Manley Pultec EQP1-A Owner's Manual

MANLEY
LABORATORIES, INC.
OWNER'S MANUAL
ENHANCED PULTEC
EQP1-A
EQUALIZER
MANLEY LABORATORIES, INC.
13880 MAGNOLIA AVE.
TEL: (909) 627-4256 FAX: (909) 628-2482
email: emanley@netcom.com
http://www.manleylabs.com
CONTENTS
SECTION PAGE
INTRODUCTION 3
EQ HINTS 4
FRONT PANEL 5
REAR PANEL 6
MAINS CONNECTIONS 7
TECH NOTES 8
TROUBLESHOOTING 9, 10
CURVES 11, 12
WARRANTY 13
WARRANTY REGISTRATION 14
APPENDIX: WIRING YOUR OWN CABLES ? TEMPLATE FOR STORING SETTINGS
INTRODUCTION
THANK YOU!...
for purchasing the Manley Laboratories Enhanced Pultec EQP-1A Equalizer. The Enhanced Pultec Equalizer utilizes the original WESTERN ELECTRIC passive-equalization circuit found in the long-out-of-production and justifiably famous PULTECS. According to experts, Western Electric developed the passive EQ in the 30's to allow music to pass through a typical telephone system. This may help to explain the choice of curves and frequencies - boost a bit of bottom, boost a bit on top and filter out the hiss. Western Electric also seem to have brought us the balanced audio & the 600 ohm standard. Eugene Shenk of Pulse Technologies re-discovered the EQ and added his vacuum tube gain make up amplifier. While Pultec sold a healthy number of units to broadcast, when transistors came in, many jumped to the new technology and Pultec fell on hard times. It was not until the mid 70's and early 80's with the big new recording studios that engineers and producers found that nothing had the same magic low end that old Pultec tube EQs could give. Twenty years later, and they are still favorites (along with old British console EQs) and today few understand why they sound so good. Its not "just" the tubes.
We can offer a few good reasons. First - the EQ is passive. That means that the components involved have no gain. A typical modern parametric EQ can use 10 to 20 op-amps, each with many, many transistors. Music generally prefers a simple path with the fewest parts to pass a signal through. This also is one of the big advantages to tube circuits - simplicity. The EQ uses a few capacitors, inductors and resistors (or pots). No headroom problems, no crossover distortions, no slew induced distortions. Second - The EQ curves tend to be wide. While not perfect for everything, wide, low-Q, low-resonance frequency shaping is very musical and easy to use. Third- Transformers can add a nice fat low end. That euphonic bottom was partially due to transformer saturation. In other words the lower and louder a signal got, the more it saturated (added some extra harmonics to the ultra lows where most speakers are deficient). It helps us percieve that there was some energy down there without hearing the distortion as such. The older transformers suffered from wide band distortion and losses in the highs. This is rarely wanted. Modern high quality transformers are much better in the highs and generally much lower distortion, due to improvements in materials, but they can still saturate - the way we like. Fourth - Op-amp circuits have limitations. They use negative feedback to control gain. Often enough, this can cause a loss of transient accuracy and/or instability. Most op-amp EQ circuits rely on some very small signal levels that are prone to cross-over distortions in the push-pull outputs. Older op-amps have slow PNP transistors that began rolling off at a few hundred hertz causing crossover distortions. Headroom can be a hard ceiling (+20 dBu) that gets nasty when significant amounts of boost are called for. All of this worsens when driving capacitive wire or low impedances. The better solid state EQs are discrete with high voltage power supplies for headroom. Our Langevin Pultec is that style. The Manley tube version beats it.
Manley uses an all-tube gain block with a +31 dBu capability and less than 10 dB of feedback. Four triodes are used for "flat" class A gain stages and demonstrate the beauty of simplicity. We use a similar line amp in our 40 dB Mic Preamps and Electro-Optical Limiters and some of our audiophile hi-fi preamps.
Our version of this classic EQ incorporates modern audiophile grade components with our proven line-amp for absolute sonic beauty... Conductive plastic potentiometers and sealed gold-contact switches, polystyrene and rolled film and foil capacitors, and a our own transformers combine with a regulated stiff power supply and state-of-the-art tube circuitry to bring the PULTEC that is as good in the mids and highs as it has always been in the lows. It is now commonly used in the best mastering suites and has become a standard (must-have) item in studios world-wide. We added 8 frequencies and better interfacing, and it's only 1U !
Please take a few moments to read through this manual carefully as it contains information essential to proper operation of this unit. Thank you again, and please enjoy!
3
EQ HINTS
We usually give a few hints about tricks commonly used with our products. With an
EQ of this type it is not so likely you need much help.
The most common question we get asked about our Pultecs is "Why both a boost and a cut knob in the lows?". We don't know why it was designed that way for sure. It was designed in the 1930's by Western Electric to improve music fed through telephone lines. We believe it was done this way because it was the most practical in a simple passive design. This was before op-amps and Baxandall type cut / boost circuits were common. We do know that most engineers do use both knobs at the same time. Cutting a bit, boosting a bit, and the combination gets the fat bottom they turn to the Pultec for. "Wouldn't they just cancel out?" No, the shapes of the cut and boost are different and the result typically is boosted lows and a dip in the mids but it depends on the relative settings. The slope of the low boost tends to be steeper as well. We included a few pages of response curves to clarify this for you.
Vintage Pultecs are known for their usefulness on kick, bass, and raunchy guitars. They are rarely used for vocals, mixes or sounds where transparent highs are important. The Manley version, however, is often used for these purposes. It is featured in quite a few mastering suites as one of the primary EQs. The difference is the Manley has better gain make-up amps and fewer and better transformers. Here is the hint: for low end punch we suggest using the XLR transformer inputs & outputs because the signal passes through two transformers with a selected saturation characteristics. For situations where highs and fidelity are most important you can bypass the transformers using the 1/4 inch phone jacks. You can also use one transformer and bypass the other for something in-between. A little experimentation when you first get the unit will go a long way in the years of use. The Manley EQs were never intended as a clone of the original. We sought to improve them where we could. We knew it was a good concept and, with permission, could produce this little gem.
The Bandwidth control (mid &high boost section) seems reverse to many. As one turns the Bandwidth control clockwise the actual bandwidth increases - the "Q" is less. If one is used to "Q" controls then it will seem reverse - but think of it as "bandwidth" not "Q". It also boosts less dB's as bandwidth is increased but because the "area" is somewhat constant it doesn't sound like lost boost. The bandwidth narrows slightly as frequency is increased.
Watch out boosting major amounts of low end when using most nearfield monitors. Most don't have great response down there. One common technique is for engineers to watch speaker excursion to get an idea how much lows they are putting on. How accurate is that? It is not uncommon for an engineer to be surprised once they hear the tape in the car or on a system with a sub woofer. The extreme lows and highs are the most likely part of a sound to not "nail" because of monitors, fatigue, and the hype factor that is occasionally called for.
Best applications for this EQ? Important up-front sounds that a cheap EQ might butcher just passing the signal. Low end sounds like kick and bass that need serious fatness and punch & guitar amps that have lost that low thump we hear in the studio. Strong transient sounds like shakers, tamborines, and cowbells that some solid state gear has a way of smearing and turning into noise. Best time and place to shape the sound - before recording and with mic technique. Then the EQ becomes a useful tool - not a needed crutch.
4
FRONT PANEL
IN
BYPASS
BOOST SELECT CUT
BANDWIDTH SELECT BOOST SELECT CUT
POWER
A B C D E F G H I J K
LOW FREQUENCY
SECTION
HIGH FREQUENCY BOOST
SECTION
A IN / BYPASS - This switch in BYPASS mode bypasses the EQ section while the amplifier remains
in circuit.
B L.F. BOOST - Shelf - Provides continuously variable BOOST from 0dB to +15dB to the selected low
frequency (control C). Check out the curves on pages 15 & 16.
C LOW FREQUENCY SELECTOR - Used for both L.F. BOOST and/or CUT. For BOOST or CUT
this frequency is almost the maximum of the curve. With maximum boost (or cut), lower frequencies may get 3 dB more boost (or cut).
D L.F. CUT - Shel f - Provides continuously variable CUT from 0dB to +16dB to the selected low
frequency ( control C). Many use a combination of boost and cut to get an interesting shape. The typical effect is boosed lows with a dip in the low mids or mids. Why ? Because the boost and cut are not mirror images of each other. The cut stetches higher.
HIGH FREQ. CUT
SECTION
E BANDWIDTH - This continuously variable control affects the width of the HIGH FREQUENCY
BOOST effect. Counter-clockwise (around 1) is narrow or a high Q. Clockwise is a larger bandwidth, wider or lower Q. The maximum boost of 20 dB occurs at narrow bandwidths and goes to 13 or 14 dB with wider bandwidth. Because the area stays somewhat constant it does not sound like lost boost. The bandwidth also tends to get slightly narrower with higher H.F. BOOST frequencies - normal for passive EQs. This knob may seem reversed if one is used to modern parametrics.
F H.F. BOOST - Peaking - Provides Continuously variable BOOST from 0 to +20dB to the selected
high frequency (select control G). The maximum amount of H.F. BOOST is affected also by the BANDWIDTH control. (see E)
G HIGH FREQUENCY BOOST SELECT - Selects at which frequency maximum operation of the H.F.
BOOST section occurs. The frequencies are marked in KiloHertz.
H HIGH FREQUENCY CUT - Shelf - Provides continuously variable CUT from 0 to -21dB of the
extreme high frequencies.
I HIGH FREQUENCY CUT SELECT - Selects at which frequency the H.F. CUT control occurs.
The frequency is about half way down the curve (max =-21dB, at selected freq = -12 dB)
J LED - When power is first turned on the LED is RED. This means that the EQ is muted until the tubes
are warmed up. It prevents thumps and pops. About 20 seconds later the LED turns GREEN and the EQ will pass audio. This circuit is smart enough to ignore a quick black-out.
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