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Yamaha OPL

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The OPL (FM Operator Type-L) series is a family of sound chips developed by Yamaha. It consists of low-cost sound chips providing FM synthesis for use in computing, music and video game applications.

The OPL series of chips enabled the creation of affordable sound cards for IBM PC compatibles in the late 1980s such the AdLib and Sound Blaster, effectively becoming a de-facto standard until they were supplanted by "wavetable synthesis" cards in the early-to-mid 1990s.

Internal operation

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The internal operation of the chips is completely digital. Each FM-tone is generated by a digital oscillator using a form of direct digital synthesis. A low-frequency oscillator and an envelope generator drive an FM operator to produce floating-point output for the DAC. Decapsulation of the chips shows two look-up tables, one for calculating exponents and one for log-sine.[1] This allows the FM operator to calculate its output without any multipliers, using the formula and two 256-entry look-up tables. Both tables are stored as pairs of values rounded to the nearest whole number, with the second value represented as the difference between it and the first value.

A quarter of the log-transformed sine waveform is stored as a sampled approximation in a 256-word read-only memory (ROM) table, computed by for values of 0 to 255. The rest of the sine-waveform is extrapolated via its property of symmetry. Scaling the output of an oscillator to a wanted volume would normally be done by multiplication, but the YM3526 avoids multiplications by operating on log-transformed signals, which reduces multiplications into computationally cheaper additions.[2]

Another 256-word ROM stores the exponential function as a lookup table, used to convert the logarithmic scale signal back to linear scale when required, as the final stage where the oscillator-outputs are summed together (just prior to the DAC-output bus), with the modulator waveform always delayed by one sample before the carrier waveform.[3] This table is computed by for values of 0 to 255. To compute the exponent, 1024 is added to the value at the index given by the least significant byte of input; this becomes the significand and the remaining bits of input become the exponent of the floating point output.

Chips in the series

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OPL

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Yamaha YM3526

The YM3526, introduced in 1984, was the first in the OPL family, providing a nine channel, two operator synthesizer. A very closely related chip is the Y8950, or MSX-AUDIO, which was used as an MSX expansion. It is essentially a YM3526 with ADPCM recording and playback capability.

The circuit has 244 different write-only registers. It can produce 9 channels of sound (or 6 channels with 5 percussion instruments available), each made of two oscillators. Each oscillator can produce sine waves and has its own ADSR envelope generator. Its main method of synthesis is frequency modulation synthesis, accomplished via phase modulation of the phase of one channel's oscillators by the output of another.

The YM3526's output, a sequence of floating point numbers clocked at a sampling frequency of approximately 49716 Hz, is sent to a separate digital-to-analog converter (DAC) chip, the YM3014B. The YM3014B DAC chip was also used in other FM chips such as the YM2151 and YM2203.

Overview of a channel's registers:

For the whole channel:

  • Main frequency (10 bits)
  • Octave (3 bits)
  • Note on/off
  • Synthesis mode (FM or just additive)
  • Feedback (0–7, the modulator modulating itself)

For each one of the two oscillators:

  • Frequency multiply (can be set to 12, 1 to 10, 12 or 15)
  • Waveform (Sine)
  • Volume (0–63, logarithmic)
  • Attack, decay, sustain, release (4 bits each, logarithmic)
  • Tremolo (on or off)
  • Vibrato (on or off)
  • Sustain (on or off)
  • Envelope scaling per key (on or off)
  • Volume scaling per key (0–3)

There are also a few parameters that can be set for the whole chip:

  • Vibrato depth
  • Tremolo depth
  • Percussion mode (uses 3 channels to provide 5 percussion sounds)
  • Composite sine mode (see Oscillator sync)

OPL2

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An audio sample of music written for and played on YM3812
OPL2 waveforms[4]: 46 

In 1985, Yamaha created the YM3812, also known as the OPL2. It is backward compatible with the YM3526. Another related chip is the YM2413 (OPLL), which is a cut down version of the YM3812.

Limited to two-operator FM synthesis, the YM3812 is unable to accurately reproduce timbres of real instruments and percussive sounds unlike other FM chips. Melody polyphony is limited to nine voices in melodic mode and six voices in percussive mode.[5]: 27.14–17.16  Among its newly-added features is the ability to pick between four waveforms for each individual oscillator by setting a register. In addition to the original sine wave, three modified waveforms can be produced: half-sine waves (where the negative part of the sine is muted), absolute-sine waves (where the negative part is inverted), and pseudo-sawtooth waves (quarter sine waves upward only with silent sections in between). This odd way of producing waveforms give the YM3812 a characteristic sound.[6] The YM3812 is used with an external YM3014B monophonic DAC chip to output its audio in analog form, like with the YM3526.

Having little competition on the market at the time of introduction of Adlib and Sound Blaster in the late 1980s, the chip became the de-facto standard for "Sound Blaster compatible" sound cards.[5]: 27.14 

OPL3

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OPL3 waveforms[4]: 46–47 

Released as early as 1990,[7] an upgraded version of the OPL2 known as the YMF262 (a.k.a. OPL3) was developed. It improves on the feature-set of the YM3812, which notably includes the ability to use four-operator FM synthesis. This makes the YMF262 produce more harmonically richer sound than its predecessors, similar to that of contemporary consumer synthesizer keyboards such as Yamaha DX100.[5]: 27.16 

The following features were added:[8]

  • twice as many channels (18 instead of 9)
  • simple stereo (hard left, center or hard right)
  • 4 channel sound output
  • 4 new waveforms (alternating-sine, "camel"-sine, square and logarithmic sawtooth)
  • 4 operator mode, pairing 2 channels together to create up to six 4 operator FM voices
  • reduced latency for host-register access (the OPL2 had much longer I/O access delays)
  • subtle differences in the sine-wave lookup table and envelope generator to YM3812 (e.g. the modulator waveform on YM3812 is delayed by one sample, whereas both carrier and modulator waveforms on OPL3 are properly synchronized)[3]

The YMF262's FM synthesis mode can be configured in different ways:[5]: 27.16–27.18 [8]

  • Its basic mode provides 18 two-operator FM channels.
  • One setting, common with the rest of the OPL line, converts 3 of the FM channels into a 5-channel percussion set.
  • Another setting, introduced with this chip, causes 12 of the channels to be paired up into six four-operator channels. This trades in polyphony for more complex sound formation.
  • These two settings above can be used separately or in conjunction, resulting in four total modes:
    • 18 2-operator channels
    • 15 2-operator channels + 5 drum channels (drum setting on)
    • 6 2-operator channels + 6 4-operator channels (4-op setting on)
    • 3 2-operator channels + 6 4-operator channels + 5 drum channels (both settings on)

The YMF262 also removed support for the little-used CSM (Composite sine mode) that was featured on the YM3526 and YM3812.[3] The mode was equivalent to triggering multiple channels simultaneously. Like its predecessors, the OPL3 outputs audio in digital form, requiring an external DAC chip such as the YAC512.

The YMF262 was used in the revised Sound Blaster Pro, Sound Blaster 16, AdLib Gold, Media Vision’s Pro AudioSpectrum cards, and Microsoft’s Windows Sound System cards.[4]: 45  Competing sound chip vendors (such as ESS,[9] OPTi,[10] Crystal[11] and others) have also designed their own OPL3-compatible audio chips, with varying degrees of faithfulness to the original OPL3.

Yamaha YMF289

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A comparison of the outputs of Yamaha's YMF262 and YMF289 FM sound chips. 0:00 is YMF262, and 0:31 onward is YMF289.

In 1995, Yamaha produced a fully compatible, low-power variant of the YMF262 called the YMF289 (OPL3-L), targeting PCMCIA sound cards and laptop computers.[12] It was also used in some Sound Blaster 16 sound cards made by Creative Technology. The YMF289B is paired with a YAC513 or YAC516 companion floating-point DAC chip.

The YMF289 is fully register-compatible with and retains the feature-set of the YMF262, with a number of differences:[12]

  • Supports 5 or 3.3 volt operation.
  • The registers can be read or written by the host CPU, whereas on the YMF262 they are write-only.
  • 44,100 Hz (44.1 kHz) output sample rate.
  • A power-down mode is added.
  • Somewhat smaller overall footprint, including DAC, compared to a full YMF262 implementation.
  • 33.868 MHz input clock, compared to the 14.32 MHz input clock used for the YMF262.
  • Internal linear interpolator.

ESS ESFM

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ESFM's output under Legacy / OPL3-compatible mode demonstrates some tangible differences in the way some sounds are synthesized.

ESS Technology's in-house developed derivative, termed ESFM, is an enhanced 72-operator OPL3-compatible clone incorporating two operating modes, a Native mode and a Legacy mode, which controls its feature-set and behavior.[9] In Native mode, ESFM allows 18 4-operator FM voices to be mapped, each with per-operator frequency control and LFO depth,[13] potentially allowing for a significant increase in the complexity of tones generated. The drivers for Windows 9x incorporate their own custom instrument patches which make use of this extended mode. Conversely, Legacy mode provides full backward-compatibility with Yamaha's YMF262.[9] ESFM's output in this mode is moderately faithful to the YMF262 overall, but some tones are rendered quite differently, resulting in unique distortions in the sound and music of some games.

ESFM is available in ESS sound chips starting with the ISA-based ES1688 AudioDrive, up to the PCI-based ES1946 Solo-1E, whereas earlier chips required an external FM synthesizer chip (typically a Yamaha YMF262). ESS's Maestro series of PCI-based sound chips rely on a software implementation of FM synthesis that lacks ESFM's special features.

OPL3-SA, DS-XG, OPL4

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Yamaha's later PC audio controllers, including the YMF278 (OPL4), the single-chip Yamaha YMF718/719S, and the PCI YMF724/74x family, included the YMF262's FM synthesis block for backward compatibility with legacy software. See YMF7xx for more information.

Products using the OPL series

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The YM3526 was notably used in a Commodore 64 expansion, the Sound Expander, as well as several arcade games, such as Terra Cresta and Bubble Bobble. A modified version of the YM3526 with ADPCM audio known as the Y8950 (MSX-AUDIO) was used in the MSX computer as an optional expansion.

The YM3812 saw wide use in IBM PC-based sound cards such as the AdLib, Sound Blaster and Pro AudioSpectrum (8bit),[14] as well as several arcade games by Nichibutsu, Toaplan and others.

The YM2413 was used in the FM Sound Unit expansion for the Sega Mark III and the Japanese model Sega Master System, as well as the MSX-MUSIC standard, which was released both as separate enhancement cards (such as the Panasonic FM-PAC) and built-in into several MSX2+ and the MSX TurboR computers. It was also used in some arcade games by Atari, SNK and Alpha Denshi, among others.

The YMF262 was used in many IBM PC-based sound cards, firstly with the popular Sound Blaster Pro 2 in 1991 and then later with the Sound Blaster 16 ASP in 1992, as well as the Pro AudioSpectrum (16bit).[14] Later models of the Sound Blaster 16 and Sound Blaster AWE series integrated the OPL3 with other chips, with Creative Labs using an OPL3 clone chip, the CQM, integral with other chips in later models from late 1995.[15] It is also used in several arcade games by Tecmo and others.

The YMF278 was used in the Moonsound card for the MSX, as well as the Sound Edge card by Yamaha for IBM PC compatibles.

Synthesizers

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Synthesizers that use the YM3812:[16]

  • Yamaha PSR-11 49-keys 16-sounds (1986)
  • Yamaha PSR-12 49-keys 32-sounds (1987)
  • Yamaha PSR-21 49-keys 16-sounds, 2 steps sliders (1986)
  • Yamaha PSR-22 49-keys 32-sounds, 2 steps sliders (1987)
  • Yamaha PSR-31 61-keys 16-sounds, additional YM3301 chip[17] for drums (1986)
  • Yamaha PSR-32 61-keys 32-sounds, additional YM3301 chip[17] for drums (1987)
  • Yamaha PSS-360 49 mini-keys 21-sounds, 5 steps sliders, low-cost mono version of PSS-460 (1986)
  • Yamaha PSS-460 49 mini-keys 21-sounds, 5 steps sliders (1986)
  • Yamaha PSS-470 49 mini-keys 21-sounds, 5 steps sliders (1987)
  • Yamaha PSS-560 49 mini-keys 21-sounds, 5 steps sliders, additional YM3301 chip[17] for drums (1986)
  • Yamaha PSS-570 49 mini-keys 21-sounds, 5 steps sliders, additional YM3301 chip[17] for drums (1987)

Synthesizers that use the YM2413 (cost reduced YM3812):[16]

  • Yamaha PSR-6 49-keys 100-sounds (1994)
  • Yamaha PSS-140 37 mini-keys 100-sounds (1988); the PSS-140 actually uses the YM2420, a slightly modified variant of the YM2413 with different registers[18]
  • Yamaha PSS-170 44 mini-keys 100-sounds (1986)
  • Yamaha PSS-270 49 mini-keys 100-sounds (1986)

Variants and derivatives

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An open-source RTL implementation of the OPL3 was written in SystemVerilog and adapted to an FPGA in 2015.[19]

See also

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References

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  1. ^ "Adlib / OPL2 / YM3812 – iki.fi/o". 11 January 2009.
  2. ^ "OPLx decapsulated". Google Docs.
  3. ^ a b c "Data". dev.kewl.org. Retrieved 2021-10-07.
  4. ^ a b c Leinecker, Richard C (1994). Making noise : creating sounds on your PC. New York: M & T Books. ISBN 1558513868.
  5. ^ a b c d Keyes, Jessica (1997). The Ultimate multimedia handbook. New York: McGraw Hill. ISBN 978-0-07-034530-0.
  6. ^ Sanglard, Fabien (2019). "3.6.2. Music". Game Engine Black Book: Wolfenstein 3D. Software Wizards. p. 95.
  7. ^ "Nuked OPL3 emulator". VOGONS. Retrieved 2024-02-09.
  8. ^ a b "YMF262 datasheet" (PDF). www.fit.vutbr.cz. Archived from the original (PDF) on 2003-05-20. Retrieved 2021-10-07.
  9. ^ a b c "Manual" (PDF). ftp.alsa-project.org. Retrieved 2021-10-07.
  10. ^ "82C925(100QFP) PDF Datasheet - OPTi Technologies, Inc". www.datasheets360.com.
  11. ^ "Archived copy" (PDF). gd.tuwien.ac.at. Archived from the original (PDF) on 6 February 2018. Retrieved 15 January 2022.{{cite web}}: CS1 maint: archived copy as title (link)
  12. ^ a b "Info" (PDF). doc.chipfind.ru. Retrieved 2021-10-07.
  13. ^ "esfm". www.github.com.com. Retrieved 2020-07-07.
  14. ^ a b "Ad-Lib Sound Card for the Parallel Port" – via www.youtube.com.
  15. ^ "PC audio for luddites". flaterco.com.
  16. ^ a b "Meet the little-known "Soundblaster" Keyboards". The 8-Bit Guy, Youtube. Retrieved 19 August 2015.
  17. ^ a b c d "Edward D-tech, Yamaha Chips, YM series". Edward D-tech. Archived from the original on 16 May 2016. Retrieved 25 January 2016.
  18. ^ "The Yamaha PSS-140 - a vintage keyboard that sounds like a Sound Blaster card". Preece Music, Youtube. Retrieved 16 January 2024.
  19. ^ "opl3_fpga". September 28, 2021 – via GitHub.
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