Danley DNA 10K4, DNA 20K4 User Manual

Danley Sound Labs

DNA Pro Series Advanced System Amplifiers

User Guide

For DNA 10K4 and DNA 20K4

Version 1 (For firmware version 1.100 and above)

1

Contents

IMPORTANT SAFETY INSTRUCTIONS ..................................................................................................... 5

CONSIGNES DE SÉCURITÉ IMPORTANTES .............................................................................. 6

COMPLIANCE ......................................................................................................................................... 8

FOR CUSTOMERS IN EUROPE ............................................................................................................. 8

FOR CUSTOMERS IN THE USA ............................................................................................................ 9

FOR CUSTOMERS IN THE CANADA ................................................................................................... 10

Thanks and Unpacking ......................................................................................................................... 11

Unpacking the Danley Sound Labs DNA Pro Amplifier .................................................................... 11

INSTALLATION INSTRUCTIONS ............................................................................................................. 12

Mechanical Installation .................................................................................................................... 12

AC Power Connection ...................................................................................................................... 13

The User Guide .................................................................................................................................... 14

Introduction and Key Features ............................................................................................................ 15

Introduction ..................................................................................................................................... 15

Key Features ................................................................................................................................ 15

Audio Connections ............................................................................................................................... 18

Input Connections ........................................................................................................................... 18

Using unbalanced connections ........................................................................................................ 18

Amplifier Output Connections ......................................................................................................... 18

100V line operation ......................................................................................................................... 19

Panel Layouts ....................................................................................................................................... 20

Operation ............................................................................................................................................ 22

Starting up the unit .......................................................................................................................... 22

Overview of Modules, Presets Components and Snapshots ........................................................... 22

Navigation ........................................................................................................................................ 23

The Home Page ................................................................................................................................ 24

Drive Modules ................................................................................................................................. 24

Drive Module Presets ...................................................................................................................... 24

Component Presets ......................................................................................................................... 25

Factory Module Presets ................................................................................................................... 25

Storing Module Presets ............................................................................................................... 25

Recalling Module Presets ............................................................................................................ 26

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Recalling Components ................................................................................................................. 26

Input ................................................................................................................................................ 26

AES3 Inputs .................................................................................................................................. 26

Networked Audio (Dante) Inputs ................................................................................................. 27

Gain and Polarity ......................................................................................................................... 27

Delay ............................................................................................................................................ 27

High Pass Filter ............................................................................................................................ 27

Parametric Equalization ............................................................................................................... 28

FIR Shelving EQ ............................................................................................................................ 28

Parametric Filters ......................................................................................................................... 28

Routing ........................................................................................................................................ 28

Output ............................................................................................................................................. 28

Gain and Polarity ......................................................................................................................... 28

Delay ............................................................................................................................................ 29

High and Low pass Filters ............................................................................................................ 29

LIR Crossover Filtering ................................................................................................................. 29

Parametric Equalization and All-‐Pass Filters ................................................................................ 29

Limiters ........................................................................................................................................ 30

Bridge ........................................................................................................................................... 31

Routing ........................................................................................................................................ 31

Utility Pages ..................................................................................................................................... 31

Screen Contrast ........................................................................................................................... 31

Stereo Linking .............................................................................................................................. 31

Current Ethernet IP Address ........................................................................................................ 31

IP Mode ....................................................................................................................................... 32

IP Static ........................................................................................................................................ 32

Store Snapshot ............................................................................................................................. 32

Recall Snapshot ............................................................................................................................ 32

Bandwidth Units .......................................................................................................................... 32

Aux Style ...................................................................................................................................... 32

ECO .............................................................................................................................................. 32

External Breaker Protection (EBP) ................................................................................................... 33

Ethernet ........................................................................................................................................... 33

Ethernet configurations ............................................................................................................... 33

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DHCP ............................................................................................................................................ 33

AUTO-‐IP ....................................................................................................................................... 33

Static-‐IP ........................................................................................................................................ 33

IP Troubleshooting ....................................................................................................................... 33

Snapshots ........................................................................................................................................ 34

AUX Port .......................................................................................................................................... 34

Latency delay ................................................................................................................................... 36

Input/Output Latencies ............................................................................................................... 36

Processing Latencies .................................................................................................................... 36

Secure Mode .................................................................................................................................... 37

Overlay Flush ................................................................................................................................... 37

Protection Systems .......................................................................................................................... 37

Incident Reporting ........................................................................................................................... 38

Fault Relay ....................................................................................................................................... 38

Performance Logging ....................................................................................................................... 38

Processing Block Diagram .................................................................................................................... 40

Input Menu Map Utility Menu Map .................................................................................. 41

Output Menu Map ............................................................................................................................... 42

EQ and Filter Response Graphs ........................................................................................................... 43

Technical Specifications ....................................................................................................................... 47

General ............................................................................................................................................ 47

Audio ............................................................................................................................................... 47

Digital processing ............................................................................................................................. 48

Power supply ................................................................................................................................... 48

Protection systems .......................................................................................................................... 48

System protection ......................................................................................................................... 48

Power distribution protection systems ........................................................................................... 49

Monitoring and logging ................................................................................................................... 49

OEM Features ...................................................................................... Error! Bookmark not defined.

Physical ............................................................................................................................................ 49

Options ................................................................................................................................................ 49

4

IMPORTANT SAFETY INSTRUCTIONS

5

6

7

1

2

3

4

Read these instructions.

Keep these instructions.

Heed all warnings.

Follow all instructions.

Do not use this apparatus near water.

Clean only with dry cloth.

Do not block any ventilation openings. Install in accordance with the manufacturer's instructions.

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9

Do not install near any heat sources such as radiators, heat registers, stoves or other apparatus (including amplifiers) that produce heat.

Do not defeat the safety purpose of the polarized or grounding type plug. A polarized plug has two blades with one wider than the other. A grounding type plug had two blades and a third grounding prong. The wide blade or the third prong are 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 apparatus.

11 Only use attachments / accessories specified by the manufacturer.

12 Use only with the cart, tripod, bracket or table specified by the manufacturer, or sold with the apparatus. When a cart is used, use caution when moving the cart / apparatus combination to avoid injury from tip-‐over.

13 Unplug this apparatus during lightning storms or when unused for long periods of time.

14 Refer all servicing to qualified service personnel. Service is required when the apparatus has been

damaged in any way, such as power-‐supply cord or plug damaged, liquid has been spilled or objects have fallen into the apparatus, this apparatus has been exposed to rain or moisture, does not operate normally, or has been dropped.

SAFETY WARNING

Do not remove any covers, loosen any fixings or allow items to enter any aperture.

SAFETY WARNING

The rear of the product may get hot. Avoid direct skin contact during operation and for at least 5 minutes after power has been isolated.

SAFETY WARNING

The product must only be positioned at floor level when operated in a horizontal position.

5

CONSIGNES DE SÉCURITÉ IMPORTANTES

1.

Lisez ces instructions.

2.

Conservez ces instructions.

3.

Respectez tous les avertissements.

4.

Suivez toutes les instructions.

5.

Ne pas utiliser cet appareil près de l'eau.

6.

Nettoyer uniquement avec un chiffon sec.

7.

Ne pas bloquer les ouvertures de ventilation. Installer conformément aux instructions du fabricant.

8.

Ne pas installer près de sources de chaleur telles que radiateurs, registres de chaleur, poêles ou autres appareils (y compris les amplificateurs) qui produisent de la chaleur.

9.

Ne supprimez pas le dispositif de sécurité de la fiche polarisée ou mise à la terre.

Une fiche polarisée possède deux lames dont l'une est plus large que l'autre. Une prise de terre a eu deux lames et une troisième broche de terre. La lame large ou la troisième broche sont fournies pour votre sécurité. Si la fiche fournie ne rentre pas dans votre prise, consultez un électricien pour remplacer la prise obsolète.

10.

Protéger le cordon d'alimentation soit écrasé ou pincé, particulièrement au niveau des fiches, des prises et le point où ils sortent de l'appareil.

11.

Utilisez uniquement les accessoires spécifiés par le fabricant.

12.

Utilisez uniquement le chariot, le trépied, le support ou la table spécifiés par le fabricant, ou vendu avec l'appareil. Quand un chariot est utilisé, soyez prudent lorsque vous déplacez l'ensemble chariot / appareil afin d'éviter toute blessure en cas de chute.

13.

Débranchez cet appareil pendant les orages ou lorsqu'il n'est pas utilisé pendant de longues périodes de temps.

14.

Adressez-‐vous à un personnel qualifié. Une réparation est requise lorsque l'appareil a été endommagé de quelque façon que ce soit le cordon d'alimentation ou la fiche endommagé, du liquide a été renversé ou des objets sont tombés dans l'appareil, cet appareil a été exposé à la pluie ou à l'humidité, ne fonctionne pas normalement, ou s'il est tombé.

15.

Le dispositif ne doit pas être exposé à des gouttes ou des éclaboussures et aucun objet rempli de liquides, tels que des vases, doit être placé sur l'appareil.

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16.

Déconnexion permanente de l'alimentation secteur doit être atteint en supprimant le connecteur du cordon fourni à l'arrière de l'unité. Ce connecteur doit être facilement utilisable.

AVERTISSEMENT DE SECURITE

Ne retirez pas les couvercles, ne desserrez pas les fixations et ne laissez aucune pièce s'introduire dans les ouvertures.


Le radiateur arrière de cet appareil devient chaud. Evitez tout contact direct avec la peau pendant le fonctionnement et au moins 5 minutes après la mise hors tension de l'appareil.


Le produit ne doit être positionné au niveau du sol lorsqu'il est utilisé en position horizontale.

7

COMPLIANCE

FOR CUSTOMERS IN EUROPE

This product complies with both the LVD (electrical safety) 73/23/EEC and EMC

(electromagnetic compatibility) 89/336/EEC directives issues by the commission of the

European community.

Compliance with these directives implies conformity with the following European standards:

EN60065 Product safety

EN55103-‐1 EMC emissions

EN55103-‐2 EMC immunity

This product is intended for the following electromagnetic environments: E1, E2; E3 & E4.

THIS PRODUCT MUST BE EARTHED ( GROUNDED). Use only a flexible cable or cord with a green and yellow core which must be connected to the protective earthing (ground) terminal of a suitable mains plug or the earthing ( grounding) terminal of the installation.

The cord must be a maximum of 2m long, have a 2.5mm

2 CSA, a 300/500V rating and comply with EN50525-‐2-‐11 / H05W-‐F.

THIS PRODUCT IS DESIGNED FOR PERMANENT INSTALLATION. It must be fitted in to a 19” rack enclosure and not operated unless so installed. The rack enclosure should be open at the front and back to allow free ventilation and movement of air through the product.

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FOR CUSTOMERS IN THE USA

This product complies with UL60065 7th edition.

THIS PRODUCT MUST BE GROUNDED. Use only a flexible cable or cord with a green or green

/ yellow core which must be connected to the protective ground terminal of a suitable mains plug or the ground terminal of the installation. The cord must be a maximum of 6’ long, be 14AWG, have a rating SJ, SJT, SJE or 300/500V H05W-‐F and be marked VW-‐1.


DECLARATION OF CONFORMITY WITH FCC RULES

We, Danley Sound Labs Gainesville, Georgia, USA, declare under our sole responsibility that this family of devices, complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) this device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.

FEDERAL COMMUNICATIONS COMMISSION NOTICE

An example of this equipment has been tested and found to comply with the limits for a

Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential and commercial installation.

This equipment generates, uses, and can radiate radio frequency energy, and if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try and correct the interference by one or more of the following measures:

•

Reorient or relocate the receiving antenna.

•

Increase the distance between the equipment and the receiver.

•

Connect the equipment to an outlet on a circuit different from that to which the receiver is connected.

•

Consult the dealer or an experienced radio/TV technician for help.

FCC Caution: Any changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate this equipment.

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FOR CUSTOMERS IN CANADA

This product complies with CA /CSA C22.2 No.60065-‐03

Ce produit est conforme avec CA /CSA C22.2 No.60065-‐03

THIS PRODUCT MUST BE EARTHED. Use only a flexible cable or cord with a green or green / yellow core which must be connected to the protective earthing terminal of a suitable mains plug or the earthing terminal of the installation. The cord must be a maximum of 6’ long, be

14AWG, have a rating SJ, SJT, SJE or 300/500V H05W-‐F and be marked VW-‐1.

CE PRODUIT DOIT ÊTRE MIS À LA TERRE. Utilisez uniquement un câble souple avec un noyau vert ou vert / jaune qui doit être relié à la borne de terre de connecteur d'alimentation ou la borne de terre de l'installation. Le cordon doit être un maximum de 6' (2m) de long, 14 AWG

(2.5mm

2 CSA), être classé SJ, SJT, SJE ou 300/500V H05W-‐F et être marquée VW-‐1


CE PRODUIT EST CONÇU POUR UNE INSTALLATION PERMANENTE. Il doit être installé dans un boîtier rack 19 ". Le rack devrait être ouvert à l'avant et l'arrière pour permettre la ventilation et le mouvement d'air libre à travers le produit .

DECLARATION OF CONFORMITY WITH CANADIAN ICES-‐003

This Class B digital apparatus complies with Canadian ICES-‐003.

Cet appareil numérique de la classe B est conforme à la norme NMB-‐003 du Canada.

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Thanks and Unpacking

Thank you for choosing a Danley Sound Labs DNA Pro Advanced System Amplifier for your application. Please spare a little time to study the contents of this manual, so that you obtain the best possible performance from this unit.

All Danley Sound Labs products are carefully engineered for world-‐class performance and reliability.

If you would like further information about this or any other Danley Sound Labs product, please contact us. We look forward to helping you in the near future.

Unpacking the Danley Sound Labs DNA Pro Amplifier

After unpacking the unit please check carefully for damage. If damage is found, please notify the carrier concerned at once. You, the consignee, must instigate any claim. Please retain all packaging in case of future re-‐shipment.

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INSTALLATION INSTRUCTIONS

Mechanical Installation

482

431

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The DNA Pro Amplifier system is designed to be mounted in a standard 19” rack enclosure.

Where the amplifier is used in a fixed installation, as long as the bottom unit is supported and there are no gaps between units, it is acceptable to use only the front panel 19” rack holes when fitting it in a standard rack enclosure. If the amplifier is mounted in a mobile rack it is important that the rear is supported with a rear rack mounting kit (part number ZA1182). Damage caused by insufficient support is not covered by the warranty.

To prevent damage to the front panel it is recommended that plastic cups or washers are fitted underneath the rack mounting bolt heads.

It is possible to mount multiple DNA Pro amplifiers without ventilation gaps between them but it is essential that an unobstructed flow of clean air is available from the front of the unit to the rear. It is important that neither the air intakes on the front of the unit or the exhaust vents at the rear are covered. Steps must be taken to ensure that hot air does not continually circulate through the amplifiers from the back of the rack to the front.

The amplifier should never be exposed to rain or moisture during operation or storage. If the unit does come into contact with moisture, remove the AC power cord immediately and leave it in a dry and warm location to dry out.

Note that when any equipment is taken from a cold location into a hot humid one, condensation may occur inside the device. Always allow time for the equipment to attain the same temperature as its surrounding environment before connecting the AC power cord.

AC Power Connection

The amplifier utilises a 32A Neutrik PowerCon TM type locking AC power connector. Use only an AC power cord with a correctly terminated PowerCon TM type connector to make the connection to the mains power supply.

The amplifiers are designed to operate on 50/60 Hz AC power. The power supply sections automatically configure themselves for either 115V or 230V nominal voltage at turn on. The amplifiers will operate over an extended range of supply voltages (please refer to the technical specifications).

Note that while the amplifier will operate correctly at voltages indicated, the specified output power will only be achieved when operating with the stated nominal voltages.

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The User Guide

This user manual gives a progressively more detailed description of the functions of the Danley

Sound Labs DNA Pro Advanced System Amplifier. A single page quick reference guide is provided for those users who are experienced with this type of equipment and just need to know how to ‘drive’ the front panel. A detailed explanation of the front and rear panel controls and indicators is

contained in the next section.

The final section describes each individual function or feature with annotated images explaining its use. Where appropriate, the graphical display is shown to further elaborate on the units operation.

To complete the manual a reference section is included, describing the technical performance of the

device complete with graphs of filter responses.

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Introduction and Key Features

Introduction

The Danley Sound Labs DNA Pro Advanced System Amplifier represents current state-‐of-‐the-‐art technology in several areas. This product is the result of several years of research, from which many advances in switched mode power technologies and ever finer detail in signal processing have stemmed. Taking advantage of the latest advances in analogue to digital conversion technologies, the unit achieves performance levels among the very best that engineering permits.

Below is a list of key features, followed by some information on the major advanced features of the product.

Key Features

-‐ Four channels of sonically pure Class D amplification

-‐ Very high power density packs four channels and 20kW into just 2U of rack space

-‐ Packed with robust protection and monitoring systems to keep the show going

-‐ External Breaker Protection (EBP) limits the current draw to prevent breakers opening

-‐ Danley Sound Labs minimal signal path design

-‐ Class leading sonic performance achieved by the use of state of the art Amplifier technologies and highly advanced DSP algorithms using Linea Micro Detail (LMD)

-‐ 96kHz sampling frequency provides for a nominally flat response beyond 40kHz.

-‐ Rotary encoders, illuminated buttons and graphical display provide a rapid, intuitive and user-‐friendly control interface

-‐ High speed Ethernet communications supporting DHCP, static-‐IP and auto-‐IP and direct connection to a computer without the need for a router or a switch

-‐ Powerful Drive Module concept, abstraction from device centric to speaker based control

-‐ Innovative Component Presets to allow individual outputs to be used for selected drivers of a loudspeaker system

-‐ Twelve layers of Parameter Overlays for trouble-‐free Grouping

-‐ Unique VX limiter providing dynamic control for passive 2-‐way enclosures

-‐ Unique LIR linear phase crossover shapes giving FIR-‐like performance without the drawbacks

-‐ Linear phase HF system EQ profiling which provides perfect integration between enclosures

-‐ Innovative excursion control limiter with sliding High Pass Filter; limits only the damaging low frequencies

-‐ Transducer thermal modelling provides regulation limiters, addressing long term overload

-‐ Overshoot limiter governs amplitude of transient signals retaining average power while constraining peak energy

-‐ Dante audio networking with AVB upgrade path

-‐ AES3 inputs

15

Drive Modules

The DNA Pro processor has a new way of ordering and grouping channels in order to give a more speaker-‐based approach to controlling, designing and recalling speaker configurations; these are called Drive Modules. A Drive Module is the Processing provided by one Input DSP Block, and a number of Output DSP Blocks, which are associated with one-‐another by means of routing. For example, if Input DSP Block B is routed to Outputs 3 and 4, then this is a 2-‐way Drive Module with

Input DSP Block B forming the ‘Master’ control, and Output DSP Blocks 3 and 4 providing the driver-‐ related control. Overall, this forms the processing typically for one loudspeaker sub-‐system. The

PodWare Drive Module control panel for this sub-‐system may then be used for control and monitoring of the associated speaker.

Drive Modules may be included in Module Groups, which use the Parameter Overlay feature in the

Device to achieve trouble-‐free Grouping in the PodWare application.

The Presets in the Device are Drive-‐Module centric, and are used to configure individual Drive

Modules rather than the whole device.

Importantly, Drive Modules move the focus away from the processing device, and onto the loudspeaker systems.

Component Presets allow the Drive Module Presets to be broken apart, allowing any output to be used for any component within a Drive Module Preset (i.e. any driver in a loudspeaker subsystem).

See Overview of Modules

Overlays

When the Device is used in Modules view in PodWare, this allows the modules to be grouped into

Overlay G roups . These groups allow various Input (master) parameters to be adjusted in all modules in that group, whist maintaining independent parameter values across each group. This is achieved in the device by combining the parameters for all the layers for a given section (Gain Delay, EQ etc.).

When an Overlay parameter is active, the Overlay indicator will become illuminated. The combined

Gain or Delay etc. associated with a given section is shown on the module panel in PodWare, within square brackets [ ] under the Delay and Gain for each input channel. The combined EQ curve is shown in an olive colour. The Input Mute button in PodWare will flash if an overlay mute is active.

On the device, the presence of an active overlay is generally indicated by square brackets “[]” after the parameter value on the display. An input overlay mute is indicated on the mute/clip indicator for that channel flashing. Note that overlay parameters cannot be adjusted on the Device itself; these can only be controlled by the PodWare application. However, overlay parameters may be removed on the device

– see Overlay Flush .

LIR Linear Phase Crossover Filtering

The Device also includes a new type of crossover filtering “Linear Impulse Response” (LIR) crossover filtering, which results in a Linear Phase crossover that has a constant delay regardless of frequency

(unlike other types of crossover which delay different frequencies to a different extent, thus

16

smearing the arrival time). The LIR crossover can thus be described as having a flat Group Delay response, and thus entirely free of Group Delay Distortion.

The shape of the LIR crossover filter is quite similar to a 4 th order or 24dB/Oct Linkwitz-‐Riley filter, and maintains zero phase difference between the adjacent bands across the crossover region to keep the polar response rock steady.

FIR Linear Phase Equalization

The Input High-‐Shelf Equalizers use Finite Impulse Response (FIR) filtering to produce Linear Phase equalization; that is all frequencies are delayed by the same amount, perfectly preserving the transient response. This can also be important in applications where different amounts of EQ are applied to different parts of a speaker cluster, such as to add 'Throw' EQ boost so that parts of cluster which are throwing further can have HF absorption correction added. If this EQ is not linear phase, then the zones where the speakers combine may suffer frequency response anomalies.

17

Audio Connections

Input Connections

For each input channel there is a female XLR input connector. Even channel numbers are for

Analogue inputs only. Odd channel numbers are either for Analogue inputs (when in Analogue input mode) or for AES3 input pairs (when in AES3 input mode).

The HOT, + or ‘in phase’ connection should be made to pin 2 of the XLR connector.

The COLD, -‐ or ‘out of phase’ connection should be made to pin 3 of the XLR connector.

Pin 1 of the XLR connectors is internally connected to the chassis. The shield of the input cable should always be connected Pin 1 of the XLR to ensure that EMC performance and regulations are met.

Input XLR balanced connection

2

3

1

Pin 2 HOT +

Pin 3 COLD -

Pin 1 Shield

Using unbalanced connections

Please note that the use of unbalanced connections is not recommended, however when connecting the amplifier to an unbalanced audio source, the signal conductor should be connected to XLR pin2.

The ‘Cold’ conductor or cable screen should be connected to XLR pin 1 with a short connection made between pin 1 and pin 3.

Input XLR unbalanced connection

2

3

1

HOT +

Shield

Amplifier Output Connections

The amplifier is fitted with one Speakon TM connector per amplifier channel. The appropriate conductor terminations are shown below and on the rear panel of the unit.

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Amplifier output connections

1+

1-

2+ 2-

Speaker -

Speaker +

The Speakon TM connector for amplifier channel 1 carries the output for amplifier channels 1 and 2.

Similarly, the Speakon TM connector for amplifier channel 3 carries the output for amplifier channels 3 and 4. This can be useful for making a connection to two loudspeakers with one 4-‐core cable (i.e. Bi-‐

Amp):

Amplifier output connections – Bi Amp

1+

1-

2+ 2-

Speaker1 -

Speaker1 +

Speaker2 -

Speaker2 +

In addition, the channel 1 or channel 3 connector can also be used if the pair of amplifier channels is being operated in bridged mode.

Amplifier output connections – Bridge

1+

1-

2+ 2-

Speaker +

Speaker -

More than one speaker can be connected to each channel provided the total impedance per channel is not less than 2 ohms . In bridged mode the minimum total impedance should not be less than 4 ohms .

100V line operation

Each output of the device can be configured to drive either a low impedance load (LOW-‐Z), or a

Constant Voltage (CV) such as 70V LINE or 100V LINE using the CV parameter in the Output menu.

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Panel Layouts

Limiter Indicators-‐ The output indicators shows the status of the limiter and output level. The < SIG > indicator shows signal presence and will illuminate when a signal is present in the output. The second indicator < -‐6dB > shows that the signal has reached 6dB below the limiter threshold. The third < LIMIT > indicator indicates that the threshold of that

Driver Indicator-‐ limiter has been exceeded, or when the thermal limiter is active, protecting against long term thermal stress. Please

note that because of the long release time of the thermal limiter, this indicator may remain illuminated for several seconds after signal on that channel is reduced.

Amplifier Indicator-‐ This indicates when the amplifier protection systems are reducing the gain to keep the parameters of the amplifier within specification, or that the channel is clipping.

Mute Buttons-‐ DSP output mute status is indicated and controlled by and illuminated button for each channel. These

Bridge Indicator-‐

Bridge Mode

Two velocity sensitive parameter encoders are used to adjust parameters shown on the display.

Up to three parameters at a time are displayed on the screen. The parameter name is shown above the parameter

Status Indicators

OVERLAY ” indicator shows when there are parameters active on a group layer, which the user

Overlay Flush ). The “ NETAUDIO ” indicator shows that a networked digital audio card is installed and routed (Such as Dante™). The “

ONLINE ” indicator has three states: Off – unit does not find an IP address the unit will assign itself an IP address automatically and the indicator will stop flashing. On-‐ the unit is online and connected with software. IP settings can be viewed or changed within the < UTILITY> pages. The “ AES3 IN ” indicator illuminates when one or more of the inputs is using an AES3 source.

Graphical Display-‐ When the device is switched on, it will show the Home screen. This provides a useful overview of

UTILITY > button to

most pages the currently selected channel and parameter information is displayed on the upper part of the screen and

Page Selection Buttons-‐ When one of the buttons < INPUT >, < OUTPUT > or < UTILITY > is illuminated, the up < p > and down < q > arrows will also illuminate, informing the user that these buttons may be used to scroll through the various

pages of parameters that may be viewed and edited. The < ENTER > button is used to confirm an operation such as storing or recalling a preset or snapshot. It will illuminate when the user is being invited to press it. It will flash when

Menu Buttons-‐

OUTPUT > button displays pages of parameters associated with a particular output channel. The <

INPUT

INPUT

> button displays pages of

> or < OUTPUT > buttons repeatedly will scroll through the inputs/outputs of the processor. After the last channel, navigation returns to the

Home screen. The <

UTILITY > button displays pages of miscellaneous parameters not associated with any particular

Power Switch-‐ Applies mains power to the device. If the device has entered Sleep mode, it may be woken up again

A set of five indicators show “Sig ”, “ -‐12 ”, “ 0dBu ”, “ +6 ” and “ +12 ” and “ Clip (mute)” for each of

the DSP inputs “ A ” “

B ” “ C ” “ D ”. The signal present Indicators operate at approximately –40 dBu. The “ 0dBu ” indicators

Clip/mute

Indicators-‐ warn the user of input overload and operate at 1dB before clip. This indicator also shows a muted input state, and will remain illuminated at all times whilst mute is active. Input mute is turned on/off in the < INPUT> gain

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Relay output-‐ This isolated relay output may be used to indicate abnormal conditions to external monitoring apparatus. See Fault Relay

Power Inlet -‐ The unit should be connected to a suitable mains electricity supply using an earthed Powercon connection power lead. The device has a switch mode power supply that is capable of operating with a nominal mains voltage of

Auxiliary Port-‐

Ethernet Communications Port-‐ The device may be controlled entirely from another controller, typically a Personal

normally be made to the controller via this Ethernet port connector. This port is also used for updating the firmware in the unit.

Networked Audio Ports

vendor.

For inputting Digital Audio signals. The Input is fully balanced and wired: pin-‐1 to ground, pin-‐2 data+ & pin-‐3 data. The Link connector allows a buffered AES3 signal to be passed on to another device.

Audio Input Connectors-‐ All audio connections are fully balanced and wired: pin-‐1 to ground (as required by the AES48 standard), pin-‐2 hot & pin-‐3 cold.

Loudspeaker Connectors-‐ The amplifier Speakon TM outputs. Connect the loudspeaker to the 1+ and 1-‐ terminals. CH1 also carries the (duplicated) loudspeaker output for channel 2 on terminals 2+ and 2-‐. Similarly, CH3 carries the loudspeaker output for channel 4 on terminals 2+ and 2-‐. For Bridged mode, use terminals 1+ and 2+ of either CH1 or

CH3.

21

Operation

Starting up the unit

When power switch is switched on the unit will go through its start-‐up cycle, checking all the sub-‐ systems as it does so. Along the way, the screen will inform you of its progress. Once this is complete the display will then show the Home screen indicating drive module configurations.

Overview of Modules, Presets Components and Snapshots

A Drive Module represents a loudspeaker subsystem, and comprises one input channel and a number of output channels, associated with one-‐another by routing. The size of the Drive module is determined by the number of outputs in it. The device may contain up to four Modules.

Output 1

DSP Input A

Output 2

A Module Preset is a collection of settings (parameters) for a Drive Module of a particular size. The

Preset contains a set of parameters for one input and a set of parameters for each of the outputs in the module. When a Module Preset is recalled, it will automatically change the routing between

Input DSPs and Outputs, consuming a number of outputs according to the size of the Drive Module.

Recalling a Module Preset thus always creates a Drive Module with consecutive outputs.

Input component parameters

Output component parameters


A Component is a collection of settings (parameters) for one (input or output) channel. Any one of the output components in a Module Preset may be recalled to any individual output.

Input parameters



Component

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These concepts are depicted in the PodWare application as in the following example of a 2-‐way

Module:

A Snapshot is a device-‐wide representation of most of the settings in the device. This is represented as four Input Component numbers, eight Output Component numbers, plus a number of machine-‐ centric settings such as routing and Input/Output Analogue/Digital selection etc.

Device

Settings

Input A component number

Input B component number

Input C component number

Input D component number

Output 1 component number








Navigation

Parameter navigation and adjustment on the DNA Pro is very straightforward. There is no concept of drilling down deeper into hidden menus; every parameter is accessible by simply scrolling across a

‘map’ of parameter pages which can be thought of as placed on a 2-‐dimensional grid. Horizontally across the width of the grid are the various channels, and vertically up and down the grid are the parameter pages for each section of processing.

To view a parameter, repeatedly press the desired < INPUT > or < OUTPUT > channel button until the desired channel is reached. Then repeatedly press the up < p > and down < q > buttons to scroll through the processing parameters for the selected input/output.

Two encoders allow you to select and adjust a parameter. Often, several parameters will be shown in various zones on the display. To select a parameter for adjustment, turn the right-‐most encoder such that the parameter you wish to adjust is highlighted. Then turn the leftmost encoder to adjust the value of that parameter. Turning this encoder clockwise will increase the value of a parameter, or anticlockwise will decrease it. The encoders are velocity-‐sensitive so turning an encoder rapidly will cause the action to ‘accelerate’, so the value changes more rapidly.

Turn the SELECT encoder to highlight the zone you wish to adjust.

Turn the ADJUST encoder to change its value.

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The Home Page

The Home Page presents an overview of the configuration of the device. It indicates the user-‐define

Device Name at the top, and shows the four Drive Modules . In each Drive Module the top line shows the Input DSP channel (‘A’, ‘B’ etc), and the name the user has given to this channel. The bottom line shows the physical input number, and a list of the outputs which are routed from the Drive

Module.

Device Name DSP Input

Input Name

Drive Modules

Physical Input Outputs assigned

The DNA Pro uses Drive Modules to represent loudspeaker sub-‐systems. Drive modules result in a less processor-‐centric and more speaker-‐orientated system design. A drive module is defined as the processing provided by one Input DSP, and a number of outputs, which are associated with one-‐ another by means of routing. For example, if Input DSP B is routed to outputs 3 and 4, then this is a

2-‐way Drive Module; input DSP B forming the ‘master’ control, and output DSP 3 and 4 providing the driver-‐related control. The Input DSP parameters then control the Drive Module (and thus the speaker sub-‐system). The Drive Module control panel in the PodWare application is then used for control and monitoring of this sub-‐system.

Drive Module Presets

Presets do not change the settings device-‐wide. Rather, recalling a Module Preset creates a Drive

Module by ‘consuming’ a number of consecutive outputs and setting up routing between the Input the preset was recalled on and those outputs. The parameters in that Drive Module are then set according to the parameters in the components in the Module Preset.

Note however, that modules with non-‐consecutive outputs can be created by manually manipulating the routing, and then recalling Component Presets to the individual outputs. The resulting system can then be stored in a Snapshot . Such a Module cannot be saved in a Module Preset.

Note: When a Module Preset Recall consumes outputs to construct a module, it treats a pair of

Bridged outputs as a single channel, so recalling a 2-‐way Module Preset will consume 3 output channels if a Bridged pair is encountered. See Bridge Mode

Note: DSP inputs are not the same as physical inputs. The DNA Pro has four audio inputs and four

DSP inputs. This is a matrix mixing system where any physical inputs, be they analogue, AES3 or networked audio feeds, can drive any number of DSP inputs.

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Component Presets

A Component Preset represents the processing for just one output. Any part of a Module Preset may be recalled to any one output. A Drive Module comprised of parameters which have been recalled to its outputs using Component Preset Recalls can then be saved into another Module Preset provided the outputs remain consecutive (i.e. you have not changed the routing manually). If the routing has been changed manually, then the whole arrangement may be saved into a Snapshot . Also see

Snapshots and Recalling Components .

Factory Module Presets

The device may contain a library of Factory Presets designed to suit a range of enclosures.

Factory Presets may contain some parameters that are fixed and hidden from view; the remainder of the parameters are available for user manipulation. The number and type of hidden parameters is dependent on the Factory Preset, typically crossover frequencies, output delay and some EQs are hidden; those settings that are a function of the loudspeaker cabinet design and should not require adjustment for different applications. Factory Presets are locked (as indicated by a ‘box’ symbol after the Preset name) so they cannot be over-‐written. The user can, however, store an edited version of a Factory Preset in any free preset location.

In addition to the Factory Presets the device may have further ‘ Skeleton Presets ’ which will help to create new presets. They can be used to develop settings for any loudspeaker combination and are recalled in the same way as the Factory Presets described above. These Presets are also usually locked but the user can name and store their own edited versions in any free preset location.

Storing Module Presets

Once a drive module has been created it can be stored by pressing the < INPUT > button until the edited channel is reached, then pressing the down < q > button until store page is reached. Using

“ADJUST” encoder will change the preset number. When the destination preset is reached, pressing the < ENTER > button will enable the name associated with that preset to be changed. Once the name changing is active, the character to be changed will be highlighted and the “ADJUST” encoder will edit the character. Using the “SELECT” encoder will move through the character positions. Once the new preset name has been assembled, the operation can be confirmed by pressing the < ENTER > button, then a message will be displayed, “Enter to confirm or q to exit”; pressing < ENTER > will store the preset.

A STOR Preset

SUBS 40

Name

2 X 18 BASS

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Note: Storing a Drive Module preset for a module which is not configured with consecutive outputs is not permitted.

Note: When storing a Drive Module preset on the device, Component Names cannot be edited. To change Component names, the Module Preset must be saved in the PodWare application.

Recalling Module Presets

To recall a Drive Module preset, press the < INPUT > button, then use the down < q > button navigate to the RECL Preset page. Using the “ADJUST” encoder will scroll through the presets available. When the desired preset is reached, pressing < ENTER > will display the message “Enter to confirm or q to exit”, pressing < ENTER > will recall the preset. Note that presets do not contain and do not disturb parameter Overlays. See Overlays

A RECL Preset

SUBS 40

Name

2 X 18 BASS

Recalling Components

To recall a Component Preset (to a single output), press the < OUTPUT > button, then use the down

< q > button navigate to the RECL Preset page. Using the encoder, “ A ” will scroll through the component presets available (as indicated by the ModulePreset.Component number and

ModulePreset.Component name). When the desired component is reached, pressing < ENTER > will flash the Enter button. Pressing < ENTER > again will then recall the component preset. Note that component presets do not contain and do not disturb parameter Overlays. See Overlays

A RECL Comp

SUBS 40.2

Name

SP28.Mid

Also see Snapshots .

Input

AES3 Inputs

In addition to the usual analogue inputs, the Device can also accept AES3 digital inputs. When a DSP input channel is assigned to an AES3 channel, the “AES3” indicator will illuminate.

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There is no ‘standard’ for the relative gains between Analogue and AES3 so depending on the levels delivered by the audio source, it may be necessary to adjust the digital input gain trims to normalise them. It is possible to adjust the gain of the AES3 input using the Input Route AES3 Gain parameter.

For example, to achieve 0dBFS = +18dBu, set the AES3 trim to -‐2dB. To achieve 0dBFS = +24dBu, set the trim to +4dB.

This device will automatically lock onto any sample rate within the range 28kHz and 108kHz.

Networked Audio (Dante) Inputs

When the Digital Audio Network option is fitted, it is possible to select any channel(s) as being sourced from this network. To do this, connect the audio network connection to the connection on the rear of the Device, and set the relevant Input Route menu Source parameter to “Dante” (for example.)

When the Digital Audio Network input is installed and routed, the “Net Audio” indicator above the encoders will illuminate. This indicator will come on even if there are no cables plugged into the networked audio port on the Device.

As for the AES3 inputs, it is possible to set the relative gain between an Analogue input and the signals sourced from the Digital Audio Network using the Input Route Dante gain parameter.

The amplifier will automatically select the correct sample rate from the incoming stream.

For other details on the operation of the Digital Audio Network, please refer to the relevant manufacturer’s documentation.

Gain and Polarity

The gain page of the input channel selected allows users to increase or decrease the amount of signal going into the selected input. Using the “SELECT” encoder to highlight the Gain value allows the value to be changed by the “ADJUST encoder in 0.2dB steps from -‐40dB to +20dB. The presence of an active Group Overlay parameter is indicated by the ‘[]’ symbol (See Overlays ). This page will also allow users to change the polarity of the selected input from normal to reverse. And to mute the selected channel.

Delay

The delay page which controls the amount of delay associated with the input channel selected and is adjustable from 0 to 998ms. The delay parameter is adjustable in fine steps at low values; the adjustment becomes progressively coarser as the value increases. The presence of an active Group

Overlay parameter is indicated by the ‘[]’ symbol. See Overlays .

High Pass Filter

System high pass filtering is provided for the input signal. Filter type is selectable from 1 st order,

Butterworth, Bessel, Linkwitz-‐Riley and Hardman. Filter slopes of up to 4th order or 24dB / octave are provided. Not all filter types are available in all slopes. For example 18dB / octave Linkwitz-‐Riley filters do not exist.

The Hardman type filter is always described by its order as the filter becomes progressively steeper rather than following a linear slope so a dB/octave description is not accurate.

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Parametric Equalization

There are nine stages of equalization available for each input channel, three shelving filters and six parametric filters.

FIR Shelving EQ

The Input High Shelf EQ is implemented using a Finite Impulse Response (FIR) filter, and exhibits a linear phase response; that is all frequencies are delayed by the same amount. This can be important in applications where different amounts of EQ are applied to different parts of a speaker cluster, such as to add high frequency EQ boost so that parts of cluster which are ‘throwing further’ can have

HF absorption correction added. If this EQ is not linear phase, then the zones where the speakers combine may suffer frequency response anomalies.

Because the Input High Shelf EQ is a FIR filter, it will necessarily introduce some latency (delay), which is constant regardless of the settings. However, when the ‘Enable’ parameter is set to “Off”, it is removed from the signal path entirely, so it does not add any latency. In this page you can change the frequency parameter from 2kHz to 20kHz, enable/disable the filter, and change the cut or boost in 0.2dB increments. The presence of an active Group Overlay parameter is indicated by the ‘[]’ symbol being appended to the Gain value (See Overlays ). The filter (and its associated latency) can be completely removed by setting the enable parameter to the “Off” position. Note that this EQ can only be used in Module Groups if set to ‘On’.

Also see Latency Delay .

Parametric Filters

Parametric filters are defined by frequency, bandwidth and gain. The frequency is adjustable over the range from 10Hz to 25.6kHz. The bandwidth shown as Width on the screen, ranges from 0.10 octaves to 5.2 octaves. Bandwidth can be shown and adjusted as Q or Octaves (Oct). Gain is adjusted in 0.2dB increments. The presence of an active Group Overlay parameter is indicated by the ‘[]’ symbol being appended to the Gain value. See Overlays .

Also see Bandwidth Units in Utilities.

Routing

Routing allows users to route any physical analogue or digital signal channel to any DSP input. This is effectively a matrix mixing system where all DSPs can be driven from any one input, or from pairs of inputs “ 1+2 ”, “ 3+4 ”, “ 1+3 ”, “ 1+4 ”, “ 2+3 ” or “ 2+4 ”. Summed inputs have 6dB of attenuation so that a sum of largely similar programme material remains at the correct calibrated level. When a sum input is selected, the input DSP meters show the higher of the two inputs so that indication of the onset of clipping of either input is indicated.

Output

Gain and Polarity

The gain page of the output channel allows users to increase or decrease the relative signal gain for the selected output. The Gain value may be adjusted in 0.2dB steps from -‐40dB to +20dB. This page will also allow users to change the polarity of the selected output from normal to reverse.

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Delay

The delay page controls the amount of delay associated with the output channel selected and is adjustable from 0 to 998ms. The delay parameter is adjustable in fine steps at low values; the adjustment becomes progressively coarser as the value increases.

High and Low pass Filters

High pass crossover filtering is provided for the output signal. Filter type is selectable from 1 st order,

Butterworth, Bessel, Linkwitz-‐Riley, Hardman and LIR Linear Phase. Filter slopes of up to 8th order or

48dB / octave are provided. Not all filter types are available in all slopes. For example 18dB / octave

Linkwitz-‐Riley filters cannot be selected because they do not exist.

The Hardman type filter is always described by its order as the filter becomes progressively steeper rather than following a linear slope so a dB/octave description is not accurate.

LIR Crossover Filtering

Unique to Danley Sound Labs, “Linear Impulse Response” (LIR) crossover filtering gives a Linear

Phase crossover which has a constant delay regardless of frequency (unlike other types of crossover which delay different frequencies to a different extent, thus smearing the arrival time). The LIR crossover can thus be described as having a flat Group Delay response, and thus entirely free of

Group Delay Distortion, this is exactly the same as can be provided by common FIR filtering but without the complications and disadvantages inherent with the FIR technique.

The shape of the LIR crossover filter is similar to a 4 th order Linkwitz-‐Riley filter, and maintains zero phase difference between the adjacent bands across the crossover region to keep the polar response consistent.

Linear Phase filtering necessarily introduces delay; the laws of physics demand it. To keep this delay to a minimum, it is recommended that more conventional crossover shapes (such as Linkwitz-‐Riley) are used for the very lowest frequency high-‐pass edge, particularly if this is less than perhaps 100Hz, which is well below the frequency thought to cause audible ‘Group Delay Distortion’.

This constant delay will depend on the lowest high-‐pass frequency used in the crossover filters in a given Drive Module.

Also see the section on Latency Delays .

Parametric Equalization and All-‐Pass Filters

There are ten different EQ filters; two shelving filters and eight parametric filters. Parametric filters are defined by frequency, bandwidth and gain. The frequency is controlled over the range from 10Hz to 25.6kHz. The bandwidth, shown as Width on the screen, ranges from 0.10 octaves to 5.2 octaves.

Bandwidth can be shown and adjusted as Q or Octaves (Oct). Gain is adjustable in 0.2dB increments.

Any of the six Parametric filters can be used as All-‐Pass filters. When a filter is set to All-‐Pass mode, the Gain parameter value will show as “AllPass” on the display. This setting may only be engaged or disengaged from the PodWare PC application.

Also see Bandwidth Units in Utilities .

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Limiters

The DNA Pro includes three limiters in the output signal path. Please note that while the Limiters in this product offer protection for amplifiers and drivers, they can never protect from all possible scenarios, therefore Danley Sound Labs is not responsible for any damage which might occur.

VX Limiter (Unique to DNA Pro series )

This is a peak-‐detecting signal limiter. The VX Mode parameter determines the style of limiter. When

Virtual Crossover (VX) mode is off, the limiter is controlled in a conventional manner; the only controls being Threshold and Overshoot.

The Overshoot limiter prevents the signal from exceeding threshold during the attack phase of the main limiter by more than a predetermined amount. The optimal Overshoot setting is usually about

8dB. Lower Overshoot settings will sound progressively ‘harder’.

When VX mode is engaged, the user can choose the crossover point of a ‘virtual crossover’, which incorporates two limiters per output so the user can individually limit the drivers in a passive 2-‐way enclosure using individual thresholds, and optimised attack and release characteristics for each. The

Threshold of the second ‘Hi’ limiter is set relative to the threshold of the first ‘Lo’ limiter.

The effect of the VX threshold and split frequency on the Limiter curve can be seen in PodWare.

This Limiter introduces some delay. In non-‐VX mode, this delay will depend on the lowest high-‐pass frequency used in the crossover filters in a given Drive Module. In VX mode, the delay is related to the Split frequency. This delay will be applied to all of the outputs in a given Drive Module to keep them in phase.

Also see Latency Delays

Tmax Thermal Limiter

The Thermal Limiter is intended to protect the driver against damage due to over-‐heating. It models the temperature of the driver, and constrains the output signal level in order to keep the average output power below a predetermined limit, applying attack and release characteristics to go some way towards modelling the complex thermal circuit of a driver’s voice coil and magnet assembly.

Three parameters are available for adjustment:

Threshold – the continuous RMS voltage which the driver should be able to withstand. This is calibrated at the output of the amplifier. The Thermal Limiter can be defeated by setting the

Threshold to the maximum “Off” value.

Attack – The time-‐constant of the speed at which the driver heats up (in seconds).

Release – The time-‐constant of the speed at which the driver cools down (expressed as a multiple of the Attack time).

Xmax Excursion Limiter

The Excursion Limiter protects the driver against excessive linear movement of the cone and voice-‐ coil which could otherwise cause mechanical damage. Since this movement (excursion) is largely related to the inverse of the signal frequency, drivers are prone to being damaged by very low frequencies. This limiter is progressively more sensitive at lower frequencies and, rather than varying the gain to provide the limiting action, it uses a sliding high-‐pass filter to progressively curtail the

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low-‐frequency response, effectively limiting the linear excursion to below the X-‐max specification of the driver. To set the limiter up, it is necessary to know the shape of the family of Excursion vs.

Frequency curves of the driver for various drive voltage levels. A curve should then be chosen where the slope is high where it passes though the specified X-‐Max value for the driver. The peak voltage and frequency of this point should then be noted.

The Xmax limiter is usually then set up using just two parameters:

Threshold – the peak voltage of the point arrived at above. This is calibrated at the output of the amplifier. The Excursion Limiter can be defeated by setting Threshold to the maximum

“Off” value.

Frequency – The frequency at which the above threshold voltage is appropriate.

A further parameter “ Min ” may also be available for more advanced applications. This allows the increasing limiting action at lower frequencies to level-‐off below a certain frequency. In most application, this would be left set to its default value of 5Hz.

Bridge

When an amplifier pair is set to Bridge Mode, it uses two amplifier channels to drive one loudspeaker with greater power. In this mode, only one set of Output controls is active per pair of amplifier channels since both of the amplifiers in the pair are driven with the same signals, as determined by the channel 1 (or channel 3) controls. Bridge settings should be set up before recalling Drive Module Presets . Module Preset Recall will see a bridged pair of outputs as a single channel. Bridge Mode is enabled or disabled in the AMP page for a given odd numbered Output.

When enabled, the Bridge indicator will be illuminated between the bridged channels.

Routing

Outputs can be driven from any DSP input. This routing is the fundamental means by which Drive

Modules are created. Routing should always consume outputs consecutively alphabetically and numerically. However, non-‐consecutive Drive Modules may be created using manual routing and

Recalling Components . See the drive module section of this user manual for more information.

Utility Pages

Screen Contrast

The Screen page in the “ UTILITY ” section adjusts the contrast (and optimal viewing angle) of the screen from 0-‐100% in 1% increments.

Stereo Linking

Stereo linking is available between DSP Drive Modules A & B and between C & D. Changing a parameter in either of the stereo linked Drive Modules will change the other linked Drive Module.

Stereo linking is controlled by the STEREO page in the “ UTILITY ” menu.

Note: Stereo linking will only work when the linked Drive Modules are of equal size.

Current Ethernet IP Address

This may be viewed in the “ IP Curr ” page of the “ UTILITY ” menu. This value cannot be edited.

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IP Mode

The Ethernet IP address may be automatic “ Auto ” or may be a fixed static value “ Static ” as determined by the “IP Mode” page of the “ UTILITY ” menu.

WARNING – Do NOT use Static mode unless your IT system specifically requires it. Auto mode should always be used where possible since in this mode, the Device can always be ‘discovered’ by the PodWare application. When in Static mode, the IP Address will flash on the Home screen.

Also see Ethernet Configurations .

IP Static

This allows the Static Ethernet IP address to be adjusted by the three rotary encoders on the IP Static page of the “ UTILITY ” menu. This will only have effect when in Static mode.

Store Snapshot

This page of the “ UTILITY ” menu allows a Snapshot of the device to be stored.


Recall Snapshot

This page of the “ UTILITY ” menu allows a Snapshot to be recalled.

Also see Snapshots and Aux Port .

Bandwidth Units

This page of the “UTILITY” menu allows the Bandwidth of Parametric Equalizers to be viewed and adjusted in either Octaves or ‘Q’.

Aux Style

This page of the “ UTILITY ” menu allows the action of the Aux port to be viewed and adjusted.

Also see Aux Port .

ECO

This page of the “UTILITY” menu allows the device to save power by going into a low power mode when it is not being used.

Standby is a fast mode which saves some energy, but will wake-‐up very quickly if an audio input is detected. The associated Standby Time parameter allows the amplifier to automatically go into power-‐save if no audio signal has been detected for a period of time. This function can be defeated by setting the latter control to Manual. Linea would strongly advise leaving it set to automatic however as there is no negative consequence to doing this since ‘wake-‐up’ on detecting the presence of an audio input signal is instantaneous.

The Standby Now ‘parameter’ allows the amplifier to be put into standby mode manually when it is not being used.

Sleep is a deep power save mode which saves the most energy, however it will take a small number of seconds for the amplifier to wake-‐up, and it may only be woken up manually (either from the

PodWare application or by switching the device off then on again). The associated Sleep Time

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parameter allows the amplifier to automatically go into Sleep mode if no audio signal has been detected for a period of time. This function can be defeated by setting the latter control to Manual.

External Breaker Protection (EBP)

The Power (“PWR”) utility page provides access to the External Breaker Protection (EBP) feature, which allows the output power to be limited in order to prevent the nuisance tripping of mains circuit breakers or fuses when the amplifier needs to be operated on a mains supply with restricted capacity. Set the EBP value to that of the circuit breaker or fuse to which the amplifier is connected.

Ethernet

Ethernet configurations

IP addressing in the Device can be completely automatic; No setup is required.

When first installing and launching PodWare, the computer Firewall may ask to allow PodWare to access the network . NOTE: This must be allowed .

DHCP

There are two primary IP address ranges – one used when there is a DHCP server, and another (‘Link

Local’) where there is no DHCP server (so the Device and the Computer will instead use 'Auto IP' to allocate themselves an IP address). Both the device and the computer must be in the same IP address range. In a local network environment such as an office where there is a DHCP server, both the computer and the Device will be in the DHCP IP address range, and so will connect immediately.

AUTO-‐IP

The device will initially search for a DHCP server when first switched on (during which time its Online

Indicator will be flashing). As it can take up to one minute to establish that there is no DHCP server available, this is the time it may take before Auto IP is entered.

Please be aware that it can also take some time from a computer being switched on in an isolated network (without a DHCP server), or unplugged from a network with DHCP to time out of DHCP searching, so it will not connect immediately to amplifiers that are already using Auto IP. The time it takes before it decides to revert to Auto IP depends on the operating system but it can take several minutes to acquire an Auto IP address.

Static-‐IP

If the device or the computer has a static IP address set, PodWare may not be able to 'see' the device if it is in a different IP Address range (i.e. in a different subnet ). Unless there are good reasons it is best to avoid the use of static IP addressing if at all possible.

IP Troubleshooting

If PodWare cannot connect to the device:

•

Check that the Firewall in the computer will allow PodWare access to the network.

•

If there is no Router in the system acting as a DHCP server, wait 10 minutes (for the computer to acquire the correct IP address) and try again.

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Check that the Current IP address in the device is compatible with the IP address of the computer.

Generally, the leftmost two sets of 3 digits should be the same.

Always switch on any DHCP server before connecting either the computer or amplifier to the network.

Snapshots

A Snapshot may be recalled either via the device User Interface, from the PodWare application or via the AUX port on the rear of the Device.

The snapshot menu is accessed via the utility pages. Recalling a Snapshot triggers the recalling of a

Component to each input and output, and may change other device-‐wide settings, effectively recalling a processor-‐wide preset. In addition to being able to recall snapshots from Podware and from the Device's front panel, some of the snapshots are also recallable from the auxiliary port.

Also see Aux Port

The parameters inside the Drive Modules are not individually stored in Snapshots. Recalling a

Snapshot will merely trigger the recall of the appropriate Input and Output Components, rather than restoring the parameters that were active when the Snapshot was stored. This has the distinct advantage that the library of OEM presets may be updated without having to be concerned about what parameters might have been saved in users Snapshots. It does however require that any existing edits to the parameters in Drive Modules are stored into Drive Module presets before a

Snapshot is stored.

Also see Overview Of Modules Components and Snapshots

AUX Port

The AUX has two inputs, X & Y. These allow simple contact closure devices (relays or switches) or external logic signals to change the state of the amplifier as described below. Connecting an AUX input to ground (the earth symbol) will trigger it; there is no requirement for an external voltage.

However, the ports can also be triggered directly by a logic signal as long as the logic ‘low’ goes below +0.5V. Do not connect systems if their logic ‘high’ voltage exceeds +24V.

The AUX port may be configured to work in a number of ways by adjusting the Style parameter in the Aux page of the Utility menu :

•

None -‐ No operation

•

2+Mute (Event or State) – Either Snapshot 1 or Snapshot 2 may be recalled by applying a momentary or static connection to an Aux port terminal, or the device may be muted by

Grounding both Aux port terminals

•

3 Snaps (Event or State) – Either Snapshot 1 or 2 or 3 may be recalled by applying a momentary or static connection pattern to an Aux port terminals

•

4 Snaps (State) – One of the four Snapshots 1,2,3,4 may be selected by applying a static connection pattern to the Aux port terminals

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• 3+Mute (State) -‐ One of the three Snapshots 1,2,3 may be selected by applying a static connection pattern to the Aux port terminals, or the device may be mute by Grounding both

Aux port terminals

The following table shows the action taken for various Aux connection patterns in the various Aux port modes:

AUX X AUX Y 2+Mute ACTION 3 Snaps ACTION 4 Snaps ACTION 3+Mute ACTION

(State or Event) (State or Event) (State) (State)

Open Open No Change No Change Recall Snapshot 1

Gnd Open Recall Snapshot 1 Recall Snapshot 1 Recall Snapshot 2

Recall Snapshot 1

Recall Snapshot 2

Open Gnd Recall Snapshot 2 Recall Snapshot 2 Recall Snapshot 3

Gnd Gnd Mute Recall Snapshot 3 Recall Snapshot 4

Recall Snapshot 3

Mute

Some of the above modes allow the AUX Port to be used either in Event mode (whereby a momentary push-‐button or momentary relay contact closure on one of the AUX lines will cause a

Snapshot to be recalled). Or in State mode (where a rotary switch etc. connected to both of the AUX lines selects which Snapshot to use).

Some of the other modes only allow State mode, requiring the connection pattern to persist in order for the Snapshot to be held as the current one.

NOTE: That if the contact closure port is being driven, or if the Aux Style is set to one of the State modes, this will override the snapshot recall setting in the menu (or in PodWare). Also under these conditions, the snapshot menu items are not accessible, and the Home screen will show the

Snapshot number as a reminder.


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Latency delay

All Digital Signal Processing, and conversion between different formats of signal – analogue/digital/network etc., necessarily introduce some delay (latency) to the signal path. Of course, we strive to minimise these latencies. Small as they are, it is sometimes useful to know their precise values. The following describes the principal latencies introduced by various parts of the

Device product:

Input/Output Latencies

Analogue Input 0.385ms

OR Digital input at 96KHz sample rate 0.5ms

OR Digital input at 48KHz sample rate 0.66ms

Analogue Output 0.402ms

OR AES3 Output 0.1ms

OR Dante Output 0.5ms (TBC)

Processing Latencies (limited to a minimum of 1.53ms):

Input HiShelf FIR 0.6ms (0ms if set to ‘Off’)

LIR Linear Phase crossover 1.19ms/Fhp(kHz), limited to 30ms maximum **

VxLim Limiter (VX mode off) 0.12ms/Fhp(kHz), limited to 1.53ms maximum **

OR VxLim Limiter (VX mode on) 0.358ms/Fsplit(kHz), limited to 1.53ms max 

** This latency figure is calculated using the crossover High-‐pass frequency (in kHz)

 This latency figure is calculated using the Vx Split frequency (in kHz)

Important tip: The processing latency is constant at 1.53ms unless LIR crossover filters or FIR HiShelf

EQs are used, so normally you would just need to add the Input and Output delays to this constant value.

If LIR or FIR are in use, the Processing latency of a Drive Module may increase beyond this figure. The

Drive Module Latency may be viewed on the Latency page of the relevant Input DSP channel. This can be accessed by pressing Input then down until the latency page is reached.

When LIR, is used the Vx Limiter can take the overall latency above the 1.53ms. When high pass frequency is set below 40Hz the filter will automatically revert to Linkwitz riley, this is set so that the latency will not exceed 30ms as stated.

Note that the latency reported on the Latency screen in the utilities menu does not include the

Input/Output latencies.

When using input FIR filters, LIR or VX Limiters always check the view latency screen to see the latency attributed to that Drive Module.

36

Example:

Input/Output

Analogue Input

Analogue Output

Processing

0.385ms

0.402ms

Input HiShelf FIR (Off) 0ms

LIR Linear Phase crossover (500Hz) 2.38ms

VxLim Lim (VX mode on, 1KHz Fsplit) 0.358ms

Total 3.525ms

Note that the latencies within a Drive Module are equalized among outputs of that Drive Module.

That is, padding delay will be automatically added to some outputs such that the total latency is the same in each output of a Drive Module.

This latency equalization does not extend outside a Drive Module, so Drive Modules are not guaranteed to have the same latency as one-‐another.

Secure Mode

When activated, this will disable all the front panel controls so they cannot affect the signal path, making the unit secure against tampering. The only option that is left for user control is snapshot recall. If this is not required then storing the same device state in every snapshot will effectively disable this feature. When in secure mode, the indicators still operate normally. To activate secure mode, press and hold the utility button for 5 seconds. To deactivate, press and hold the utility button for 5 seconds. When in secure mode, this will be shown on the display. Note that the

Ethernet communications port is still active in secure mode.

Overlay Flush

If the device has been used in Module Groups, and still has an active Overlay (as indicated by the

Overlay indicator), these can be removed by simultaneously pressing and holding for 5 seconds the

Utility and Enter buttons. See Overlays .

Protection Systems

Comprehensive protection features preserve the longevity of the loudspeaker and amplifier by continuously monitoring several critical parameters, and reducing the gain, or muting the amplifier either temporarily or permanently depending on the nature and seriousness of the fault or misuse.

The amplifier will recover and restart if at all possible, but may remain in shut down if a serious fault persists.

Limiters deal with routine over-‐driving of the amplifier, making sure that the driver(s) are not pushed too hard. The limiter indicators will warn you when the driver is being driven into limit.

Minor faults are dealt with by ‘dimming’ the amplifier, reducing the level to a sufficient degree and for a sufficient time that the amplifier is able to recover gracefully without any user interaction.

When the fault condition has passed, the amplifier will recover automatically.

37

When the protection systems are reducing the level, this is indicated by illuminating the left-‐hand

Amplifier channel protection indicator. This will also illuminate when the output voltage is ‘clipping’.

This indicator will remain permanently illuminated if the channel has been muted by the protection systems. The Mute button will also flash. This will usually also be indicated by a warning message on the display.

Some types of protection affect all output channels, so you may see the Amplifier indicator illuminated, and the Mute button flash, on every channel.

Incident Reporting

In the PodWare application, a coloured indicator appears on a Device Bar in the System View which displays the Incident state of the device. The Incident state may be one of three states:

•

Red: Fault (The device is faulty in some way and requires attention)

Yellow: Check (The device may not be performing to its full and should be checked)

•

•

Green: OK (The device is performing well and requires no attention)

Holding your mouse over the Incident indicator for a few seconds will show the current incident level and name.

If an incident is reported you can disable it, and all less serious incidents, by right clicking the bar in

System View and selecting ‘Enable/Disable Alarms’. Doing this will show a cross over the Incident indicator and the device will no longer report any Incidents at this level or below.

If any Incidents have previously been disabled they can be enabled by using the right click context menu and selecting ‘Enable/Disable Alarms’ again.

Any active incident will be shown on the display of the device.

A Fault state will also cause the Fault Relay to open. See Fault Relay

Fault Relay

Three connections are available via the Phoenix connector for this relay. The schematic representation printed on the rear panel shows the ‘idle’ state of the relay (when the amplifier is not switched on). When the amplifier is switched on, the relay will normally energise. When a Fault incident occurs, the relay will be de-‐energised. This will allow either a Fault Incident or a loss of

power to be seen as a ‘Fault’.

Also see Incident Reporting

Performance Logging

The PodWare application allows you to inspect various performance measurements, including various graphs of performance against time, recording events over a period of up to three days.

Since the amplifier cannot record any events while powered-‐off, breaks in a log due to power-‐downs are indicated by a break symbol || in the log.

The events recorded are:

Supply Current -‐ How much current is being supplied to the device via the mains inlet

DC Link Voltage – A voltage which is derived from the mains supply voltage

38

Thermal Capacity – How much of the available thermal capacity has been used

Driver Current (for each output) – The average current being delivered to the driver

Driver Impedance (for each output) – The average impedance of the driver

Protection Limiting (for each output) -‐ How much the amplifier is ‘dimming’ itself in order to protect itself from potential damage

The data in the log can be exported by right-‐clicking on the log to launch a context menu, and selecting “copy log data to clipboard”. The data could then be pasted into a spread sheet for further analysis. Your dealer may ask you to do this is you have experienced a problem.

Alternatively, all of the operational and performance data, including the logs may be collected together into a single file by selecting File > Save Device Diagnostics. Your dealer will be able to read and interpret this data.

39

Processing Block Diagram

40

Input Menu Map

CH A CH B

IN

RECL

STOR

IN

ROUT

LATEN

EQa\

HPF

DEL

GAIN

EQ3

EQ 2

EQ 1

EQb\

FIR/

EQ6

EQ5

EQ4

RECL

STOR

IN

ROUT

LATEN

EQa\

HPF

DEL

GAIN

EQ3

EQ 2

EQ 1

EQb\

FIR/

EQ6

EQ5

EQ4

CH C

CH D

RECL

STOR

IN

ROUT

LATEN

EQa\

HPF

DEL

GAIN

EQ3

EQ 2

EQ 1

EQb\

FIR/

EQ6

EQ5

EQ4

RECL

STOR

IN

ROUT

LATEN

EQa\

HPF

DEL

GAIN

EQ3

EQ 2

EQ 1

EQb\

FIR/

EQ6

EQ5

EQ4

Utility Menu Map

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

STATIC IP

UTIL

IP CURR

STEREO

POWER

SAVE

EBP

SCREEN

AUX

STYLE

EQ BW

SCREEN

RECAL

SNAP

HOME

KEY

MENU PAGE

MENU BUTTON

CHANNEL NO.

UP/DOWN BUTTON PRESS

MENU BUTTON PRESS

41

OUT

Output Menu Map

CH 1 CH 2

DEL

GAIN

RECL

ROUT

EQ 3

EQ 2

EQ 1

EQ \

LPF

HPF

LIM

TMAX

XMAX

AMP

EQ /

EQ 8

EQ 7

EQ 6

EQ 5

EQ 4

DEL

GAIN

RECL

ROUT

EQ 3

EQ 2

EQ 1

EQ \

LPF

HPF

LIM

TMAX

XMAX

AMP

EQ /

EQ 8

EQ 7

EQ 6

EQ 5

EQ 4

CH 4

DEL

GAIN

RECL

ROUT

EQ 3

EQ 2

EQ 1

EQ \

LPF

HPF

LIM

TMAX

XMAX

AMP

EQ /

EQ 8

EQ 7

EQ 6

EQ 5

EQ 4

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

HOME

CH 3

DEL

GAIN

RECL

ROUT

EQ 3

EQ 2

EQ 1

EQ \

LPF

HPF

LIM

TMAX

XMAX

AMP

EQ /

EQ 8

EQ 7

EQ 6

EQ 5

EQ 4

42

EQ and Filter Response Graphs

43

44

45

46

Technical Specifications

General

Number of channels

Total power output

DNA 20K4 Pro model

DNA 10K4 Pro model

Input types

Control, monitoring & alarm

Energy saving modes

System sleep and wakeup

Four

20,000 Watts RMS

10.000 Watts RMS

Analog, AES3 (Dante as model option)

Ethernet, configurable function Volt-free relay and contact closure port

Standby and deep ECO sleep both with auto-sleep timers

Front panel switch, network command, contact closure and audio detection

40degC (105degF) Max ambient temperature (full power, no audio limiting)

Audio

Amplifier topology Proprietary 5th generation Class D.

Amplifier modulation scheme

Output power per channel continuous program material at a crest factor of 4 (12dB)

Output power per channel all channels driven all channels driven

with

with continuous program material at a crest factor of 2.8 (9dB)

L ow feedback, multiple loop, with feed forward error correction.

20K4 - 5000W RMS into 2 Ohms.

(10000W RMS into 4 Ohms bridged).

10K4 – 2500W RMS into 2 Ohms






20K4 - 1,300W RMS into 8 Ohms.


Output power per channel all channels driven with continuous program material at a crest factor of 2 (6dB)

Output power per channel all channels driven with continuous program material at a crest factor of 4 (12dB)



20K4 - 5000W RMS Hi-Z, 70V and 100V line.

10K4 - 2500W RMS Hi-Z, 70V and 100V line.

Dynamic range (analog input to speaker output) >113dBA typ.

Dynamic range (AES3 or Dante input to speaker output) >114dBA typ.

Frequency response

Total harmonic distortion, THD

Inter-channel crosstalk (worst combination of channels)

Maximum analog input level

Analog input sensitivity range for full output

Analog input

+/- 0.5dB, 5Hz to 20kHz, 4 Ohms.

-2.5dB, <3Hz to >30kHz, 4 Ohms.

<0.05% typ, 1kHz, AES17, 4 Ohms. better than -85dBr at 1kHz. better than -75dBr at 10kHz.

+20dBu.

0dBu to +20dBu, continuously adjustable.

20k Ohm, electronically balanced.

47

Analog link

Analog ground scheme

AES3 input

AES3 link

AES3 supported sampling rates

Directly connected to the analog input.

AES48 standard compliant.

Transformer isolated with active cable equalization for extended range (unique to Linea).

Active AES3 signal regeneration with automatic direct bypass to the AES3 input if the unit is unpowered.

24kHz to 192kHz (auto locking).

Digital processing

Resolution

Sample rate

Special functionality:

Class leading limiter suite

Hardman crossover filters

LIR crossover filters

FIR Shelving EQ filters

Overlays

40 bit, using proprietary LMD (Linea-Micro-Detail) algorithms.

96kHz throughout.

See the ‘speaker protection systems’ section.

Better out of band rejection than Linkwitz-Riley (Unique to Linea).

Linear Phase without the compromises of FIR filters (Unique to Linea).

For linear phase filtering.

Twelve additional independent overlays of EQ, Delay and Gain.

Power supply

Topology (main power supply)

Topology (auxiliary and standby supplies)

Internally stored energy

Mains input voltage range (automatically configured)

Mains input frequency range

Mains inrush current (max for <10ms)

Protection systems

3rd generation Series Resonant.

Low quiescent Eco-Flyback.

>600 Joules.

85V to 240V.

47Hz to 63Hz.

6A at 115V, 12A at 230V.

Note : Under all circumstances the control and protection systems will endeavor to deliver the maximum power possible for a given set of conditions, applying limiters only in extreme circumstances. Muting will only occur when a dangerous situation is detected, normal operation automatically resuming when the condition clears.

System protection Speaker protection

Excessive output current Audio soft-clip limiter

Excessive power supply current

Excessive amplifier section temperature

Excessive power supply section temperature

VxLim, Multiband peak limiter

VxMax, Multiband overshoot limiter

Vx-Xmax, Driver excursion limiter

Excessive DSP section temperature

Mains voltage out of range

Fan speeds out of range

Internal power rails out of range

Vx-Tmax, Driver thermal limiter

(long term power limiter)

DC offset protection

Excessive HF energy (VHF) limiter

48

Power distribution protection systems

Mains inrush current limiting (soft start and anti-surge).

Mains average current limiting (mains breaker / fuse trip protection).

Randomised initialisation when powered up to reduce the peak power demand in large systems.

Monitoring and logging

Supply current logged vs time

Supply voltage logged vs time

Thermal Capacity logged vs time

Each driver current logged vs time

Each driver impedance logged vs time

Number of power cycles counted

Number of mains brownout events counted

Fan speeds continuously monitored

Fan underspeed events counted

Various protection mute events counted

Protection limiting for each output logged vs time Driver Impedance continuously monitored

An inbuilt alarm and notification system can be configured to indicate problems to remote devices either via the network or the Volt-free changeover relay contacts accessibly on the rear panel.

Physical

Cooling

Airflow

Air filtration

Analog IN and LINK connectors

AES3 IN and LINK connectors

Audio output connector

Mains input connector

Dante Primary and Secondary

Relay output & contact closure inputs

Front panel display (backlit)

Front panel encoders

Front panel push buttons

LED indicators

Depth (behind rack ears)

Net Weight

Variable speed fans.

Front to back.

Washable media, changeable without the use of tools.

Genuine Neutrik XLR.

Genuine Neutrik XLR.

Genuine Neutrik Speakon.

Genuine Neutrik 32A Powercon.

Shielded RJ45.

Phoenix pluggable terminal block.

Graphical, high contrast, daylight visible.

Two, indented, velocity sensitive.

Large, tactile, illuminated.

Bright, easily differentiated. Enclosure Standard 19”

2U (88mm) with handles and optional rear support system

357mm (14”).

12.5kg (27.5 pounds).

Options

There is internal provision for digital audio network option cards to be factory fitted. Currently

Danley Sound Labs supports Dante from Audinate.

49

Danley DNA 10K4, DNA 20K4 User Manual

Danley Sound Labs

DNA Pro Series Advanced System Amplifiers

User Guide

For DNA 10K4 and DNA 20K4

Contents

IMPORTANT SAFETY INSTRUCTIONS

COMPLIANCE

Thanks and Unpacking

INSTALLATION INSTRUCTIONS

The User Guide

Introduction and Key Features

Audio Connections

Panel Layouts

Operation

Processing Block Diagram

Input Menu Map

Utility Menu Map

Output Menu Map

EQ and Filter Response Graphs

Technical Specifications

Options

Related manuals

Linea Research

44 Series

EM Acoustics

DQ6

Danley

DNA 5k4c