The
Passeq complements our parametric Equalizers Qure
and PQ 2050 by a
classic design with passive coil filters and perfectly
fulfills the highest expectations in all areas of
audio processing, from recording through mixing to
mastering.The superior sound qualities and musical
characteristics of passive filters ideally meet increasing
demands in creating manifold sound colors full of
character.
| Unique
Features |
• |
The
most powerful passive EQ ever made—144 (!)
passive filters (72 per channel) in one EQ |
• |
Individual
coils per filter |
• |
Single
core coils, which means that every one is wound
individually on its own dedicated core. This excludes
sonic degradation from mutual influences while
at the same time improving THD values |
• |
120V
makeup amplifiers based upon SPL unique SUPRA-OPs
with 150dB dynamic rage and 200 v/ms slew rate |
|
|
Special
Features |
• |
Individual
design and component specificity for each filter |
• |
Custom
made coils for critical mid-frequency ranges |
• |
Boost
and cut crossovers mesh perfectly so that with
the high number of frequencies one can dependably
command the most elaborate set of response curves
that to date any passive EQ has offered |
• |
Transformers
from Lundahl with perfectly matched sonic characteristics
provide for balanced I/O stages. |
| |
|
| Other
Features |
• |
XLR
contacts from Switchcraft. |
• |
Switches
and potentiometers from Elma and ALPS (including
ALPS “Big Blue” with 41 steps). |
• |
Internal,
linear power supply featuring a generously proportioned
toroidal transformer and voltage selection (110-120V,
60Hz or 220-240V, 50Hz) |
In
Detail
The
most powerful passive Equalizer ever made
With 72 passive filters per channel (36 x Boost, 36
x Cut), the Passeq surpasses all previous designs
of this type by a wide margin. Each channel is divided
into three Cut and three Boost bands, each offering
12 switchable frequency ranges. The Cut and Boost
ranges are not identical; crossovers are designed
to work with like a precise mechanic cogwheel so as
to allow the engineer access to the largest possible
number of optimal, wide-band S-curves with variable
slopes.
A further noteworthy Passeq feature is its individual
sonic adaptation of each inductive filter through
separate coil/condenser/resistor combinations: In
stark contrast to earlier filter design and construction,
each Passeq filter is optimized for the frequency
assigned.
To insure the best possible signal warmth, richness
and musicality in processing, coils for critical voice
frequencies are custom-made for the Passeq.
This achieves the widest possible range and tonally
appealing sound color palette from any passive EQ.
| Advantages
of Passive Filtering |
• |
Typically
coil inductance in virtually all active filters
is achieved through simulation. True passive coil
filters, on the contrary, can only deliver the
genuine, characteristic sound associated with
inductive components. |
• |
Distortion
elements typical of active filters are ruled out
by passive filter design. |
• |
For
any number of reasons stemming from design and
component advantages over active filters, passive
filters achieve a very natural aural quality and
through their harmonic treatment (THD, distortion,
phase response, etc.), offering at the very least,
a clear sonic alternative, which our ears often
perceive as an extremely attractive one. |
• |
All passive filter components (variable resistor,
capacitor and coil) work in concert to produce
this beautiful sonic result. An important part
of this process is played by coil saturation and
condenser loading characteristics. The resulting
difference in latency from characteristically
extremely fast reaction of active filters provides
for more pleasant, musical sonic qualities. We
tend to perceive these attributes in terms of
an increased suppleness and transparency, with
perceptibly improved, silky highs and robust basses.
|
Filter
Types
The Passeq employs two distinct filter types: One
of these functions much like traditional shelving
filters, while the other, as a peak filter, and together,
they provide the combined characteristics of wide-band
control in low and high ranges with more specific
frequency range control in mids. This selection minimizes
mutual influences between low, mid and high bands
while providing a more selective control in the mids
is often useful.
Mid boost and cut, as well as HF boost filers have
been set up in a peak (bell) configuration, while
the hi cut, low cut and low boost filters function
in a shelving configuration. The HF boost band offers
variable values from Q=1 to 0.1.
Single
Core Coils
Until now design approaches have involved individually
wound coils, but multiple coils have nonetheless been
placed on a single core. The Passeq design places
each coil on separate cores. This eliminates any possible
unwanted mutual influence transmitted through common-core
windings and thus, among other improvements, results
in better THD values.
120V
Makeup Amplifiers
With passive filtering comes an unavoidable drop in
signal level that requires makeup amplification, and
with the Passeq, here SPL’s extraordinary Supra-OPs,
with their unique analog 120-volt technology, come
into play. With a 116 dB signal-to-noise ratio and
+34dB of headroom, the SUPRA-OPs offer a stunning
150dB dynamic range, placing them in an unsurpassed
leadership position in either analog or digital signal
processing. The tremendously fast SUPRA slew rate
of 200V/ms allows for a highest possible precision
in filter output signals, particularly in the all-important
arena of transient response. These amplifiers effortlessly
and without coloration or degradation, transmit all
the desired filter characteristics and sonic results
an engineer has sought out and in the process, pushing
beyond the limits of what has been technically possible
to now.
SPL
SUPRA Op Amps
The specially designed and for-audio optimized SUPRA
OPs are constructed in three stages with high performance,
extremely low noise transistors from the modern HF
technology sector.
Tech
Talk: SPL SUPRA Input Stages
SPL SUPRA components
The central component of the PQ is a fundamentally
new amplification design: discrete, custom made Class
A audio operational amplifiers which run on a 120V
operating voltage (+/- 60V). This amounts to over
three times the operating voltage found in most high
quality audio gear (+/-15-20V) and about twice as
much as the highest voltages used in the best units
currently available.
This extremely high voltage allows the circuitry to
process an astonishing dynamic range of ca. 150dB
and an amazing +34dB of headroom, virtually eliminating
overloading of individual filter stages—even
when processing extremely high-level signals.
For the first time, transistor circuits with such
an impressive degree of stability and freedom from
harmonic distortion can be realized.
Input
stages of the SUPRA components
The development of the SUPRA components focused on
high loop amplification, extremely low phase shifting
and THD, combined with maximum amplification and a
frequency response up to 100kHz.
A main and obvious advantage of the discrete SUPRA
components is the exclusion of parts often found in
industrially manufactured standard components that
are not necessary for audio processing.
The SUPRA input stages are designed as balanced differential
stages and comprise six matched high voltage transistors
switched in parallel.The concept of the input stage
is based on the established principle that currents
of not correlated noise sources in shunt circuits
add up—which decreases the overall noise of
the input circuitry. The input stages are free of
coupling capacitors to exclude additional capacitor
noise. The balanced operational voltage of +/-60V
is delivered from a linear -80dB high voltage power
supply.
Intermediate
stages of the SUPRA components
The audio signal is further routed to a differential
stage and from there through further processing stages
to the Class-A output stage. All passive components
have been tested to yield the highest possible fidelity.
Output
stages of the SUPRA components
Extremely low noise, high voltage output transistors
are set up with a high quiescent current and excess
heat is dissipated via special cooling plates.
Lundahl
Transformers
The Swedish firm of Lundahl is recognized world wide
for the superior sonic qualities of its hand made
transformers. SPL has used Lundahl transformers for
many years, typically for optional in- and output
stages of various products. In the case of the Passeq,
there is no question of whether solid state or transformer-based
input and output stages are the better choice: Because
of their excellent and similar sonic qualities, Lundahl
transformers are a clear choice to complement to the
Passeq’s EQ circuitry.
I/O transformers are classical analog components in
many “vintage” machines. In addition to
increased operational safety due to the isolation
from incidental I/O electrical interference they offer,
transformers also introduce their own element of sonic
“warmth” that is today too often inadequately
attributed solely to tube circuitry.
The sonic quality from Passeq’s Lundahl transformers
may be described in comparison to straight electronic
I/O circuitry as: Bass and fundamentals are rounder,
fuller, and exhibit more “punch”, while
higher frequencies and harmonics sound silkier and
more present, yet without leaving the impression of
being overly emphasized or singled out. Moreover,
they add the subtle impression that mix elements are
better localized.
The reasons for this are the tendency of transformers
to reduce uneven harmonics (which give the impression
of harshness in a sonic canvas) and to act with some
latency compared to electronically balanced stages.
In particular, fundamentals and low frequencies benefit
from this.
Layout
of Operational Elements
Initially one might be struck by the circular arrangement
of the Passeq’s control elements. As unusual
as this first appears, the more understandable and
clearer these elements become when one looks closer.
Along with the fact that we simply like this design
from an aesthetical view, this layout makes even more
sense with respect to the idea of the passive EQ concept
itself: In a passive design, filters for boosting
and cutting a frequency range are physically separated
from each other. Reflecting this fact, the elements
left of the central output control perform level cuts,
while controls to the right of this central regulator
serve as signal boost controls. Cut and boost switches
are positioned next to the appropriate frequency band
selector and frequency bands are arranged from low
to high from the standpoint of both physical and frequency
range layout—all in all a clear overall functional
picture though without much in the way of boring routine.
The
Full Range
The Passeq is the first passive EQ which provides
three separate frequency ranges for both amplifier
and cut stages. One famous, if not the most famous,
passive design was the Pulteq EQ from the decades
of the 1950’s and 60’s. This EQ sported
two frequency bands (low and high frequencies, or
LF and HF), and had only a few switchable frequencies
to offer. In contrast, the Passeq has 12 switchable
frequencies per band, totaling 36 boost and 36 cut
frequencies. Boost and cut frequencies are NOT identical,
thus the resultant 72 frequencies per channel offer
an enormous choice for the most elaborate EQ curves
(please refer to the next chapter, “Frequency
Layout”).
The Passeq offers for the first time passive filter
control possibilities extending throughout the relevant
audio frequency range—and that with an unheard
of abundance of filter choices.
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 influences 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 high grade
core also provides for excellent THD values.
Allocation
of Frequencies
The greatest Passeq design challenge 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 corrections rather than choices of
what may be musically more sensible.
In assigning the Passeq's frequency ranges 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 professionals 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
320Hz, 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 (320Hz) frequency range by about 3dB. At
the same time, you chose a 4dB 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
Bands: LF-LMF Cut and LF Boost
The low cut frequency range extends from 30Hz to 1.9kHz
and will be referred to in this text as LF-LMF (Low
to Low-Mid frequencies). In contrast, the low boost
(LF Boost) band encompasses a range of 10 Hz to 550
Hz. The maximum available increase in this LF Boost
band is (+)17dB, while the maximum reduction of the
LF-LMF Cut band is (-)22dB.
Optically these filter bands may be represented as
having a shelving characteristic with an 6dB slope.
Passive filters do not allow for direct alteration
of the slope gradient because this quality is pre-determined
by component selection and not, as with active filters,
by an variable value.
The lowest frequencies begin here with 10Hz, then
follow with 15, 18, 26, 40Hz, and so on. At this point
one might think that such a lavish set of frequency
choice in this range might be a bit overdone, as there
is acoustically a rather limited amount of audio material
of any real significance below 26 Hz. However, these
choices are anything but arbitrary. These frequencies
represent a consistent -3dB point of a sloping down
response curve. That is, the gentle 6dB slope also
allows frequencies above 10 Hz to be processed. As
mentioned in other parts of this text, special condenser/coil/resistor
filter networks have been designed for each frequency
range. The choice of one or the other inductances
produces differences in sonic coloration even when
limited differences between frequencies such as 10Hz
or 15Hz play a subordinate role. Along with this differing
phase relationships may come into play and affect
tonal color. Because modern productions often demand
a definite number of choices in an engineer’s
options for achieving an optimal result in bass emphasis,
the Passeq has been designed with a very complete
set of low frequency options to insure realizing these
goals.
MF-MHF
Cut und LM-MHF Boost
The Midrange bands elevate the Passeq to a complete
combination of filter options that classic passive
designs do not offer. Both midrange bands exhibit
peak filter characteristics, that is, when viewed
from the boost band, the frequency curve appears as
bell-shaped slopes above and below the chosen frequency
range. The slope or Q-value is, again, not variable,
but attuned through the choice and configuration of
the passive filter's components for a maximum in musical
efficiency, relying in the Passeq on its developer,
Wolfgang Neumann's years of musical experience. The
middle bands' peak structure is chosen for a clean
separation of LF and HF bands. Were the choice here
to be for a shelving filter design, too many neighbouring
frequencies would be processed, with resulting undesirable
influences extending into LF and HF bands. Along with
this is the simple fact that a midrange peak filter
characteristic is accompanied by a more easily focused
centre point processing of critical voice and instrument
fundamental frequencies.
The MF-MHF Cut Band overlaps the LF-LMF Cut band by
approximately an octave, with its lowest frequency
extending from 1kHz. The LF Boost and LMF-MHF boost
bands are set up in a similar fashion, with the lowest
LMF-MHF boost band frequency set at 220Hz and thereby
1-1/2 octaves under the highest LF boost band frequency.
The maximum reduction of the MF-MHF Cut and LMF-MHF
boost band extends from -11.5dB to +10dB.
The overlapping band characteristics give a good idea
of the available degree of precision in frequency
adjustment: For example, one can boost in the LMF-MHF
Boost band at 220Hz while in the LF boost band, 240Hz
can be followed by 320Hz in the LMF-MHF boost band:
The next step could be at 380Hz in the LF boost band,
followed by 460Hz in the LMF-MHF Boost band and 550Hz
in the LF-Boost band ...
MHF-HF Cut and HF Boost
Passeq’s high frequency bands have a different
layout for the cut and boost ranges: The MHF-HF Cut
Band exhibits a (wideband) shelving characteristic,
while the HF Boost band exhibits a variable Q, peak
filter characteristic.
As seen above, one can also note and intensification
in choice of frequencies in the high range. Here the
same reasons apply as in prior cases: Individually
designed and constructed coil-condenser-resistor configurations
result in slightly differing sonic coloration. Thus
beginning at 10kHz there are seven additional switchable
frequencies. The available variable Q (ranging from
Q=0.1 to Q=1.0) allows the engineer access to an enormously
flexible range in high frequency boost options.
HF
Boost Quality Settings with the Proportional Q Principle
With the proportional or variable Q principle, boost
control settings would apply only if the HF Boost
Q were to be set at Q=1.0 (control set fully clockwise).
Were the value to be reduced (thus increasing the
bandwidth), the boost would also be reduced. This
can lead to a situation wherein, for example, a HF
Boost Q-setting of 0.1 and a boost of 3dB would result
in effectively no audible boost in the chosen frequency—at
this value the Q-value resides at about 0.3dB. With
this Q value, don’t hesitate to turn turn up
the HF band boost control to its full 12.5dB setting—this
resultsin an actual overall increase of around 3.5dB.
Narrower Q settings, for example, to 0.6, result in
further level boosts again.
The advantage of Proportional Q as compared to Constant
Q designs rests with the musically superior way it
functions. The wave energy which resides below the
bell curve remains essentially the same and in the
process, retains the balance of high frequencies in
relation to the entire frequency spectrum as one experiments
with varying Q values. While it is true that one must
think independently of the scaled HF boost dB values
in such cases (because these only apply to a value
of 1), the result is a simpler, more musically sensible
and worthwhile way to work that does not require continual
additional corrections.
MHF-HF
Cut
The MHF-HF Cut band is similar to a shelving filter
that can reduce higher frequencies in a wide bandwidth.
It is appropriately wide, beginning with 580Hz and
extending to 19.5kHz, a range of over 5 octaves and
overlapping the lowest, LF-LMF Cut Band by just about
two octaves. With it one can lower a very wide bandwidth
and with the peak mid range filters further reduce—or
raise—specific ranges. The process can result
in the creation of very interesting curves. Here the
maximum cut is -14.5dB, while the maximum boost reaches
+12.5dB.
The Passeq is not limited to any one particular kind
of application, and, for example, is also especially
well suited to processing individual instruments in
recording sessions. In such cases the wide downward
reaching MHF-HF Cut band may be play an exceptional
role. Individual instruments can easily be cut upwards,
either to give them a more compact sound or when higher
frequencies might be supplied from different microphone—or
because the mix simply suggests it.
