MOS Technology

MOS Technology, Inc. ("MOS" being short for Metal Oxide Semiconductor), later known as CSG (Commodore Semiconductor Group) and GMT Microelectronics, was a semiconductor design and fabrication company based in Audubon, Pennsylvania. It is most famous for its 6502 microprocessor and various designs for Commodore International's range of home computers.

MOS Technology, Inc.
IndustrySemiconductor design and manufacturing
PredecessorAllen-Bradley
Founded1969 (1969)
Defunct2001 (2001)
SuccessorCommodore Semiconductor Group
Western Design Center
Headquarters,
United States

History

A 1973 MOS Technology advertisement highlighting their custom integrated circuit capabilities

Three former General Instrument executives, John Paivinen, Mort Jaffe and Don McLaughlin, formed MOS Technology in Valley Forge, Pennsylvania in 1969. The Allen-Bradley Company was looking to provide a second source for electronic calculators and their chips designed by Texas Instruments (TI). In 1970 Allen-Bradley acquired a majority interest in MOS Technology.

In the early 1970s, TI decided to release their own line of calculators, instead of selling just the chips inside them, and introduced them at a price that was lower than the price of the chipset alone. Many early chip companies were reliant on sales of calculator chips and were wiped out in the aftermath; those that survived did so by finding other chips to produce. MOS became a supplier to Atari, producing a custom single-chip Pong system.

Things changed dramatically in 1975. Several of the designers of the Motorola 6800 left Motorola shortly after its release, after management told them to stop working on a low-cost version of the design. At the time there was no such thing as a pure-play semiconductor foundry, so they had to join a chip-building company to produce their new CPU. MOS was a small firm with good credentials in the right area, the east coast of the US. The team of four design engineers was headed by Chuck Peddle and included Bill Mensch. At MOS they set about building a new CPU that would outperform the 6800 while being similar to it in purpose and much less expensive. The resulting 6501 design was somewhat similar to the 6800, but by using several design simplifications, the 6501 would be up to four times faster.

Mask fixing

Previous CPU designs, like the 6800, were produced using a device known as a contact aligner. This was essentially a complex photocopier, which optically reproduced a CPU design, or "mask", on the surface of the silicon chip. The name "contact" referred to the fact that the mask was placed directly on the surface of the chip, which had the significant disadvantage that it sometimes pulled away materials from the chip, which were then copied to subsequent chips. This caused the mask to become useless after about a dozen copies, and resulted in the vast majority of chips having fatal flaws; for a complex chip like the 6800, only about 10% of the chips would work once the masking process was complete.[1]

In 1974 Perkin-Elmer publicly introduced the Micralign system, the first projection scanner. Instead of placing the mask on the surface of the chip, it held it far from the surface and used highly accurate optics to project the image. Masks now lasted for thousands of copies instead of tens, and the flaw rate of the chips inverted so that perhaps 70% of the chips produced would work. The result was a similar inversion in pricing. The 6800 sold in small lots for $295; with no other changes than using a Micralign, the same design could sell for $42.[1]

The change to the Micralign revealed a further advantage. Previously the masks were mass-produced by photography companies like Kodak, who would make tens of thousands of copies of a master mask, or "reticle", and ship the masks to the aligners by the truckload. This meant that if a flaw was found in the design, it would cost a significant amount of money to fix it, as all the older masks would have to be thrown out. In contrast, with Micralign there was only one mask per aligner, so there was no inherent cost in replacing the mask if need be, although the cost, and especially time, of producing these master masks was considerable.[1]

MOS developed the ability to "fix" its masks after they had been produced.[1] This meant that as flaws in the design were discovered, the masks could be removed from the aligners, fixed, and put back in. This allowed them to rapidly drive out flaws in the original masks.

The company's production lines typically reversed the numbers others were achieving; even the early runs of a new CPU designwhat would become the 6502were achieving a success rate of 70 percent or better. This meant that not only were its designs faster, but they also cost much less as well.

6502 family

When the 6501 was announced, Motorola launched a lawsuit almost immediately. Although the 6501 instruction set was not compatible with the 6800, it could nevertheless be plugged into existing motherboard designs because it had the same functional pin arrangement and IC package footprint. That was enough to allow Motorola to sue. Allen-Bradley sold back its shares to the founders, sales of the 6501 basically stopped, and the lawsuit would drag on for many years before MOS was eventually forced to pay US$200,000 in fines.

In the meantime MOS had started selling the 6502, a chip capable of operating at 1 MHz in September 1975 for a mere US$25. It was nearly identical to the 6501, with only a few minor differences: an added on-chip clock oscillator, a different functional pinout arrangement, generation of the SYNC signal (supporting single-instruction stepping), and removal of data bus enablement control signals (DBE and BA, with the former directly connected to the phase 2 clock instead).[2] It outperformed the more-complex 6800 and Intel 8080, but cost much less and was easier to work with. Although it did not have the 6501's advantage of being able to be used in place of the Motorola 6800 in existing hardware, it was so inexpensive that it quickly became more popular than the 6800, making that a moot point.

Image of the circuit board of a Commodore 64 showing some important MOS Technology circuits: the 6510 CPU (long chip, lower left) and the 6581 SID (right). The production week/year (WWYY) of each chip is given below its name.

The 6502 was so cheap that many people believed it was a scam when MOS first showed it at a 1975 trade show. They were not aware of MOS's masking techniques and when they calculated the price per chip at the current industry yield rates, it did not add up. But any hesitation to buy it evaporated when both Motorola and Intel dropped the prices on their own designs from $179 to $69 at the same show in order to compete. Their moves legitimized the 6502, and by the show's end, the wooden barrel full of samples was empty.

The 6502 would quickly go on to be one of the most popular chips of its day. A number of companies licensed the 650x line from MOS, including Rockwell International, GTE, Synertek, and Western Design Center (WDC).

A number of different versions of the basic CPU, known as the 6503 through 6507, were offered in 28-pin packages for lower cost. The various models removed signal or address pins. Far and away the most popular of these was the 6507, which was used in the Atari 2600 and Atari disk drives. The 6504 was sometimes used in printers. MOS also released a series of similar CPUs using external clocks, which added a "1" to the name in the third digit, as the 6512 through 6515. These were useful in systems where the clock support was already being provided on the motherboard by some other source. The final addition was the "crossover" 6510, used in the Commodore 64, with additional I/O ports.

Commodore Semiconductor Group

However successful the 6502 was, the company itself was having problems. At about the same time the 6502 was being released, MOS's entire calculator IC market collapsed, and its prior existing products stopped shipping. Soon they were in serious financial trouble. Another company, Commodore Business Machines (CBM), had invested heavily in the calculator market and was also nearly wiped out by TI's entry into the market. A fresh injection of capital saved CBM, and allowed it to invest in company suppliers in order to help ensure their IC supply would not be upset in this fashion again. Among the several companies were LED display manufacturers, power controllers, and suppliers of the driver chips, including MOS.

In late 1976, CBM, publicly traded on the NYSE with a market capitalization around US$60 million, purchased MOS (whose market cap was around US$12 million) in an all-stock deal. Holders of MOS received a 9.4 percent equity stake in CBM[3][4][5] on the condition that Chuck Peddle would join Commodore as chief engineer. The deal went through, and while the firm basically became Commodore's production arm, they continued using the name MOS for some time so that manuals would not have to be reprinted. After a while MOS became the Commodore Semiconductor Group (CSG). Despite being renamed to CSG, all chips produced were still stamped with the old "MOS" logo until 1989.

MOS had previously designed a simple computer kit called the KIM-1, primarily to "show off" the 6502 chip. At Commodore, Peddle convinced the owner, Jack Tramiel, that calculators were a dead end, and that home computers would soon be huge.

However, the original design group appeared to be even less interested in working for Jack Tramiel than it had for Motorola, and the team quickly started breaking up. One result was that the newly completed 6522 (VIA) chip was left undocumented for years.

Bill Mensch left MOS even before the Commodore takeover, and moved home to Arizona. After a short stint consulting for a local company called ICE, he set up the Western Design Center (WDC) in 1978. As a licensee of the 6502 line, their first products were bug-fixed, power-efficient CMOS versions of the 6502 (the 65C02, both as a separate chip and embedded inside a microcontroller called the 65C150). But then they expanded the line greatly with the introduction of the 65816, a fairly straightforward 16-bit upgrade of the original 65C02 that could also run in 8-bit mode for compatibility. Since then WDC moved much of the original MOS catalog to CMOS, and the 6502 continued to be a popular CPU for the embedded systems market, like medical equipment and car dashboard controllers.

GMT Microelectronics

After Commodore's bankruptcy in 1994, Commodore Semiconductor Group, MOS's successor, was bought by its former management for about $4.3 million, plus an additional $1 million to cover miscellaneous expenses including a United States Environmental Protection Agency (EPA) license. Dennis Peasenell became CEO. In December 1994, the EPA entered into a Prospective Purchase Agreement (limiting the company's liability in exchange for sharing the costs of cleanup) with GMT Microelectronics. In 1994, the company, operating under the name GMT Microelectronics (Great Mixed-signal Technologies), reopened MOS Technology's original, circa-1970 one-micrometre process fab (semiconductor fabrication plant) in Audubon, Montgomery County, Pennsylvania that Commodore had closed in 1993.[6]

The plant had been on the EPA's National Priorities List of hazardous waste sites since October 4, 1989.[7][8] This was due to a 1974 leak of trichloroethylene (TCE) from an underground 250-gallon concrete storage tank used by Commodore Business Machines in the semiconductor cleaning process.[6] Leaks from the tank had caused the local groundwater to become contaminated with TCE and other volatile organic compounds (VOCs) in 1978.[6] By 1999 GMT Microelectronics had $21 million in revenues and 183 employees working on the site. Announced in March 1999, GMT would have provided foundry services based on TelCom's Bipolar and SiCr (silicon chromium) Thin Film Resistor processes and would have been a licensed alternate source for TelCom's Bipolar based products,[9] with production running at 10,000 5-inch semiconductor wafers per month, producing CMOS, BiCMOS, NMOS, bipolar and SOI (silicon on insulator) devices. In 2000, GMT Microelectronics discontinued operations and abandoned all of its assets at the Commodore Semiconductor Group superfund site.[6]

Chip naming convention

Most of the MOS chips are named according to following rules, which shows used technology (logic gate design):[10]

Products

  • KIM-1 single board computer (kit)/CPU evaluation board, based on 6502
  • 4510 CPU (CSG 65CE02) with two CIAs on-chip; 3.45 MHz
  • 5719 Gary Gate Array
  • 2521 8-digit calculator chip[11][12]
  • 2523 8-digit calculator chip[13][14]
  • 2529 Single chip scientific calculator array[15]
  • 6501 CPU pin-compatible with Motorola 6800
  • 6502 CPU equal to 6501 except no 6800-pin-compatibility
  • 65CE02 CPU derived from the 6502
  • 6503 CPU with 12 address pins, NMI pin and IRQ pin
  • 6504 CPU with 13 address pins and IRQ pin
  • 6505 CPU with 12 address pins, IRQ pin and RDY pin.
  • 6507 CPU with 13 address pins
  • 6508 CPU with 256 B RAM and 8 I/O pins
  • 6509 CPU with 20 address pins
  • 6510 CPU with clock pins and I/O ports,
  • 6520 PIA Peripheral Interface Adapter
  • 6522 VIA Versatile Interface Adapter
  • 6523/6525 Tri-Port Interface
  • 6526/8520/8521 CIA Complex Interface Adapter
  • 6529 SPI/SPIA Single Port Interface Adapter
  • 6530 RRIOT ROM-RAM-I/O Timer
  • 6532 RIOT RAM-I/O Timer
  • 6540 2 KiB ROM
  • 6545 CRTC CRT Controller
  • 6550 512 byte Static RAM
  • 6551 ACIA Asynchronous Communications Interface Adapter
  • 6560 VIC Video Interface Chip, (NTSC)
  • 6561 VIC Video Interface Chip, (PAL) Revision: -101 / E
  • 6562 VIC Video Interface Chip, (NTSC) (6561 supporting 40-column)
  • 6564 80-column video (intended for Colour PET, part of its design used in the MOS 6560/6561)
  • 6566 VIC-II (MaxMachine)
  • 6567 VIC-II (NTSC) Revision: R56A/R7/R8/R9
  • 6569 VIC-II (PAL) Revision: R1/R3/R4/R5 (R1 = only 5 lumas)
  • 6570 6500/1 microcontroller on keyboard PCB in Amiga 500 revision: -036
  • 6572 VIC-II (PAL-N)
  • 6573 VIC-II (PAL-M)
  • 6581/6582/8580 SID Sound Interface Device
  • 7360/8360 TED Text Editing Device (HMOS-I/II)
  • 7501 CPU HMOS-I 6502 with 7-bit I/O port
  • 8361 AGNUS Address Generator Unit (NTSC)
  • 8362 DENISE Display Encoder
  • 8364 PAULA Port Audio UART and Logic
  • 8367 AGNUS Address Generator Unit (PAL)
  • 8370 "Fat" AGNUS Address Generator Unit (NTSC)
  • 8371 "Fat" AGNUS Address Generator Unit (PAL)
  • 8372 ECS AGNUS Address Generator Unit
  • 8373 ECS DENISE Display Encoder
  • 8374 AGA ALICE Address Generator Unit
  • 8375 ECS AGNUS Address Generator Unit
  • 8500 CPU HMOS-II Version of 6510
  • 8501 CPU HMOS-II 6502 with 7-bit I/O port
  • 8502 CPU compatible with 6510 but able to run at 2 MHz
  • 8520 CIA (Complex Interface Adapter) 1 MHz 8520 or 2 MHz 8520A-1 in Amiga
  • 8551 ACIA Asynchronous Communications Interface Adapter, HMOS-II variant of the 6551
  • 8562 VIC-II (NTSC)
  • 8563 VDC Video Display Controller
  • 8564 VIC-II (NTSC)
  • 8565 VIC-II (PAL)
  • 8566 VIC-II (PAL)
  • 8568 VDC with composite HSYNC, VSYNC, and RDY interrupt
  • 8701 clock generator
  • 8721 PLA
  • 8722 MMU Memory Management Unit
  • 8726 REC RAM Expansion Controller
  • 8727 DMA Direct Memory Access

References

  1. Mensch, Bill (November 10, 2014). "Oral History of William David "Bill" Mensch, Jr" (PDF). Computer History Museum. p. 18.
  2. "MOS MCS6500 Microcomputer Family Hardware Manual (Publication Number 6500-10A), January 1976, p. 41" (PDF).
  3. "MOS – The Rise of MOS Technology & The 6502" (published January 18, 2006). March 2015. Retrieved May 10, 2016. MOS Technology is privately owned and valued at around $12 million.
  4. "Calculator maker integrates downwards". New Scientist. Vol. 71, no. 1071. Reed Business Information. September 9, 1976. p. 541 via Google Books.
  5. "Commodore Buys MOS Technology", New Scientist, September 1976
  6. "THIRD FIVE-YEAR REVIEW REPORT For Commodore Semiconductor Group Superfund Site" (PDF). United States Environmental Protection Agency Region III. August 2015. Archived from the original (PDF) on May 21, 2020.
  7. "Commodore Computers Superfund Site Information". Environmental Protection Agency. April 2004. Retrieved May 23, 2019.
  8. "Commodore Semiconductor Group" (PDF). epa.org. August 2002. Retrieved August 11, 2020.
  9. "GMT signs bi-polar foundry deal with TelCom". Electronic Engineering Times. Retrieved May 23, 2019.
  10. "m6502.txt - m6502 - tankcarneiro". Archived from the original on March 5, 2016. Retrieved March 24, 2015.
  11. Vis, Peter. "Melcor 380". Calculators. Retrieved January 14, 2023.
  12. Woerner, Joerg. "MELCOR Model 380". Datamath Calculator Museum. Retrieved January 14, 2023.
  13. Sebastian, Mike. "MOS Technology, Inc. Calculator Chips". Programmable Calculators. Retrieved April 4, 2019.
  14. Braun; et al. (January 4, 1977). Measuring system for the pharmacological manipulation of the coagulation mechanism in blood and for the elapsed coagulation time. United States: United States Patent and Trademark Office. Retrieved April 4, 2019.
  15. "MOS Technology Calculator Chip Ad 1974". Electronics. November 14, 1974. Retrieved April 4, 2019.

40°07′27.9″N 75°25′07.2″W

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