Milestone-Nomination:16-bit Monolithic DAC, 1981
World’s First Monolithic 16-Bit Digital-to-Analog Converter (DAC) for Digital Audio, 1981
In early 1982, Burr-Brown Research Corporation, later part of Texas Instruments, Inc., demonstrated a 16-bit monolithic digital-to-analog converter. Coupled with earlier compact disc development by Philips and Sony, it enabled affordable high-quality compact disc players, helped transform music distribution and playback from analog phonograph records to digital compact discs, and ushered in digital media playback.
The plaques may be viewed at:
1) Texas Instruments' North Dallas campus, Dallas, TX U.S.A. outside the Semiconductor Building that has other TI landmarks installed. The outside location is chosen so that anyone at the building can easily see the milestone and its significance. If awarded, a duplicate marker would be placed in TI Tucson where the product design and manufacturing actually happened. The building is one of many at TI’s North Campus in Dallas, Texas, which is guarded electronically and by booths staffed with security personnel. The public can enter the campus after showing personal identification.
2) Texas Instruments building, 5411 East Williams, Blvd., Tucson, Arizona, U.S.A. where the product design and manufacturing actually happened
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Historic significance of this work: its importance to the evolution of electrical and computer engineering and science and its importance to regional/national/international development.
The PCM53/DAC700 is the World's First Monolithic 16-bit DAC. Designed by Jimmy Naylor and TI / Burr-Brown data converter design team [1-4], this product played a key role in transforming the music industry from analog audio tapes and Vinyl long Play Discs (LPs) into digital audio Compact Discs. This 16 bit DAC was designed in to almost all major manufacturers of CD players when the Compact Disc Player was emerging as a superior Digital Audio apparatus and led TI / Burr-Brown to dominate the digital audio data converter market with more than 80% share for several years. The TI/ Burr Brown DAC was mentioned in the movie “The Italian Job”. This unique monolithic chip and its fundamental achievement together with the technical advances in Audio and Speech processing, digital signal processing, which occurred in the 1970s and 1980s [5] resulted in digital audio [6] overtaking analog audio and spawning a new digital audio industry that is still expanding today with the introduction of a new generation iPods and other MP3 Players.
In April of 1981, Jim Naylor, William J Lillis, Anthony D. Wang, and Robert L. White from Burr-Brown Research Corporation (Tucson, AZ) which later on become part of Texas Instruments, Inc.; filed 2 US patents 4,381,497 and 4,423,409 on a monolithic Digital to Analog converter design. Later on Jim Naylor wrote a paper in 1983 [1] on PCM53/DAC700 - The World's First Monolithic 16-bit DAC that the TI Burr-Brown team designed. Paul Prazak has presented the paper at the WESCON 82. This product played a key role in transforming the music industry from analog vinyl disc to Digital Compact Disc and was a monumental change. The PCM53/DAC700 is the World's First Monolithic 16-bit DAC. Designed by Jimmy Naylor and TI / Burr-Brown data converter design team [1], this product played a key role in transforming the music industry from analog audio tapes and Vinyl long Play Discs (LPs) into digital audio Compact Discs. This 16bit DAC was designed in to almost all major manufacturers of CD players when the Compact Disc Player was emerging as an superior Digital Audio apparatus and led TI / Burr-Brown to dominate the digital audio data converter market with more than 80% share for several years. The TI burr brown DACs was mentioned in the movie “The Italian Job”. This unique monolithic chip and its fundamental achievement together with the technical advances in Audio and Speech processing, digital signal processing, which occurred in the 1970s and 1980s [2] resulted in digital audio overtaking analog audio and spawning a new digital audio industry that we still expanding today.
References:
[1] "A complete high-speed voltage output 16-bit monolithic DAC", Naylor, J.R.;Solid-State Circuits, IEEE Journal of Volume 18, Issue 6, Dec 1983 Page(s):729 – 735
[2] "A 16b monolithic DAC with voltage output", Naylor, J.; Solid-State Circuits Conference. Digest of Technical Papers. 1983 IEEE International, Volume XXVI, Feb 1983 Page(s):186 - 187
[3] United States Patent 4,423,409
Naylor , et al. December 27, 1983
Digital-to-analog converter having single-ended input interface circuit
Inventors: Naylor; Jimmy R. (Tucson, AZ), Lillis; William J. (Tucson, AZ), Wang; Anthony D. (Tucson, AZ)
Assignee: Burr-Brown Research Corporation (Tucson, AZ)
Appl. No.: 06/250,868
Filed: April 3, 1981
[4] United States Patent 4,381,497
Lillis , et al. April 26, 1983
Digital-to-analog converter having open-loop voltage reference for regulating bit switch currents
Inventors: Lillis; William J. (Tucson, AZ), Naylor; Jimmy R. (Tucson, AZ), Wang; Anthony D. (Tucson, AZ), White; Robert L. (Tucson, AZ)
Assignee: Burr-Brown Research Corporation (Tucson, AZ)
Appl. No.: 06/250,858
Filed: April 3, 1981
PCM53 datasheet
[5] Gene Frantz and Larry Zhang, TI IEEE Electrical Engineering and Computing Milestone nomination: Speak & Spell – the first implementation of a Digital Signal Processing IC for speech generation, 1978.
[5] IEEE milestone to N.V. Philips for "COMPACT DISC AUDIO PLAYER, 1979".
Features or characteristics set this work apart from similar achievements?
For the first time, a complete 16-bit monolithic DAC has been integrated into a single chip with all the components necessary for a high performance Digital to Analog converter. Up until this point all 16-bit DACs were multi-chip hybrids that are not functionally complete because external components must be added and they were very costly to build.
When Sony and Philips were designing the Digital Audio players, there were three fundamental problems that needed to be solved:
1) A medium that could store the amount of information needed for high fidelity audio. They started with digital tape, but settled on the compact disc (CD) format.
2) Lowering the cost of the read mechanism (laser) to read the CD.
3) A low cost, high performance DAC to play back the music!
TI / Burr-Brown’s design team were already working on a monolithic DAC for industrial markets, but we really stepped up the pace and were first to the emerging audio market. The differential linearity laser trim algorithm made the DAC "sound better” with lower Total harmonic Distortion (THD) that was better than if you trimmed for absolute linearity. This was the best performance audio DAC of its time with much improved reliability over the older hybrid design which required multiple chips and over 100 wirebonds. With the help of TI/Burr-Brown Japan’s super sales and applications team we were designed in to almost all major manufacturers of CD players and dominated the Digital to Analog audio converter market with more than 80% share for several years.
To reduce a multichip hybrid converter design to a single chip, several obstacles had to be overcome in the late 1970’s or early 1980’s:
Power consumption changes on a single chip will cause thermal gradients that affect temperature sensitive components introducing offset, gain, and/or linearity errors. Since thermal gradients on the chip surface take a few hundred microseconds to stabilize after a power change, the settling time of the DAC output could be adversely affected. This phenomenon is sometimes referred to as a thermal settling “tail.”
Minimizing the die size precluded the use of large capacitor values that is common in a hybrid design, for the compensation of amplifiers or for suppressing switching transient.
To realize the new single chip monolithic DAC, and holding the die size to less than 20000 square mils to minimize the cost per die, required an innovative process technology. Rather than using a conventional 40 V bipolar process used for many analog circuits, a thinner epi process yielding 20 V BVCEO transistors was chosen. This saved considerable die area as typical transistor geometries are approximately 50 percent smaller.
Letter from the site owner giving permission to place IEEE milestone plaque on the property.
