7400 series

The 7400 series of transistor-transistor logic (TTL) integrated circuits are historically important as the first widespread family of TTL integrated circuit logic.[1][2] It was used to build the mini and mainframe computers of the 1960s and 1970s. Several generations of pin-compatible descendants of the original family have since become de-facto standard electronic components.

Contents

Overview

The 7400 series contains hundreds of devices that provide everything from basic logic gates, flip-flops, and counters, to special purpose bus transceivers and Arithmetic Logic Units (ALU). Specific functions are described in a list of 7400 series integrated circuits.

Today, surface-mounted CMOS versions of the 7400 series are used in various applications in electronics and for glue logic in computers and industrial electronics. The original through-hole devices in dual in-line packages (DIP/DIL), which were the mainstay of the industry for many decades, are very useful for rapid breadboard-prototyping and education and so remain available from most manufacturers. The fastest types and very low voltage versions are typically surface-mount only, however.

The 14-pin DIP is an example of a 7400 part. The chip contains four two-input NAND gates. Each gate uses two pins for input and one pin for its output, and the remaining two contacts supply power (+5 V) and connect the ground.

While designed as a family of digital logic, it was not unusual to see TTL chips in analog circuits like Schmitt triggers. Like the 4000 series, the newer CMOS versions of the 7400 series are also usable as analog amplifiers using negative feedback (similar to operational amplifiers with only an inverting input).

The former Soviet Union manufactured the K155ЛA3 which was pin-compatible with the 7400 part available in the United States, except for using a metric spacing of 2.5mm between pins instead of the 1/10"-based (2.54mm) spacing used in the west.[3]

7400 series derivative families

7400 series parts were constructed using bipolar transistors, forming what is referred to as transistor–transistor logic or TTL. Newer series, more or less compatible in function and logic level with the original parts, use CMOS technology or a combination of the two (BiCMOS). Originally the bipolar circuits provided higher speed but consumed more power than the competing 4000 series of CMOS devices. Bipolar devices are also limited to a fixed power supply voltage, typically 5 V, while CMOS parts often support a range of supply voltages.

Milspec-rated devices for use in extended temperature conditions are available as the 5400 series. Texas Instruments also manufactured radiation-hardened devices with the prefix RSN, and the company offered beam-lead bare dies for integration into hybrid circuits with a BL prefix designation. [4]

Regular speed TTL parts were also available for a time in the 6400 series - these had an extended industrial temperature range of −40 C to +85 C. While companies such as Mullard listed 6400-series compatible parts in 1970 data sheets,[5] by 1973 there was no mention of the 6400 family in the Texas Instruments TTL Data Book. Some companies have also offered industrial extended temperature range variants using the regular 7400 series part numbers with a prefix or suffix to indicate the temperature grade.

As integrated circuits in the 7400 series were made in different technologies, usually compatibility was retained with the original TTL logic levels and power supply voltages. Strictly, an integrated circuit made in CMOS is no longer a TTL chip since it uses field-effect transistors (FETs) and not bipolar junction transistors, but similar part numbers are retained to identify similar logic functions and electrical (power and I/O voltage) compatibility in the different subfamilies. Over 40 different logic subfamilies use this standardized part number scheme.[6]

Many parts in the CMOS HC, AC, and FC families are also offered in "T" versions (HCT, ACT, and FCT) which have input thresholds that are compatible with both TTL and 3.3 V CMOS signals. The non-T parts have conventional CMOS input thresholds. The ACTQ family introduced by Fairchild utilizes Quiet Series technology to guarantee quiet output switching and improved dynamic threshold performance. FACT Quiet Series features GTO output control and undershoot corrector in addition to a split ground bus for superior performance. The 74H family is the same basic design as the 7400 family with resistor values reduced. This reduced the typical propagation delay from 9 ns to 6 ns but increased the power consumption. The 74H family provided a number of unique devices for CPU designs in the 1970s. Many designers of military and aerospace equipment used this family over a long period and as they need exact replacements, this family is still produced by Lansdale Semiconductor.[8]

The 74S family, using Schottky circuitry, uses more power than the 74, but is faster. The 74LS family of ICs is a lower-power version of the 74S family, with slightly higher speed but lower power dissipation than the original 74 family; it became the most popular variant once it was widely available.

The 74F family was introduced by Fairchild Semiconductor and adopted by other manufacturers; it is faster than the 74, 74LS and 74S families.

Through the late 1980s and 1990s newer versions of this family were introduced to support the lower operating voltages used in newer CPU devices.

History

Although the 7400 series was the first de facto industry standard TTL logic family to be second-sourced by several semiconductor companies, there were earlier TTL logic families such as the Sylvania SUHL family, Motorola MC4000 MTTL family (not to be confused with RCA CD4000 CMOS), the National Semiconductor DM8000 family, Fairchild 9300 series, and the Signetics 8200 family.

The 7400N quad NAND gate was the first product in the series.

The 5400 and 7400 series were used in many popular minicomputers in the seventies and early eighties. The DEC PDP series 'minis' used the 74181 ALU as the main computing element in the CPU. Other examples were the Data General Nova series and Hewlett-Packard 21MX, 1000, and 3000 series.

Hobbyists and students equipped with wire wrap tools, a 'breadboard' and a 5-volt power supply could also experiment with digital logic referring to how-to articles in Byte magazine and Popular Electronics which featured circuit examples in nearly every issue. In the early days of large-scale IC development, a prototype of a new large-scale integrated circuit might have been developed using TTL chips on several circuit boards, before committing to manufacture of the target device in IC form. This allowed simulation of the finished product and testing of the logic before the availability of software simulations of integrated circuits.

In 1965, typical quantity-one pricing for the SN5400 (military grade, in ceramic welded flat-pack) was around 22 USD.[9] As of 2007, individual commercial-grade chips in molded epoxy (plastic) packages can be purchased for approximately 0.25 USD each, depending on the particular chip. Purchased in bulk the price per unit falls even lower.

Part numbering scheme

The part numbers for 7400 series logic devices often use the following naming convention, though specifics vary between manufacturers.

For example SN74ALS245N means this is a device probably made by Texas Instruments (SN), it is a commercial temperature range TTL device (74), it is a member of the "advanced low-power Schottky" family (ALS), and it is a bi-directional eight-bit buffer (245) in a plastic through-hole DIP package (N).

Many logic families maintain a consistent use of the device numbers, as an aid to designers. Often a part from a different 74x00 subfamily could be substituted ("drop-in replacement") in a circuit, with the same function and pin-out yet more appropriate characteristics for an application (perhaps speed or power consumption), which was a large part of the appeal of the 74C00 series over the competing CD4000B series, for example. But there are a few exceptions where incompatibilities (mainly in pin-out) across the subfamilies occurred, such as:

Second sources in Europe and the Eastern Block

Some manufacturers such as Mullard and Siemens had pin-compatible TTL parts but with a completely different numbering scheme, however, data sheets identified the 7400-compatible number as an aid to recognition.

At the time the 7400 series was being made, some European manufacturers (that traditionally followed the Pro Electron naming convention) such as Philips/Mullard produced a series of TTL integrated circuits with part names beginning FJ. Some examples of FJ series are:

The Soviet Union started manufacturing TTL ICs with 7400 series pin-out in late 1960s and early 1970s. Part numbering is different from the Western series:

Before July 1974 the two letters from the functional description were inserted after the first digit of the series. Examples: К1ЛБ551 and К155ЛА1 (7420), К1ТМ552 and К155ТМ2 (7474) are the same ICs made at different times.

Clones of the plain 7400 series were also made in other Eastern Block countries[12]

No information is available for technology modifications (74H, 74LS, etc.) manufactured outside USSR.

References

  1. ^ http://www.computerhistory.org/semiconductor/timeline/1963-TTL.html The Computer History Museum, 1963 Standard Logic Families Introduced, retrieved 2008 April 16
  2. ^ Don Lancaster, "TTL Cookbook", Howard W. Sams and Co., Indianapolis, 1975, ISBN 0-672-21035-5 , preface
  3. ^ "Relation between names of foreign and Russian logic chips" (in Russian). http://www.gaw.ru/html.cgi/txt/doc/marker/logic.htm. Retrieved 26 March 2007. 
  4. ^ The Engineering Staff, Texas Instruments. The TTL Data Book for Design Engineers (1st edition ed.). Dallas, Texas. 
  5. ^ Mullard FJH 101 Data Sheet, from the Mullard FJ Family TTL Integrated Circuits 1970 databook, retrieved from http://www.datasheetarchive.com/preview/437512.html may 16, 2008
  6. ^ "Logic reference guide: Bipolar, BiCMOS, and CMOS Logic Technology"
  7. ^ a b c ti.com: Logic Selection Guide 2007, st.com: Standard Logic ICs
  8. ^ Lansdale Semiconductor home page
  9. ^ Allied Industrial Electronics Catalog #660. Chicago, Illinois: Allied Electronics. 1966. p. 35. 
  10. ^ The Engineering Staff, Texas Instruments. The TTL Data Book for Design Engineers (1st edition ed.). Dallas, Texas. 
  11. ^ The Engineering Staff, National Semiconductor Corporation. National Semiconductor TTL DATA BOOK. Santa Clara California. pp. 1–14. 
  12. ^ http://www.pchelar-probvaisambg.com/statia115_40_spisak.htm

See also