Previous computers Ferranti was among the first companies to introduce a commercial computer, the
Ferranti Mark 1 of 1951. They followed this with several other commercial designs, most notably the
Ferranti Atlas of 1962, for a time the fastest computer in the world. In 1963 they used the
Ferranti-Packard 6000, developed independently at their Canadian division, as the "golden brick" in the sale of their entire commercial computing line to
International Computers and Tabulators (ICT). ICT used the FP6000 as the basis for their 1900 line, which sold for years. Prior to the sale, Ferranti sold about 24% of all computing hardware in the UK. As part of the deal with ICT, Ferranti were barred from sales into the commercial computer market. This left them with two existing architectures that had been developed for military uses, the small
Ferranti Argus that had already become a success in the industrial controller market, and the FM 1600, a larger machine used for realtime data handling, weapons control and simulation. Both were built of individual
transistors and
small scale integration integrated circuits using Ferranti's MicroNOR
bipolar transistor process. These were both very successful in the market, generating hundreds of millions of pounds of sales through the late 1960s.
CDI A significant problem with the MicroNOR process was that a
logic gate implemented using bipolar layout was significantly larger than one using the contemporary
MOSFET process, about six times. In typical designs, the bipolar layout also required three or four extra masking steps, each of which was time-consuming and increased the possibility of the chip being damaged during processing. Experience with MicroNOR suggested that a maximum of about 100 gates was the limit for a single chip, in contrast to MOS, which was being used for designs with thousands of gates. However, the MOS system was more sensitive to impurities in the semiconductor feedstock, which led to electrical noise that reduced performance and also limited its operating conditions. These issues made MOSFET unacceptable in the military market. In 1971, Ferranti licensed the new collector-diffusion-isolation (CDI) process from
Fairchild Semiconductor. This process, originally developed at
Bell Labs, produced a dramatically simplified bipolar gate which required fewer masking steps and was only slightly larger than the equivalent MOS. This was of little interest to either Bell or Fairchild, who were happy with their MOS processes, and neither had developed the system beyond experimental production runs. Ferranti invested heavily in the CDI process, working to raise the operating voltage from 3 to 5V for compatibility with their existing
transistor-transistor logic (TTL) devices that were already widely used in military applications. This led to a series of
medium scale integration parts using the process. Most well known among these was a series of
uncommitted logic arrays (ULA, or gate array), chips with no pre-set logic design that could be programmed by the developer to produce any required circuit. These became very popular, and by 1986 the company held about 20% of the worldwide market for ULAs.
F100-L The introduction of the first
microprocessors in the early 1970s cut into Ferranti's military computing business. While these early designs were not competitive in performance terms, their
price/performance ratio was orders of magnitude better than Ferranti's discrete designs, despite several rounds of cost-reduction in the MicroNOR line in the late 1960s. Convinced that the microprocessor represented a strategic change in military applications, in 1974 the
UK Ministry of Defence agreed to sponsor an effort by Ferranti to produce a military-grade microprocessor design using the CDI process, whose high power-handling allowed them to operate in electrically noisy environments. An internal survey within the company suggested that an 8-bit part would not have the capability needed by the various divisions, and the decision was made to produce a 16-bit part. Based on studies of the economics of chip fabrication, Ferranti concluded that they had a budget of about 1,000 gates before the design would be too expensive. To produce a 16-bit design with this limited gate count, the
arithmetic logic unit (ALU) used a
bit-serial architecture. This slows the performance of mathematical operations, so that the minimum time needed to complete an instruction is 36 clock cycles. This performance hit is offset somewhat by the 8 MHz clock speed, roughly double that of the fastest MOS-based CPUs of the era. With 16-bit data and 15-bit addresses, normally 31 pins would be required to interface the design to the computer as a whole. Desiring a low-cost solution, it had to fit into a conventional 40-pin
dual in-line package (DIP). To accomplish this, the data and address lines share pins, and thus require multiple cycles to complete the reading of a single instruction. For comparison, the
Texas Instruments TMS9900, another 16-bit design introduced the same year, had double the gate count and was packaged in an expensive custom 64-pin DIP. Ultimately the F100 failed to meet its 1,000 gate limitation and was built with about 1,500 gates on a 5.8 mm square surface. This was larger than their existing mask-production system and required them to develop a new version with a larger optical reduction ratio. The timing of the design effort also produced one advantage; the F100 was beginning to be readied for production just as the
Micralign system was coming to market, and Ferranti adopted this projection alignment system for production, thereby greatly improving yields. As was common at the time, the F100 was introduced along with a family of support chips, including memory bus interfaces, interrupt controller, a
direct memory access controller and a basic
serial bus controller. Most of these were built using their ULA chips. Perhaps most interesting among these was the F101-L, released shortly after the CPU, which performed hardware multiplication and division. This became so common that the CPU was soon offered with the F101 on the same die, as the FBH5092. While the F100 was being developed, Ferranti produced a multi-card rackmount version of the CPU, the F100-M. This was used as a development platform and saw some civilian use as well. Programming tools were initially written in
FORTRAN, but most projects were written in
CORAL once a compiler for that language became available. When it was first announced in 1977, 100-unit lots were priced at £57, but that was soon reduced to £39 by 1978. A set containing an F100 along with the F111-L control interface and two F112-L DMA controllers was available for an additional £18. While this made it uncompetitive with MOS-based commercial processors like the $25
Zilog Z80 or $11
MOS 6502 in the same 100-unit lots, it was very competitive with other military-spec designs like the Z80's military-rated unit at $165. The F100 quickly found use in UK defense projects. Among the more well-known successes was the guidance unit for the
Sea Eagle missile. Other examples include the gunnery computer for the
Falcon self-propelled anti-aircraft gun, a variety of ballistics computers used in various tanks, the CPU for the
UoSAT-1 satellite, and a number of naval computer applications. It was also used in the civilian field in engine management systems from Ultra Electronic Controls, a propeller speed limiter from Dowty Group, and even control of nuclear test equipment using the
CAMAC protocol.
F200-L The F100 line was updated in 1984 with the introduction of the F200-L, which was software and pin-compatible with the F100. The primary changes were to include the math processor, formerly the F101, as part of the base CPU. Improvements in fabrication also allowed the F200-L to run up to 20 MHz. The F200 also supported the 16th bit in addresses, expanding the memory to 64 kW (128 kB). The new F220-L memory management unit, launched at the same time, provided address lookup within a 1 MW (2 MB) memory space.
Plessey purchase During the 1980s, Ferranti was very successful and cash-flush. Desiring to make more sales into the United States, the company began looking for an established US military supplier they could buy and use as the basis for their own division in the country. This process eventually led them to purchase
International Signal and Control (ISC) in 1987, and along with it, changing the name of the company to Ferranti International. As part of the bankruptcy proceedings, Ferranti was broken up and the semiconductor division was purchased by
Plessey. This was subsequently part of the
Siemens Plessey unit after Siemens purchased the company in 1989. The line continued to be produced through this period, with the F100/200 itself being produced until at least 1992, and some of the other members until 1995.
Today Used primarily in military systems, few F100 systems remain today. Among the few are a display F100-L chip at the
Museum of Science and Industry in Manchester, also there are two types of display F100-L chips and a DATA book at The ICL Computer Museum, and a small number of cards from a F100
microcomputer at the
Centre for Computing History. ==Description==