Intel 4004

The Intel 4004, released by the Intel Corporation on November 15, 1971, was the first in a long line of Intel central processing units (CPUs). Priced at , the chip marked both a technological and economic milestone in computing.

The 4-bit 4004 CPU was the first significant commercial example of large-scale integration, using the abilities of the MOS silicon gate technology (SGT) to integrate the CPU into a single chip. Compared to the existing technology, SGT enabled twice the transistor density and five times the operating speed, making future single-chip CPUs feasible. The MCS-4 chipset design, of which the 4004 was a part, served as a model on how to use SGT for complex logic and memory circuits, accelerating the adoption of SGT by the world's semiconductor industry.

The project originated in 1969 when Busicom Corp. commissioned Intel to design a family of seven chips for electronic calculators, including a three-chip CPU. Busicom initially envisioned using shift registers for data storage and ROM for instructions. Intel engineer Marcian Hoff proposed a simpler architecture based on data stored on RAM, making a single-chip CPU possible. Design work, led by Federico Faggin with contributions from Masatoshi Shima, began in April 1970. The first fully operational 4004 was delivered in March 1971 for Busicom's 141-PF printing calculator prototype, now housed at the Computer History Museum. General sales began in July 1971.

Faggin, who had developed SGT at Fairchild Semiconductor and used it to create the Fairchild 3708, the first commercially produced SGT integrated circuit (IC), used SGT, a method of using poly-silicon instead of metal, at Intel to achieve the integration required for the 4004. Additionally, he developed the "bootstrap load," previously considered unfeasible with silicon gate technology, and the "buried contact," which enabled silicon gates to connect directly to the transistor's source and drain without the use of metal. Together, these innovations doubled the circuit density, and thus halved cost, allowing a single chip to contain 2,300 transistors and run five times faster than designs using the previous MOS technology with aluminum gates.

The 4004's architecture laid the foundation for subsequent Intel processors, including the improved Intel 4040, released in 1974, and the 8-bit Intel 8008 and 8080.

History

Original concept

In April 1969, Busicom approached Intel and asked them to produce a chip set to handle the operations for an electronic calculator. Busicom was interested in building a lower-cost competitor to the 1965 Olivetti Programma 101, one of the world's first tabletop programmable calculators. The key difference was that the Busicom design would use integrated circuits to replace the printed circuit boards filled with individual components, and solid-state shift registers for memory instead of the costly magnetostriction wire in the 101. Busicom also realized that they could launch a general-purpose processor in a low-end desktop printing calculator, and then use the same design for other equipment like cash registers and automatic teller machines. The company had already produced a calculator using TTL small-scale integration logic ICs and were interested in having Intel reduce the chip count using Intel's medium-scale integration (MSI) techniques.

Intel assigned the recently hired Marcian Hoff, employee number 12, to act as the liaison between the two companies. In late June, three engineers from Busicom, Masatoshi Shima and his colleagues Masuda and Takayama, traveled to Intel to introduce the design. Although he had only been assigned to liaise with the engineers, Hoff began studying the concept. Their initial proposal had seven ICs: program control, arithmetic unit (ALU), timing, program ROM, shift registers for temporary memory, printer controller and input/output control.

Hoff became concerned that the number of chips and the required interconnections between them would make Busicom's price goals impossible to meet. Combining the chips would reduce the complexity and cost. He was also concerned that the still-small Intel would not have enough design staff to make seven separate chips at the same time. He raised these concerns with upper management, and Bob Noyce, the CEO, told Hoff he would support a different approach if it seemed feasible.

Simplified design

thumb|Chip layout from the development phase of the Intel 4004

A key concept in the Busicom design was that the program control and ALU were not aimed specifically at the calculator market, it was the program in ROM that turned it into a calculator. The original idea was that the company could use the same chips with different amounts of shift-register RAM and program ROM to produce a range of calculating machines. Hoff was struck by how closely the Busicom's instruction set architecture matched that of general-purpose computers. He began to consider whether a truly general-purpose processor could be made cheaply enough to be used in a calculator. When later asked where he got the ideas for the architecture of the first microprocessor, Hoff related that Plessey, "a British tractor company", had donated a minicomputer to Stanford, and he had "played with it some" while he was there.

Another development that made this design practical was Intel's work on the earliest dynamic RAM (DRAM) chips. Shift registers at that time were among the only low-cost read and write memory devices. However, shift register memory is not suited for random access, as each access must wait for the desired bit to flow through the chain. DRAM, on the other hand, can be accessed randomly, and the three-transistor DRAM cell saves silicon area compared to the six-transistor shift-register cell.

Finally, Hoff noticed that much of the complexity of the program control chip was due to every instruction being implemented separately. He suggested that the chip instead support subroutine calls and instructions be implemented as subroutines where possible. The application naturally suggested a 4-bit design, as this allowed for direct manipulation of binary-coded decimal (BCD) values used by calculators. Hoff worked on the overall design concept through July and August 1969 but found that the Busicom executives seemed uninterested in his proposal. Intel had to work smarter so Busicom would accept their proposal for the 141-PF calculator. They began to conceptualize a general purpose microprocessor that could be given instructions and return their results, as well as be able to merge all of the CPU functions of a computer. Later in fall of that year, Intel's engineers proposed a new design of just four chips, including one that could be programmed for use; the programmable chip would end up becoming the 4004 microprocessor. the first IC made with SGT, first sold at the end of 1968, and featured on the cover of Electronics in September 1969. The silicon gate technology also reduced the leakage current by more than 100 times, making possible sophisticated dynamic circuits like DRAMs (dynamic random access memories). Also, the highly doped silicon used for the gates could be used for the interconnections, and this greatly improved the circuit density of random-logic ICs like microprocessors.

This technique meant the interconnections could be performed at any time in the process. More importantly, the wiring was deposited using the same equipment that made the rest of the components. This meant that the slight differences in layout between different machine types was eliminated. Previously the interconnects had to be much larger than required in order to ensure the aluminum touched the silicon components which would be offset due to inaccuracies in the machinery. With this issue eliminated, the circuits could be placed much closer together, immediately doubling the density of the components and reducing their cost by the same amount. Additionally, the aluminum wiring acted as parasitic capacitors which limited the signal speed; without these parasitics the chips could run at faster speeds.

At Intel, Faggin began designing the new processor using this self-aligned gate process. Only days after Faggin joined Intel, Shima arrived from Japan. He was disappointed to learn that the project had stalled since he'd left in December, and expressed concern his original schedule was now impossible. Faggin responded by working well into the night every day, and Shima stayed on for another six months to help. Faggin himself immersed himself in workweeks that spanned 70 to 80 hours. Additional advances were needed to reach the required circuit density. One of these advances was the use of "buried contacts" to connect the wires directly to the components. Another was figuring out how to make adding "bootstrap loads" with silicon gate as part of one of the masking steps, eliminating one step from the processing. Without these two innovations by Faggin, Hoff's architecture could not have been realized in a single chip.

Into production

thumb|Intel 4004 CPU and associated chips on the circuit board from a Busicom calculator

Intel's chip-naming scheme at that time used a four-digit number for each component. The first digit indicated the process technology used, the second digit indicated the generic function, and the last two digits specified the sequential number in the development of that component type. Using this convention, the chips would have been known as the 1302, 1105, 1507, and 1202. Faggin felt this would obscure the fact that they formed a coherent set, and decided to name them as the "4000 family". The four chips were the following:

the Intel 4001, a 256-byte 4-bit ROM;
the Intel 4002, DRAM with four 20-nibble registers (total size 40 bytes);
the Intel 4003, an I/O chip comprising a 10-bit static shift register with serial and parallel outputs; and
the Intel 4004 CPU.

A fully expanded system could support 16 Intel 4001s for a total of 4 kB of ROM, 16 Intel 4002s for a total of 1,280 nibbles (640 bytes) of RAM, and an unlimited number of 4003s. The 4003s were connected to programmable input and output pins on the 4001 and to output pins on the 4002, not directly to the CPU.

thumb|[[Busicom 141-PF]]

With the design complete, Shima returned to Japan to begin building a prototype of the calculator. The first wafers of the 4001 were processed in October 1970, followed by the 4003 and 4002 in November. The 4002 proved to have a minor problem that was easily corrected. The first 4004s arrived at the end of December, and were completely non-functional. Probing the chip, Faggin found that the buried-contact fabrication step had been left out. A second run was fabricated in January 1971 and the 4004 worked as expected except for two minor problems.

Faggin was sending samples of these chips to Shima as they arrived in February 1971. Hoff and Mazor were also concerned that the design's limitations would make it less interesting to users who were accustomed to the new 16-bit minicomputers entering the market at that time.

This all changed in the summer of 1971, when Ed Gelbach, formerly of Texas Instruments, took over the marketing department and immediately began plans to publicly announce the product. This took place in the November 1971 when Intel ran ads "Announcing a new era of integrated electronics," first appearing in the November 15 edition of Electronic News.

The 8008

The 4004 became the first commercial microprocessor available for general use. This was almost not the case.

In December 1969, Intel was approached by Computer Terminal Corporation (CTC) to produce a custom bipolar memory chip for a computer terminal they were designing, the Datapoint 2200. Mazor and Hoff considered their CPU design and concluded it was not much more complicated than the 4004, and that it could be implemented as a single-chip 8-bit CPU. A few weeks before they hired Faggin, in March 1970 Intel hired Hal Feeney to design the Intel 8008, at that time called the 1201, following Intel's naming convention. However, CTC decided to initially proceed with a conventional TTL implementation of their CPU and the project was lowered in priority. Feeney was assigned to other projects and ultimately ended up helping Faggin with testing the 4000 family chips.

In January 1971, Feeney was reassigned back to the 1201 under Faggin's supervision and production chips were available in March 1972. In May, Hoff and Mazor went on a speaking tour to introduce the two CPU designs around the USA. The tradeoffs between the two designs were that with the 4004 and its memory and I/O chips it was much easier to build a complete computer system while the 8008 was more flexible, had a larger 16 kB address space, and offered more instructions. A significant difference is that while a minimal 4004 system could be built using only two chips, one 4004 and one 4001 (256-byte ROM), the 8008 would require at least 20 additional TTL components for interfacing with memory and I/O functions.

The two designs found themselves being used in different roles. The 4004 was used where the cost of implementation was the major concern, and became widely used in embedded controllers for applications like microwave ovens or traffic lights and similar roles. The 8008 instead found itself mostly used in user-programmable applications, such as computer terminals, microcomputers and similar roles. This split in functionality remains to this day, with the former being known as a microcontroller.

Description

thumb|National Semiconductor was a [[second-source manufacturer of the 4004, under their part number INS4004.]]

The 4004 employs a 10 μm process silicon-gate enhancement-load pMOS technology on a and can execute approximately instructions per second; a single instruction cycle is The original clock rate design goal was 1 MHz, the same as the IBM 1620 Model I.

The Intel 4004 was fabricated using masks produced by physically cutting each pattern at 500x magnification on a large sheet of Rubylith photo-reducing it, and repeating, a process made obsolete by current computer graphic design capabilities.

For the purpose of testing the produced chips, Faggin developed a tester for silicon wafers of MCS-4 family that was itself driven by 4004 chip. The tester also served as a proof for the management that Intel 4004 microprocessor could be used not only in calculator-like products, but also for control applications.

The 4004 includes functions for direct low-level control of memory-chip selection and I/O, which are not normally handled by the microprocessor; however, its functionality is limited in that it cannot execute code from RAM and is limited to whatever instructions are provided in ROM (or an independently loaded RAM working as ROM—in either case, the processor is itself unable to write or transfer data into an executable memory space). The RAM and ROM parts chips also unusual in their integration of I/O functions together with their primary memory function. This partitioning significantly reduced the minimum part count in an MCS-4 system, but required inclusion of a certain amount of processor-like logic on the memory chips themselves to accept, decode and execute relatively high-level data-transfer instructions.

The standard arrangement for a 4004 system is anything up to 16 × 4001 ROM chips (in a single bank) and 16 × 4002 RAM chips (in four banks of four), which together provide the 4 KB program storage, 1024 + 256 nibbles of data/status storage, plus 64 output and 64 input/output external data/control lines (which can themselves be used to operate, e.g. a 4003). Intel's MCS-4 documentation, however, claims that up to 48 ROM and RAM chips (providing up to 192 external control lines) "in any combination" can be connected to the 4004 "with simple gating hardware", but declines to give any further detail or examples of how this would actually be achieved.

Technical specifications

thumb|Intel 4004 architectural block diagram

thumb|Intel 4004 DIP chip [[pinout]]

thumb|Open Intel 4004 processor

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| 11

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| style="width:auto;" | (bit position)

|colspan="13" | Accumulator