Tape Recording Equalization Fundamentals
and 15 in/s Equalizations

Jay McKnight, Magnetic Reference Lab

Fundamentals

It's easy to get confused about tape recorder equalization, because the basic magnetic tape recording and reproducing process has considerable high-frequency (HF) losses. This is as opposed, for instance, to FM radio, where the basic frequency response is "flat", and a "complementary" HF boost in transmission, and HF cut in reproduction, is used. Another confusion occurs because the usual "inductive" repro head gives a voltage output that rises 6 dB/oct for a constant flux input. So what follows may not be fully intuitive.

All of the tape recording standards now specify the recorded flux on the tape as a function of frequency. They specify that the flux is constant from low- to mid-frequencies, then falls at 6 dB/oct above a "transition" (-3 dB) corner frequency. (This response is the same as that of a single-pole low-pass filter.) This means that, for flat overall response, the reproducer must have a response that is complementary to the recorded flux (not to the recording pre-emphasis!). This complement is a HF boost at 6 dB/oct starting from this same transition frequency. The lower the transition frequency, the more HF boost there is in reproduction, making more HF headroom, and more HF noise to go with it. The formula for the flux level vs frequency,  and all of the transition frequencies, are given in Sec. 1.2.3 of MRL's "Choosing and Using MRL Calibration Tapes....", and the values of flux level vs frequency are given in a table. A more-detailed explanation with examples and graphs of the frequency response of magnetic recorders is given in an AES Journal paper.

The usual reproducing head is inductive, and it therefore differentiates the tape flux. That simply means that, for a constant flux input to the head vs frequency, the head output voltage will rise at 6 dB per octave. To compensate this, the usual reproducing amplifier is an integrator, whose response falls at 6 dB per octave.  Thus constant flux thru a differentiating head thru a integrating amplifier gives constant output voltage vs frequency. (The terms "differentiator" and "integrator" come from the mathematics of the circuit analysis. For our purposes, "differentiator" is just a short way of saying "makes the frequency response rise at 6 dB per octave", an "integrator" is a short way of saying "makes the frequency response fall at 6 dB per octave".)

Since the standard tape flux falls 6 dB/oct above some frequency ­-- say 3150 Hz for 15 in/s NAB equalization -- the reproducer equalizing amplifier response must rise 6 dB/oct relative to integration above that frequency. This simply means that the integration is stopped at that frequency. So the repro pre-amp voltage response falls 6 dB/oct from some low frequency (say 16 Hz) to the standard transition frequency (3150 Hz for 15 in/s NAB), then is flat above that frequency. Again, you may want to refer to the more-detailed explanation with examples and graphs of the frequency response of magnetic recorders that is here.

ONE MORE DETAIL: Everything said above assumes that the head is "ideal": no low-frequency head bumps and droop; no gap loss; no head resonance; perfect azimuth adjustment and head-to-tape contact; etc. In reality, all of those things have to be corrected or compensated in a practical reproducer, so it behaves as tho it were using an ideal head.  Actually, most modern professional reproducing heads are pretty close to "ideal".
 

If you want to read a modern general theoretical discussion of tape recording equalization, see:

" Pre- and Postemphasis Techniques as Applied to Audio Recording Systems", by  Louis D. Fielder ,
Audio Engineering Society Journal,  Volume: 33, Issue: 9, Page: 649...658 (1985). Available for purchase from the AES at  http://www.aes.org/journal/search.cfm

Abstract: Audio recorders benefit from pre- and postemphasis, which reshapes the noise spectrum to match human audibility thresholds. A 10-dB increase in apparent dynamic range is realized for some digital audio systems. A first-order boost based on the CCITT J.17 preemphasis standard is shown to be appropriate for dynamic range expansion. A survey of peak acoustic levels present in 36 music performances is also included.


Equalizations for 15 in/s -- NAB, IEC, AME, proposed Studio Master, ADE, NagraMaster

NOTE  This discussion is ONLY for 15 in/s. 7.5 in/s and 30 in/s Eq are a whole 'nother set of stories, if anyone's interested.

The present 15 in/s NAB eq was designed by Frank Lennert, at Ampex, for the Ampex Models 300, 301, and 201, in 1948 or 1949. It was for use with the standard professional tape of the day,  3M 111, and it was within ±1.3 dB of the equalization then already used by Ranger, Brush, and RCA, as shown by a figure in the Ampex 201 manual. (The Magnecord equalization was quite different.) The Ampex equalization was approved as an NAB Standard in 1953. It was appropriate in its day.

Q. Is the NAB standard optimum for recording at 15 in/s on modern tapes?

A. Without a doubt, it is far from optimum. I argued for making a change in the 1970s, but others said "Don't bother, analog is almost dead". Ha!

By the mid-to-late 1960s, the wavelength response of the tape had improved so much  that a high-frequency cut is necessary to get the standard flux on the tape, and thereby flat overall response. This makes the recording equalizer hard to design, inflexible (hard to get flat for different tapes), and terrible for utilization of the tape -- there's way too much HF "overhead" room, and way too much noise to go with it.

Several proposals have been made for a more appropriate 15 in/s standard eq. The easiest is to use the IEC1 Standard (also called IEC, CCIR, and DIN) eq, as the Tascam 8 track ½ inch system does. I discuss other possibilities below. The irony is that 2-track masters on ½ inch tape at 15 in/s still use the NAB eq! Ugh! But apparently many or most 2-track on ½ inch tape are at 30 in/s, which has a better if not necessarily optimum equalization.

For 15 in/s with modern tapes, five different "equalizations" (really the curves for recorded flux vs frequency) have been standardized, proposed, or used commercially:
 

1  IEC2/NAB Standard: Recorded HF flux droops from a transition frequency at 3150 Hz, requiring the reproducer to boost (relative to integration) from this frequency. This repro boost gives about 3 dB more HF boost in reproduction than the inherent recording losses of the tape, so an HF shelf-down is necessary in recording to match the standard flux curve -- that is, to give flat overall response. This is a shambles, dictated by all of the machines in the field that are set up this way, and all of the libraries recorded this way since 1950, and still. This Standard also use a low-frequency boost and cut -- see "Low-Frequency Equalization", below.
 

2  IEC1/IEC Standard: Transition frequency 4500 Hz. Just about matches the tape losses, and is the best you can do if you want to use an internationally-standardized eq. Has been widely used in Europe for ¼ in width master recording since the 1950s. Is used always (even in the US) for the Tascam, Otari, Fostex "double track density" recorders (8 tracks on 1/2 inch, 16 tracks on 1 inch, &c). This Standard does not use a low-frequency boost and cut -- see "Low-Frequency Equalization", below. 


3  MRL-SM  (Studio Master):  Transition frequency 6300 Hz.
For technical details, s
ee "Proposed Equalization for 15 in/s Studio Master Recording on High-Output Low-Noise Tapes", by J. McKnight and T. Kendall.
Audio Engineering Society Preprint  Nr: 920, Convention No: 45 (1973), also available for purchase from  the AES . This Standard is based on the IEC/CCIR Standard, and does not use the low-frequency boost and cut of the NAB Standard -- see "Low-Frequency Equalization", below.

To purchase a Calibration Tape with the MRL-SM equalization, see the Publication 101SM for catalog numbers and prices for all tape widths.

Abstract:
A new equalization and reference fluxivity are proposed: no LF pre-emphasis, reproducing HF equalization +3 dB at 6300 Hz (“25 µs”) and reference fluxivity of 250 nWb/m. Measured data and a demonstration compare the NAB and proposed performances. Pre-emphasis at 4 kHz is increased from
-2 to +1 dB; at 16 kHz, from +1 to +6.5 dB (NAB was +11 dB in 1950, when developed). Noise and maximum signal at 4 kHz are thus reduced 3 dB, and at 16 kHz, 5.5 dB. Recording response with less than a total of 0.5 dB ripple up to 20 kHz is achieved with one R-C recording equalizer.


Comment: In 1973,  MRL thought this was a pretty good practical compromise of noise and headroom. We offered Calibration Tapes with this equalization, but we soon withdrew this as a standard product because people who don't read carefully missed the "proposed", and would buy this calibration tape when they really wanted the old NAB tape. This eq was and is used in the Pacific Recorders (now Research) & Engineering "CAT" broadcast carts at 15 in/s.

 For a handy/cheap substitute Calibration Tape: The HF eq (that is, above 250 Hz) on a wavelength basis is the same as the standard 7.5 in/s NAB HF response. So just play a 7.5 in/s NAB Calibration Tape at 15 in/s, set the repro response above 500 Hz (at 15 in/s) to "flat", and you've got the "MRL  Studio Master" equalization.
  Note that you cannot use the frequencies below 250 Hz on this tape, since they have the low-frequency boost of the NAB equalization.
 

4  ADE   (Ampex Duplicator Equalization): Transition frequency 12.5 kHz.
See "Master-Tape Equalization Revisited
", by John G. McKnight; Peter F. Hille
Audio Engineering Society Preprint Nr: 856, Convention No: 42 (1972), available for purchase from  the AES.

Abstract: Optimum signal minus noise level of a commercial tape or disc record requires the signal- and noise-spectra of the studio master tape to be matched to those of the commercial record. The use of the NAB 380 mm/s (15 in/s) equalization (3150 Hz transition frequency) with modern tapes results in frequency- and noise-spectra which have much higher levels at higher frequencies than the final records. Other practical equalizations are studied, and a 12,500 Hz reproducing transition frequency is suggested for further evaluation.

 
Comment: This eq was used by Ampex Stereo Tapes for the 15 in/s masters for duplication to 7.5 in/s copies (the "EX+" series). The  "Nagra Master Eq", used at 15 in/s, is essentially the same, but with a LF boost/cut. A Calibration Tape with ADE is  available from MRL at standard prices.

 

5 AME (Ampex Master Equalization)

See PubAME  for details and more links.

It is NOT just a different transition frequency, so it requires an additional filter, not just re-setting the usual "HF Eq" control. It was based on modifying the NAB response with a hearing curve, which resulted in a recorded flux that had a "hump" (re the NAB eq) from about +3 dB at 630 Hz to +8 dB at 2 kHz, back to +3 dB at 5 kHz, and down to -12 dB at 16 kHz. This means that it requires making a more complicated filter, and I don't  now think  that this has commensurate practical benefits. We do, however, still make an AME Calibration Tape, for those who have old library recorded that way.

CBS Labs independently arrived at a very similar equalization, not used outside of CBS, published in:
"A New Equalization Characteristic for Master Tape Recording ", by A.. A. Goldberg; Emil L. Torick
Audio Engineering Society Journal, Volume: 8, Issue: 1, Page: 29...33 (1960). Available for purchase from  the AES.

Abstract: Although the signal-to-noise ratio of master tape recorders is good by present standards, a low level background noise still exists. This is heard as hiss, due to the characteristic of the ear. Hiss reduction is accomplished by a new equalization that increases the tape loading in the frequencies between 1000 and 15,000 cps and decreases the hiss by 6 db as compared with NAB equalization. This is achieved at the expense of increased distortion within the hiss frequencies.

 

The German Broadcasting research institute also arrived at a similar equalization, and I believe used it in their radio recordings. It was published in German, but not (that I know of) in English.
 

Low-Frequency Equalization
All above completely ignores the low-frequency (LF) response & equalization. LF boost & cut is used for IEC2/NAB, AME, & Nagra Master; but is not used for the others. For arguments against an LF boost and cut, see

"The Case Against Low-Frequency Pre-Emphasis in Magnetic Recording ", by John G. McKnight,
Audio Engineering Society Journal Volume: 10, Issue: 2, Page: 106...108 (1962).  Also available for purchase from  the AES.
 
Abstract: Data on low-frequency energy distribution in music do not justify the use of low-frequency pre-emphasis, and subjective low-frequency noise does not require it. Therefore the elimination of low-frequency pre-emphasis is suggested. Practical implications are also discussed.

 

COMMENTS

Dr. Frederick J. Bashour wrote:

"Am I the only old analog guy who used your SM eq back in the mid-70s? I have so many tapes done that way, and I always preferred them to the ones I did with Dolby A.

"In fact, I used SM until 1978, when I switched to 30 ips using my own "in-house" special curve, which was approximately 3 dB hotter from about 4 kHz on up. [That curve came about because my combination of Paradyne electronics and Ralph Norton high inductance heads couldn't quite make the normal 30 ips AES playback curve. The electronics were a dB or so from going into oscillation, but the tapes sure were quiet!]

"Unfortunately, I lost my SM test tape when I left my briefcase on the roof of the Port Authority parking garage one hot afternoon in 1980. Good thing many of my SM masters have tones on them!

"Does MRL still make a SM test tape?

"Dr. Fred"
 

Yes - see "3  Studio Mastering", above.

Q: "How does all this relate to Dolby SR?"

A: I'm not really sure. The Dolby NR systems are "dynamic" equalizers, as opposed to all of the others above which are "static" equalizers. I believe that Dolby based his design on the 15 in/s NAB curve. If so, he has already modified the responses to minimize the "evil" effects of the 15 in/s NAB curve.

See:" The Spectral Recording Process", by Ray Dolby
Audio Engineering Society Journal, Volume: 35, Issue: 3, Page: 99-118  (1987). Available for purchase from   the AES.

Abstract: A complementary audio signal encoding and decoding format, called spectral recording (SR), for use in professional magnetic recording and similar applications is described. The processing algorithm is highly responsive to the spectral properties of the signal. A further characteristic used by encoding de-emphasizes high-level signal components in the frequency regions usually subject to channel overload. The process results in a significant reduction of audible noise and distortion arising in the channel.

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Edited 1999-01-14
Originally "Fundamentals" and "15 in/s Equalizations" were two separate files; combined 2000-04-05.
2003-08-06 Minor text clarifications; links added to papers.
Edited 2004-05-27;
2005-02-18  link to pub101sm added.
Edited 2006-01-18 to emphasize that the MRL SM equalization does not use the low-frequency boost and cut of the NAB Standard.