Sound Performance Lab 2595 One Coil per Filter, one Core per Coil, Allocation of Frequencies

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Operation

One Coil per Filter, one Core per Coil

Each Passeq filter is individually constructed for its intended frequency, that is, each coil, condenser and variable resistor (var. resistor=boost or cut control) ensemble is sonically tuned to its intended frequency range. Thus each filter has its own musically sensible audio color appropriate to its own frequency.

In turn, each coil is also wound on its own separate core to avoid mutual and degrading influ- ences which stem from past designs where multiple coils were wound on a single core. Not the least, the construction of each filter on its own particularly core also provides for excel- lent THD values.

Allocation of Frequencies

One of the greatest Passeq design challenges was in determining the choice of frequencies, which in contrast to parametric EQ designs, are fixed or nonadjustable. One could accept standardized values from such as the so-called ISO frequencies, but such measurements stem too much either from conventional measurement standards or those from room correc- tions rather than choices of what may be musically more sensible.In assigning the Passeq‘s frequencies it was inevitable that we would rely on the nearly 30 years of experience of SPL’s chief developer, audio engineer and musician, Wolfgang Neumann.

To enhance further our achieving this musical objective many audio experts and musicians were consulted regarding their favored frequencies. Among the many, David Reitzas, Michael Wagener, Bob Ludwig, Ronald Prent and Peter Schmidt offered valuable advice. From this point of departure we managed to determine that there is definite agreement among profes- sionals about their preferred musical frequencies, and these differ clearly from the standard ISO choices.

The results also showed that the closely meshed boost and cut frequencies are important and sensible. Through them one can on the one hand focus more precisely on a certain frequency, and on the other, offer the option of influencing the Q factor (which is typically rather small in passive designs) by creating so-called S curves. An Example: Assume you wish to boost in the mids around 320 Hz, an instrument or voice level while at the same time avoiding a boost to the frequency range below it due to the small Q factor (high bandwidth) of the filter, and perhaps even lower it. In this case, let’s say you choose the LMF-MHF boost band and increase the chosen (320 Hz) frequency range by about 3 dB. At the same time, you chose a 4 dB reduction in the LF-LMF cut band. The close proximity of the chosen frequencies allows you achieve an increase in the slope between the two. This is “S slope EQ-ing” at its best, and in this discipline, the Passeq is a world champion in both options and results.

Frequency Table/per Band

LF

LF-LMF

LMF-MHF

MF-MHF

MHF-HF

HF

Boost

Cut

Boost

Cut

Boost

Boost

 

 

 

 

 

 

Frequenz

Frequenz

Frequenz

Frequenz

Frequenz

Frequenz

 

 

 

 

 

 

10

30

220

1k

580

5k

 

 

 

 

 

 

15

42

320

1k2

780

6k

 

 

 

 

 

 

18

60

460

1k6

1k2

7k

 

 

 

 

 

 

26

95

720

1k9

1k8

8k6

 

 

 

 

 

 

40

140

1k3

2k4

2k5

10k

 

 

 

 

 

 

54

180

1k8

2k9

3k9

12k

 

 

 

 

 

 

80

270

2k3

3k5

5k2

13k

 

 

 

 

 

 

120

400

2k8

4k3

7k8

15k

 

 

 

 

 

 

180

600

3k3

5k

11k

16k

 

 

 

 

 

 

240

900

4k

6k

14k

17k

 

 

 

 

 

 

380

1k2

4k5

7k5

18k

18k

 

 

 

 

 

 

550

1k9

4k8

8k6

19k5

20k

 

 

 

 

 

 

12

Passeq

Image 12
Contents Manual Manual Passeq, Model SPL electronics GmbH SohlwegWeee Registration 973 349 88 Contents Important Safety Information Symbols and Notes Hook UpRack Mounting Special Features IntroductionAdvantages of Passive Filtering Passive Filters with 120 Volt Makeup AmplifiersFilter Types Single Core CoilsVolt Makeup Amplifiers SPL Supra Op-AmpsInput Stages of the Supra Components Intermediate Stages of the Supra ComponentsOther Features Lundahl TransformersConclusion Power switch and voltage Rear PanelIPU/% DPME   Selector Please refer toConnections OperationOne Coil per Filter, one Core per Coil Allocation of FrequenciesFrequency Table/per Band Boost Cut FrequenzCut LF-LMF Cut MF-MHF Cut MHF-HF Boost LF Boost HFOperational Elements LF-LMF Cut and LF BoostMF-MHF Cut and LMF-MHF Boost HF Boost Q Settings with the Proportional Q Principle MHF-HF Cut and HF BoostMHF-HF Cut Output ControlRecommendations on using Equalizers Basic Approaches and Working TechniquesEQ Yin & Yang First control levels, then apply EQ First cut, then boostReducing bleed within an instrument‘s frequency range Boosting harmonic frequency levelsCutting fundamental levels Emphasis of an instrument‘s main frequenciesMix-or not? Splitting frequency bands to reduce masking effectsImproves the presence of bass lines Classical instruments and their frequencies Basics of Frequency Filtering Frequency and EnergyTone and Sound Sound Correction and Sound DesignFrequency Filters Shelf FiltersPeak Filters BandwidthEqualizer Passive EQsActive EQs Parametric EQsGraphic EQs Power Supply SpecificationsGuarantee & Product Registration Copy Master Recall Settings Engineer Artist Tracks/Groups Album Date TitleManual Passeq

2595 specifications

The Sound Performance Lab 2595 is a cutting-edge audio processor designed to elevate mixing and mastering workflows for both professionals and enthusiasts alike. This device stands out in the competitive landscape of audio equipment, thanks to its blend of innovative technologies, high-quality sound processing, and user-friendly features.

One of the main features of the 2595 is its dual-channel architecture. This allows users to process two audio signals simultaneously, making it an ideal choice for stereo applications. Designed for flexibility, the device can be used for various purposes, including mixing, mastering, and live sound reinforcement. The 2595 boasts an intuitive layout, making it easy to navigate its range of functions and settings, even for those who may be new to audio processing.

The heart of the 2595 lies in its advanced digital signal processing (DSP) capabilities. The device is equipped with high-resolution converters, allowing for pristine audio quality with minimal latency. This ensures that the integrity of the original sound is maintained, which is a crucial aspect for any serious sound engineer or musician. Additionally, the built-in algorithms are designed to enhance the audio signal intelligently, providing users with options for dynamic range control, spectral processing, and various filtering techniques.

Another notable characteristic of the Sound Performance Lab 2595 is its extensive connectivity options. The device includes both analog and digital I/O, making it compatible with a wide range of audio sources and studio environments. This versatility is essential for professionals who often work with various formats and formats, ensuring that the 2595 can seamlessly integrate into any setup.

The user experience is further enhanced by the inclusion of a bright, user-friendly display that provides real-time feedback on processing parameters. This feature allows users to make precise adjustments quickly, facilitating a more efficient workflow. Furthermore, the 2595's robust construction ensures that it is built to withstand the rigors of both studio and live applications, making it a reliable choice for any audio professional.

In conclusion, the Sound Performance Lab 2595 represents a significant advancement in audio processing technology. With its dual-channel processing capability, high-quality DSP, extensive connectivity options, and user-friendly interface, it caters to a wide range of audio applications while maintaining exceptional fidelity and performance. This makes the 2595 a valuable tool for anyone looking to achieve professional-grade sound in their projects.