meant to  
be used as a template for your own system  
designs. Acoustical characteristics, physical  
constraints, audio content, audience, and a slew of  
other factors should always be uniquely weighed  
into your own applications on a per-project basis.  
USING THE M2D-SUB WITH THE M2D  
The M2D provides full bandwidth frequency response down  
to 60 Hz, however, if the application or the program content  
requires additional low-frequency energy (e.g., clubs,  
discos, reinforcement of popular music), the M2D-Sub is  
naturally the best way to augment your M2D system. The  
M2D-Sub can achieve frequency response down to 30 Hz,  
extending system response appreciably and increasing the  
acoustic power of a system in the lowest frequencies.  
Figure 4.1: Using vertical splay to adjust a line array’s coverage  
LD-3  
Channel A  
Main  
IN  
SUB OUT  
CH 1 OUT  
CH 2 OUT  
CH 3 OUT  
Left  
Channel B  
Right  
IN  
SUB OUT  
CH 1 OUT  
CH 2 OUT  
CH 3 OUT  
Optional  
Subwoofer  
Mono  
Channel A  
INSERTS  
IN SUB  
SENDS  
OUT  
Full Range  
IN CH 1  
IN CH 2  
IN CH 3  
OUT  
Post Array  
OUT  
Post Array  
Post HPF  
Channel B  
INSERTS  
IN SUB  
SENDS  
OUT  
Full Range  
IN CH 1  
IN CH 2  
IN CH 3  
OUT  
Post Array  
OUT  
Post Array  
Post HPF  
Digital Delay  
Digital Delay/EQ  
2 In x 6 Out  
Figure 4.2: Sample block diagram of M2D/M2D-Sub array  
19  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
In addition, the use of high-pass filters to drive an M2D  
system with the M2D-Sub flattens overall frequency  
response and slightly increases M2D headroom in the  
lowest end of its usable spectrum.  
acoustical conditions. If the gains are adjusted to the same  
level, the combined response is identical to a daisy-chain  
configuration with a rise in level on the overlapping range.  
Meyer Sound makes available three different line drivers.  
Engaging the Lo-Cut Filter  
The ideal ratio of M2D to M2D-Sub loudspeakers depends  
on the configuration of the system, the application, and the  
frequency content of the signal being reproduced. For most  
applications, two M2Ds for each M2D-Sub yields good  
results in frequency response and headroom.  
Using the LD-1A, LD-2 or LD-3 Lo-Cut filter (the 160 Hz  
HPF position on the LD-3) can produce an M2D/M2D-  
Sub system (in close proximity and co-planar) with very  
flat frequency response and a minimal area of overlap.  
The M2D loudspeakers in the system receive their signal  
following a high-pass filter, while the M2D-Subs apply their  
normal internal crossover frequencies to a full range signal.  
NOTE: The M2D-Sub limit LEDs indicate  
when its safe power level is exceeded. If  
the M2D-Sub loudspeakers used in a system begin  
to limit before reaching the required SPL at low  
frequencies, you may need to add more M2D-Subs  
to satisfy the SPL requirements without exposing  
the drivers to excessive heat and/or excursion.  
NOTE: When driving M2Ds from the Mid-  
Hi output of the LD-1A, LD-2 or LD-3 line  
driver with the Lo-Cut filter engaged and M2D-Sub  
loudspeakers in their full-range configuration, their  
polarities should be kept the opposite if they are  
co-planar or near each other. This can be achieved  
by engaging the polarity reverse switch on the  
subwoofer output of the line driver. If your M2D and  
M2D-Sub loudspeakers are separated by a greater  
distance – or delay must be used between them  
– a measurement system such as the SIM audio  
analyzer should be used to determine the correct  
delay and polarity.  
The M2D and M2D-Sub loudspeakers can accommodate  
three basic connection options.  
Daisy-Chained  
When M2Ds and M2D-Subs are daisy-chained using the  
loop feature on the user panel, the result will have a fairly  
flat frequency response. However, at a ratio of two M2D to  
each M2D-Sub loudspeaker, the response will have a rise in  
the 70 to 160 Hz range where the frequency of the M2D and  
M2D-Sub overlap.  
TIP: How flat the response will be is, in any  
case, dependent on proximity to boundary  
surfaces.  
CAUTION: Always ensure that the source  
equipment can drive the total load of the  
paralleled system.  
While the change of polarity with respect to a daisy-chained  
configuration is needed due to the phase shift caused by  
the high-pass filter at overlapping frequencies, placing  
M2D-Sub loudspeakers more than 4 feet apart from M2D  
loudspeakers may require reversing the polarities once  
again to compensate for the delay propagation.  
NOTE: When both and M2D and M2D-Sub  
loudspeakers are used in their full-range  
configuration (e.g., looped audio or the same audio  
feed), their polarities should be kept the same if  
they are co-planar or near each other. If they are  
separated by a greater distance – or delay must  
be used between them – a measurement system  
such as the SIM audio analyzer should be used to  
determine the correct delay and polarity.  
Table 4.1: M2D and M2D-Sub frequency response results with LD-  
1A, LD-2 and LD-3 (160 Hz filter)  
Lo-Cut  
ø Reverse  
Switch  
Result  
Off  
Off  
Flat response (small rise on 70 Hz -160  
Hz area)  
Engaged  
Engaged  
Very flat response  
Adding a Line Driver  
Driving an M2D/M2D-Sub system with the same signal from  
different outputs using a line driver allows adjustments to  
the gain and polarity of each sub-system, and could be used  
effectively to compensate for the ratio of loudspeakers or  
20  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
Table 4.3: LD-1A, LD-2 and LD-3 (LD-3 at 160 Hz) “Lo-Cut Filter”  
Parameters  
Using the LD-3  
In addition to the 160 Hz high-pass filter on the LD-3, the  
LD-3 compensating line driver provides additional filtering  
capabilities to help you further fine-tune an M2D/M2D-Sub  
system.  
Type  
Order  
Pole  
Frequency  
Q
High Pass  
2nd (-12 dB/oct) 162 Hz  
0.82*  
* If the DSP does not have variable Q for high-pass filters, the filter  
should be set to “Butterworth” (Q .7).  
Table 4.2: M2D and M2D-Sub frequency response results with  
different filter configurations  
If the loudspeakers are going to be driven directly from  
DSP, verify that the outputs of the processor have the  
driving capabilities to drive the total load presented by the  
loudspeakers connected to it.  
HPF  
Off  
80  
LPF  
ø Reverse  
Switch  
Result  
Off  
Off  
Flat response (small rise on 70 Hz  
-160 Hz area)  
Off  
Off  
Very flat response, +3 dB sub gain  
recommended  
NOTE: When precise array design,  
subwoofer integration, DSP and delay  
systems, and compensation for acoustical  
conditions all come into play, measurement and  
correction tools are a must. Meyer’s SIM audio  
analyzer and the CP-10 parametric equalizer are  
both highly recommended.  
80  
80  
Engaged  
Engaged  
Very flat response, +3 dB sub gain  
recommended  
160  
OFF  
Very flat response  
NOTE: For more information on the LD-3 line  
driver’s atmospheric and array correction  
features, please refer to the LD-3 Operating  
USING THE 650-P WITH THE M2D  
In some applications – for instance, in a system design  
where the subwoofers do not need to be flown in the array –  
it may be desirable to deploy an M2D array in combination  
with Meyer Sound’s 650-P high-power subwoofer. The  
650-P subwoofer extends the M2D system frequency  
response down to 28 Hz, and can accommodate daisy-  
chain, line driver, and DSP connection options.  
Digital Signal Processors  
Full-range signals may be applied to Meyer Sound’s self-  
powered loudspeakers because they have built-in active  
crossover circuits; external crossovers and digital signal  
processors (DSP) are optional and should be used very  
carefully due to phase shifts that can cause cancellations.  
NOTE: The 650-P subwoofer does have a  
polarity switch, and you will need to ensure  
that it is set to pin 2 + (same polarity respect to the  
M2D loudspeaker’s pin 2 +) when co-planar and in  
close-proximity to and M2D array.  
If a DSP is used, both M2D and M2D-Sub loudspeakers  
should be fed from the DSP in order to keep their delay  
time the same. Otherwise you may experience phase  
shift differences between the M2Ds and the M2D-Subs.  
In addition, you should verify the delay time between  
channels: Some DSPs may develop channel-to-channel  
delay errors when the DSP is near maximum throughput,  
which becomes more likely as the number of filters the DSP  
is using increases.  
NOTE: When driving M2Ds from the Mid-  
Hi output of the LD-1A, LD-2 or LD-3 line  
driver with the Lo-Cut filter engaged and 650-P  
subwoofer in their full-range configuration, their  
polarities should be kept the opposite if they are  
co-planar or near each other. If your M2D and  
650-P loudspeakers are separated by a greater  
distance – or delay must be used between them – a  
measurement system such as SIM should be used  
to determine the correct delay and polarity.  
In no case should a filter higher than 2nd-order be used.  
The additional phase shift introduced by steep sloped  
filters deteriorates the impulse response and higher roll-off  
does not improve crossover interaction. In fact, it is highly  
recommended that the crossover/filter are set to emulate  
the low-cut LD-1A, LD-2 and LD-3 (at the 160 Hz position)  
characteristics themselves, as shown in Table 4.3.  
21  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 4  
Table 4.4: M2D and 650-P (650-P set to pin 2 positive) frequency  
response results with LD-1A, LD-2 and LD-3 (160 Hz filter)  
Lo-Cut  
ø Reverse  
Switch  
Result  
Off  
Off  
Flat response (small rise on 70 Hz -160  
Hz area), -6 dB sub gain recommended*  
Engaged  
Engaged  
Very flat response, -6 dB sub gain  
recommended*  
* The 650-P subwoofer is +6 dB more sensitive than the M2D and  
M2D-Sub loudpspeakers.  
In addition to its 160 Hz high-pass filter, the LD-3 line driver  
provides additional filtering capabilities (Table 4.5) to help  
you further fine-tune an M2D and 650-P system.  
Table 4.5: M2D and 650-P (650-P set to pin 2 positive) frequency  
response results with the LD-3 (using other filters)  
HPF  
LPF  
ø Reverse  
Switch  
Result  
Off  
55  
Off  
Flat response, -6 dB sub gain  
recommended*  
80  
80  
Engaged  
Engaged  
Very flat response, -6 dB sub gain  
recommended*  
160  
OFF  
Very flat response, -6 dB sub gain  
recommended*  
* The 650-P subwoofer is +6 dB more sensitive than the M2D and  
M2D-Sub loudpspeakers.  
22  
Download from Www.Somanuals.com. All Manuals Search And Download.  
CHAPTER 5  
CHAPTER 5: SYSTEM DESIGN AND INTEGRATION TOOLS  
Meyer Sound offers two comprehensive tools to assist you  
with the acoustical and functional requirements of system  
design and optimization. This chapter introduces you to the  
Meyer Sound MAPP Online acoustical prediction program,  
and the SIM audio analyzer, a robust instrumentation  
package for system measurement, analysis, and more.  
As its name indicates, the MAPP Online predition program  
is an online application: When a prediction is requested,  
data is sent over the Internet to a high-powered server at  
Meyer Sound that runs a sophisticated acoustical prediction  
algorithm using high-resolution, complex (magnitude and  
phase) polar data. Predicted responses are returned over  
the Internet and displayed on your computer in color.  
MEYER SOUND MAPP ONLINE  
With the MAPP Online prediction program, you can:  
The MAPP Online prediction program is a powerful, cross-  
platform, Java-based application for accurately predicting  
the coverage pattern, frequency response, impulse  
response, and maximum SPL output of single or arrayed  
Meyer Sound loudspeakers.  
Plan an entire portable or fixed loudspeaker system and  
determine delay settings for fill loudspeakers.  
Clearly see interactions among loudspeakers and  
minimize destructive interference.  
Place microphones anywhere in  
the sound field and predict the  
frequency response, impulse  
response, and sound pressure  
level at the microphone position  
using MAPP Online’s Virtual SIM  
feature.  
Refine your system design to  
provide the best coverage of the  
intended audience area.  
Use a Virtual VX-1 program  
equalizer to predetermine the  
correct control settings for best  
system response.  
Gain valuable load information  
about the array to determine  
rigging capacities.  
The MAPP Online prediction program  
enables you to come to an installation  
with a wealth of information that  
Figure 5.1. MAPP Online is an intuitive, powerful system design tool  
ensures the system will satisfy your requirements “out of  
the box” – including basic system delay and equalization  
settings. Its accurate, high-resolution predictions eliminate  
unexpected onsite adjustments and coverage problems.  
Residing on your computer, the MAPP Online prediction  
program facilitates configuring arrays of a wide variety  
of Meyer Sound products and, optionally, defines the  
environment in which they will operate, including air  
temperature, pressure, and humidity, as well as the location  
and composition of walls. You can find the program at:  
MAPP Online is compatible with Windows, Linux®, Unix®,  
and Apple® Macintosh® computers running Mac OS® X  
version 10.1.2 or higher. The MAPP Online Web page lists  
additional system requirements and recommendations.  
NOTE: In order to use the MAPP Online  
prediction program, you will need to register  
by clicking “Apply for MAPP Online” on the website  
listed above. After registration and upon approval,  
an e-mail will be sent to you with a user name and  
password along with the address for the website  
where you can download MAPP Online.  
23  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 5  
SIM MEASUREMENT SYSTEM  
Applications  
The SIM audio analyzer is a measurement and  
instrumentation system including a selection of hardware  
and software options, microphones and accessory cables.  
The SIM analyzer is optimized for making audio frequency  
measurements of an acoustical system with a resolution  
of up to 1/24 of an octave; the high resolution enables you  
to apply precise electronic corrections to adjust system  
response using frequency and phase (time) domain  
information.  
The main application of the SIM audio analyzer is  
loudspeaker system testing and alignment. This includes:  
Measuring propagation delay between the subsystems  
to set correct polarities and set very precise delay times  
Measuring variations in frequency response caused  
by the acoustical environment and the placement  
and interaction of the loudspeakers to set corrective  
equalization  
Optimizing subwoofer integration  
Source Independent Measurement Technique  
Optimizing loudspeaker arrays  
The SIM audio analyzer can also be used in the following  
applications:  
The SIM audio analyzer implements Meyer Sound's source  
independent measurement technique, a dual-channel  
method that accommodates statistically unpredictable  
excitation signals. Any excitation signal that encompasses  
the frequency range of interest (even intermittently) may  
be used to obtain highly accurate measurements of  
acoustical or electronic systems. For example, concert halls  
and loudspeaker systems may be characterized during a  
musical performance using the program as the test signal,  
allowing you to:  
Microphone calibration and equalization  
Architectural acoustics  
Transducer evaluation and correction  
Echo detection and analysis  
Vibration analysis  
Underwater acoustics  
View measurement data as amplitude versus time  
(impulse response) or amplitude and phase versus  
frequency (frequency response)  
Utilize a single-channel spectrum mode  
View frequency domain data with a logarithmic  
frequency axis  
Determine and internally compensate for propagation  
delays using SIM Delay Finder function  
24  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 5  
CHAPTER 6: QUICKFLY RIGGING  
The M2D and M2D-Sub loudspeakers feature Meyer  
Sound’s QuickFly rigging system with rugged, reliable  
and deceptively simple components that remain captive,  
in transit. QuickFly rigging facilitates constructing rigid,  
ground-stacked or flown M2D-Sub arrays, and eases  
integration of M2D-Sub and M2D loudspeakers in unitary,  
full-range curvilinear arrays.  
This chapter gives an overview of M2D and M2D-Sub  
rigging accessories. For complete information on how to set  
up and use the rigging accessories, refer to Meyer Sound’s  
7°  
(0° to 7°)  
CAUTION: All Meyer Sound products  
must be used in accordance 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 carried out only by experienced  
professionals.  
0°  
Figure 6.2. Vertical splay can be adjusted between 0° and 7° using  
CamLinks and quick release pins  
MG-2D MULTIPURPOSE GRID  
The MG-2D multipurpose grid (Figure 6.3) allows M2D and  
M2D-Sub loudspeakers to be flown or ground stacked.  
Fitted as standard on all M2D and M2D-Sub loudspeakers,  
the MRF-2D and MRF-2D-Sub rigging frames (Figure 6.1)  
also accommodates all the parts necessary to couple an  
M2D and M2D-Sub vertical array.  
Figure 6.3. MG-2D multipurpose grid  
TIP: See Meyer Sound’s assembly guides on  
on how to set up the M2D and M2D-Sub rigging  
accessories.  
An adjustable rear extension frame provides flexibility for  
severe up-tilt and down-tilt in flown applications as well as  
increasing the stability in ground-stacked applications. Up  
to 16 M2D loudspeakers (or the equivalent weight of M2D  
and M2D-Sub cabinets) may be suspended from single or  
multiple rigging points of appropriate rating, with a safety  
factor of 7:1.  
Figure 6.1. MRF-2D and MRF-2D-Sub Rigging Frames  
The MRF-2D and MRF-2D-Sub rigging frames utilize  
CamLinks to connect adjacent cabinets, allowing vertical  
splay to be set from 0° to 7° using quick release pins (Figure  
6.2). The CamLinks are easily reconfigured to allow arrays  
to be hung with the horns on the left or right side. The MRF-  
2D and MRF-2D-Sub frames provide a rigid angle between  
cabinets, maintaining the predetermined vertical splay as  
the array is tilted up or down.  
25  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
CHAPTER 5  
The MG-2D grid provides additional functionality, including  
transitioning to an M2D or M2D-Sub array from the bottom  
of a/an:  
M3D or M3D-Sub loudspeaker (MTK-2D transition kit  
required); or  
MILO loudspeaker (MTB-2D/M transition bar kit  
required)  
MG-1D Multipurpose Grid  
The MG-1D multipurpose grid (Figure 6.4) was originally  
designed to allow M1D and M1D-Sub loudspeakers to be  
flown or ground stacked. However, it can be used to fly  
M2D and M2D-Sub loudspeakers, when the flexibility of the  
MG-2D grid is not required.  
Figure 6.4. MG-1D multipurpose grid  
Up to seven M2D loudspeakers (or the equivalent weight of  
M2D and M2D-Sub loudspeakers) may be suspended from  
single or multiple rigging points of appropriate rating, with a  
safety factor of 7:1.  
The MG-1D grid provides additional functionality, such as  
transitioning from the bottom of an M2D and/or M2D-Sub  
array to:  
An M1D and/or M1D-Sub array;  
One UPA-1P compact wide coverage loudspeaker;  
Three UPA-2P compact narrow coverage loudspeakers;  
Two MSL-4 horn-loaded long-throw loudspeakers; or  
Two DS-4P horn-loaded mid-bass loudspeakers  
CAUTION: The grid must never be  
suspended from the extension frame when  
used in this configuration.  
26  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
APPENDIX A  
APPENDIX A  
TROUBLESHOOTING  
The audio produced by the loudspeaker is dis-  
torted or compressed but the Limit LED is not  
illuminated.  
This section contains possible solutions to some common  
problems encountered by M2D and M2D-Sub loudspeaker  
users and is not intended to be a comprehensive trouble-  
shooting guide.  
1. Make sure the XLR cable is securely fastened to the  
XLR audio input connector.  
2. Send the audio signal to another loudspeaker to insure  
that the level is within the proper range. Turn the source  
level down before reconnecting the audio input and  
increase the level slowly to avoid a sudden blast of  
sound.  
The On/Temp. LED (Active LED on M2D-Sub)  
does not illuminate and there is no audio.  
1. Make sure the AC power cable is the correct type for  
the regional voltage and that it is securely connected to  
the AC inlet, then unplug and reconnect the AC cable.  
3. Monitor the audio source with headphones.  
2. Use an AC voltmeter to verify that the AC voltage is  
within the ranges 90 - 265 V AC.  
The audio produced by the loudspeaker is highly  
compressed and the Limit LED is constantly yel-  
low (red on M2D-Sub).  
3. If the On/Temp LED still fails to illuminate, call Meyer  
Sound Technical Support.  
1. Turn down the level of the input signal to the loud-  
speaker system.  
The On/Temp. LED (Active LED on M2D-Sub) is  
illuminated green but there is no sound.  
1. Verify that the audio source (mixer, EQ, delay) is sending  
a valid signal.  
The On/Temp. LED (M2D) is illuminated red.  
This occurs in conditions where the heatsink temperature  
reaches 85°C (185°F), indicating that the amplifier is ther-  
mally overloaded.  
2. Make sure the XLR cable is securely fastened to the  
XLR audio input connector.  
3. Verify that the XLR cable is functioning by substitut-  
ing another cable or by using the cable in question in a  
working system.  
1. Turn down the level of the input signal to the loud-  
speaker system.  
2. Make sure the fan is working properly.  
4. Send the audio signal to another loudspeaker to insure  
signal presence and that the level is within the proper  
range. Turn the source level down before reconnecting  
the audio input and increase the level slowly to avoid a  
sudden blast of sound.  
3. Make sure there is sufficient air flow around the unit.  
4. Avoid exposing the heatsink to direct sunlight if the  
ambient temperature is high.  
See the amplification, limiting, cooling system sections  
beginning on page 10 for a complete discussion about the  
cooling system.  
5. If possible, monitor the audio source with headphones.  
Hum or noise is produced by the loudspeaker.  
Only the high or low drivers seem to produce  
sound (M2D).  
1. Disconnect the audio input. If the noise persists, the  
problem is within the loudspeaker. In this case return  
the unit to the factory or nearest authorized service cen-  
ter. If the hum ceases, the noise originates somewhere  
earlier in the signal path.  
1. Make sure the audio signal is full-range and has not  
been filtered in a previous stage of the signal chain. If  
possible, monitor the audio source with high-quality  
headphones.  
2. Make sure the XLR cable is securely fastened to the  
XLR audio input connector.  
2. Send the audio signal to another loudspeaker to insure  
that the signal is full-range. Turn the source level down  
before reconnecting the audio input and increase the  
level slowly to avoid a sudden blast of sound.  
3. Send the audio signal to another loudspeaker to insure  
signal presence and that the level is within the proper  
range. Turn the source level down before reconnecting  
the audio input and increase the level slowly to avoid a  
sudden blast of sound.  
3. Use a sine wave and/or pink noise generator to send a  
variety of frequencies to the loudspeaker.  
4. Hum or noise can be produced by a ground loop. Since  
the M2D and M2D-Sub loudspeakers are effectively  
ground-lifted, the loop must be broken elsewhere in the  
system.  
27  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
APPENDIX A  
28  
Download from Www.Somanuals.com. All Manuals Search And Download.  
APPENDIX B  
APPENDIX B  
M2D SPECIFICATIONS  
ACOUSTICAL  
Note: The low-frequency power response of the system will increase according to the length of the array.  
Operating frequency range 60 Hz - 16 kHz  
Note: Recommended maximum operating frequency range. Response depends upon  
loading conditions and room acoustics.  
Frequency response  
70 Hz - 14 kHz ±4 dB  
Note: Free field, measured with 1/3 octave frequency resolution at 4 meters.  
Phase response  
650 Hz - 12 kHz ±45°  
136 dB  
Maximum peak SPL  
Note: Measured with music at 1 meter.  
Dynamic range  
>110 dB  
Horizontal coverage  
Vertical coverage  
Acoustical crossover  
90°  
Varies, depending on array length and configuration.  
575 Hz  
Note: At this frequency, the mid- and high-frequency transducers produce equal sound  
pressure levels.  
TRANSDUCERS  
Low frequency  
Two 10" cone drivers with neodymium magnets  
Nominal impedance: 4 Ω  
Voice coil size: 2"  
Power-handling capability: 400 W (AES)  
Note: Power handling is measured under AES standard conditions: transducer driven  
continuously for two hours with band limited noise signal having a 6 dB peak-average ratio.  
Note: To eliminate interference at short wavelengths, the two 10" drivers work in combination at low frequencies (60 Hz  
– 350 Hz). At mid frequencies (350 Hz – 575 Hz) only one cone driver is fed from the crossover to maintain optimal polar  
and frequency response characteristics.  
High frequency  
One 4" diaphragm compression driver  
Nominal impedance: 8 Ω  
Voice coil size: 4"  
Exit size: 1.5"  
Power-handling capability: 250 W (AES)  
Note: Power handling is measured under AES standard conditions: transducer driven  
continuously for two hours with band limited noise signal having a 6 dB peak-average ratio.  
Note: The driver is coupled to a constant-directivity horn through a proprietary acoustical manifold (REM).  
AUDIO INPUT  
Type  
Differential, electronically balanced  
Max. common mode range ±15 V DC, clamped to earth for voltage transient protection  
Connectors  
Female XLR input with male XLR loop output or VEAM all-in-one connector (integrates AC,  
audio and network)  
Input impedance  
Wiring  
10 kΩ differential between pins 2 and 3  
Pin 1: Chassis/earth through a 220 kΩ, 1000 pF, 15 V clamp network to provide virtual  
ground lift at audio frequencies  
Pin 2: Signal +; Pin 3: Signal -  
Case: Earth ground and chassis  
DC Blocking  
CMRR  
Differential DC blocking up to max common mode voltage  
>50 dB, typically 80 dB (50 Hz – 500 Hz)  
29  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
APPENDIX B  
RF filter  
Common mode: 425 kHz; Differential mode: 142 kHz  
TIM filter  
<80 kHz, integral to signal processing  
Nominal input sensitivity  
Input level  
0 dBV (1 V rms, 1.4 V pk) continuous is typically the onset of limiting for pink noise and music.  
Audio source must be capable of producing a minimum of +20 dBV (10 V rms, 14 V pk)  
into 600 ohms in order to produce maximum peak SPL over the operating bandwidth of the  
loudspeaker.  
AMPLIFIER  
Amplifier type  
Output power  
Two-channel complementary MOSFET output stages (class AB/bridged)  
700 W total  
Note: Wattage rating is based on the maximum unclipped burst sine-wave rms voltage the  
amplifier will produce into the nominal load impedance — low channel 30 V rms (42 V pk);  
high channel 32 V rms (45 V pk)  
THD, IM TIM  
Load capacity  
Cooling  
< .02%  
2 Ω low channel, 8 Ω high channel  
Convection cooling. 24 V DC output for optional external fan.  
AC POWER  
AC power connector  
Voltage selection  
PowerCon or VEAM  
Automatic  
Safety agency rated  
operating voltage  
100 V AC - 240 V AC; 50/60 Hz  
Turn on/turn off points  
Continuous 90 V AC - 265 V AC; 50/60 Hz  
Note: No automatic turn-off voltages. Voltages above 265 V AC are fuse protected but  
may cause permanent damage to the power supply. Voltages below 90 V AC may result in  
intermittent operation.  
Current Draw  
Idle current  
0.35 A rms (115 V AC); 0.35 A rms (230 V AC); 0.35 A rms (100 V AC)  
Max. long-term continuous 3.1 A rms (115 V AC); 1.6 A rms (230 V AC); 3.6 A rms (100 V AC)  
current (>10 sec)  
Burst Current (<1 sec)  
3.2 A rms (115 V AC); 1.6 A rms (230 V AC); 3.7 A rms (100 V AC)  
5.8 A pk (115 V AC); 2.9 A pk (230 V AC); 6.7 A pk (100 V AC)  
Ultimate short-term peak  
current draw  
Inrush current  
9 A pk (115 V AC); 9 A pk (230 V AC); 8 A pk (100 V AC)  
RMS NETWORK  
Equipped for two conductor twisted-pair network, reporting all operating parameters of  
amplifiers to system operator’s host computer.  
PHYSICAL  
Enclosure  
Finish  
Multi-ply hardwood  
Black textured  
Protective grille  
Rigging  
Powder-coated hex stamped steel  
Patented QuickFly MRF-2D rigging frame with CamLinks and quick release pins  
39.00" w x 12.12" h x 17.47" d (991 mm x 308 mm x 444 mm)  
Dimensions  
12.12  
308 mm]  
9.99  
[254 mm]  
17.47  
6.06  
[154 mm]  
[444 mm]  
8.74  
[222 mm]  
37.00  
[940 mm]  
19.56  
39.00  
[991 mm]  
Weight  
30  
116 lbs (52.62 kg); Shipping 130 lbs (58.97 kg)  
Download from Www.Somanuals.com. All Manuals Search And Download.  
APPENDIX B  
M2D-SUB SPECIFICATIONS  
ACOUSTICAL  
Note: The low-frequency power response of the system will increase according to the length of the array.  
Operating frequency range 28 Hz - 160 Hz  
Note: Recommended maximum operating frequency range. Response depends upon  
loading conditions and room acoustics.  
Frequency response  
30 Hz - 140 Hz ±4 dB  
Note: Free field, measured with 1/3 octave frequency resolution at 4 meters.  
Phase response  
40 Hz to 100 Hz ±45°  
138 dB  
Maximum peak SPL  
Note: Measured with music at 1 meter.  
Dynamic range  
>110 dB  
Horizontal coverage  
Vertical coverage  
360°  
Varies, depending on array length and configuration.  
TRANSDUCERS  
Low frequency  
Two 15" cone drivers with neodymium magnets  
Nominal impedance: 4 Ω  
Voice coil size: 4"  
Power-handling capability: 1200 W (AES)  
Note: Power handling is measured under AES standard conditions: transducer driven  
continuously for two hours with band limited noise signal having a 6 dB peak-average ratio.  
AUDIO INPUT  
Type  
Differential, electronically balanced  
Max. common mode range ±15 V DC, clamped to earth for voltage transient protection  
Connectors  
Female XLR input with male XLR loop output or VEAM all-in-one connector (integrates AC,  
audio and network)  
Input impedance  
Wiring  
10 kΩ differential between pins 2 and 3  
Pin 1: Chassis/earth through a 220 kΩ, 1000 pF, 15 V clamp network to provide virtual  
ground lift at audio frequencies  
Pin 2: Signal +  
Pin 3: Signal -  
Case: Earth ground and chassis  
DC Blocking  
CMRR  
None on input; DC blocked through signal processing  
>50 dB, typically 80 dB (50 Hz – 500 Hz)  
RF filter  
Common mode: 425 kHz; Differential mode: 142 kHz  
<80 kHz, integral to signal processing  
TIM filter  
Nominal input sensitivity  
0 dB V (1 V rms, 1.4 pk) continuous is typically the onset of limiting for pink noise and  
music.  
31  
Download from Www.Somanuals.com. All Manuals Search And Download.  
 
APPENDIX B  
Input level  
Audio source must be capable of producing a minimum of +20 dBV (10 V rms, 14 V pk)  
into 600 ohms in order to produce maximum peak SPL over the operating bandwidth of the  
loudspeaker.  
AMPLIFIERS  
Amplifier type  
Output power  
Two-channel complementary MOSFET output stages (class AB/H)  
2250 W total  
Note: Wattage rating is based on the maximum unclipped burst sine-wave rms voltage the  
amplifier will produce into the nominal load impedance — both channels 67 V rms (95 V pk).  
THD, IM TIM  
Load capacity  
Cooling  
< .02%  
4 Ω each channel  
Forced air cooling, 2 fans total (1 ultrahigh-speed reserve fan)  
AC POWER  
AC power connector  
Voltage selection  
PowerCon or VEAM  
Automatic, two ranges, each with high-low voltage tap (uninterrupted)  
95 V AC - 125 V AC; 208 V AC - 235 V AC; 50/60 Hz  
Safety agency rated  
operating voltage  
Turn on/turn off points  
Current Draw  
85 V AC - 134 V AC; 165 V AC - 264 V AC; 50/60 Hz  
Idle current  
0.640 A rms (115 V AC); 0.320 A rms (230 V AC); 0.850 A rms (100 V AC)  
Max. long-term continuous 8.8 A rms (115 V AC); 4.4 A rms (230 V AC); 10 A rms (100 V AC)  
current (>10 sec)  
Burst Current (<1 sec)  
19 A rms (115 V AC); 9.5 A rms (230 V AC); 22 A rms (100 V AC)  
39 A pk (115 V AC); 20 A pk (230 V AC); 45 A pk (100 V AC)  
Ultimate short-term peak  
current draw  
Inrush current  
7 A pk (115 V AC); 7 A pk (230 V AC); 10 A pk (100 V AC)  
RMS NETWORK  
Equipped for two conductor twisted-pair network, reporting all operating parameters of  
amplifiers to system operator’s host computer.  
PHYSICAL  
Enclosure  
Finish  
Multi-ply hardwood  
Black textured  
Protective grille  
Rigging  
Powder-coated hex stamped steel  
Patented QuickFly MRF-2D-Sub rigging frame with CamLinks and quick release pins  
39.00" w x 24.00" h x 17.50" d (991 mm x 610 mm x 445 mm)  
Dimensions  
21.86  
[555 mm]  
24.00  
[610 mm]  
11.25  
[286 mm]  
37.00  
[940 mm]  
39.00  
[991 mm]  
17.50  
[445 mm]  
8.50  
[216 mm]  
19.50  
[495 mm]  
Weight  
173 lbs (78.47 kg); Shipping: 197 lbs (89.35 kg)  
32  
Download from Www.Somanuals.com. All Manuals Search And Download.  
Download from Www.Somanuals.com. All Manuals Search And Download.  
© 2004  
Meyer Sound Laboratories, Inc.  
All Rights Reserved  
Meyer Sound Laboratories, Inc.  
2832 San Pablo Avenue  
Berkeley, CA 94702  
USA  
T: +1 510 486.1166  
F: +1 510 486.8356  
05.112.012.01  
Download from Www.Somanuals.com. All Manuals Search And Download.  

KTI Networks Switch KT 10F User Manual
Lanner electronic Network Card IAC F848 User Manual
Lenoxx Electronics Home Theater System HT 395 User Manual
Leupold Binoculars 56113 User Manual
LG Electronics Portable DVD Player DP889 User Manual
Liebert Refrigerator PS024A User Manual
Life Fitness Home Gym Elevation Series User Manual
Mabe Canada Cooktop JCBP240 User Manual
MB QUART Speaker DKE168 User Manual
Meridian Audio Speaker M60C User Manual