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Normal density of DA, DB, DC, DD, and DE sized connectors

The D-subminiature or D-sub is a common type of electrical connector. They are named for their characteristic D-shaped metal shield. When they were introduced, D-subs were among the smallest connectors used on computer systems.

Description, nomenclature, and variants

[edit]
"DE-9" redirects here. For other uses, see DE9 (disambiguation).
Normal density High density Double density
Name Pin layout Name Pin layout Name Pin layout
DA-15 8–7 DA-26 9–9–8 DA-31 10–11–10
DB-25 13–12 DB-44 15–15–14 DB-52 17–18–17
DC-37 19–18 DC-62 21–21–20 DC-79 26–27–26
DD-50 17–16–17 DD-78 20–19–20–19 DD-100 26–25–24–25
DE-9 5–4 DE-15 5–5–5 DE-19 6–7–6
19-pin[note 1] 10–9 104-pin 21–21–21–21–20[1][2]
23-pin[note 1] 12–11
  1. ^ a b non-standard shell size

Note that the high density and double density classification here is the reverse of floppy disk nomenclature. Here, high density is intermediate, between nominal and double density.

A D-sub contains two or more parallel rows of pins or sockets usually surrounded by a D-shaped metal shield, or shell, that provides mechanical support, ensures correct orientation, and may screen against electromagnetic interference. Calling that shield a shell (or D-shell) can be ambiguous, as the term shell is also short for the cable shell, or backshell. D-sub connectors have gender: parts with pin contacts are called male connectors or plugs, while those with socket contacts are called female connectors or sockets. The socket's shield fits tightly inside the plug's shield. Panel-mounted connectors usually have #4-40 UNC (as designated with the Unified Thread Standard) jackscrews that accept screws on the cable end connector cover that are used for locking the connectors together and offering mechanical strain relief, and can be tightened with a 3/16" (or 5mm) hex socket.

The hexagonal standoffs (4-40 bolts) at both sides of each connector have a threaded stud fastening the connectors to the metal panel. They also have threaded sockets to receive jackscrews on the cable shell, holding the plug and socket together.

A male DE-9 connector (inline socket)

Occasionally the nuts may be found on a cable end connector if it is expected to connect to another cable end (see the male DE-9 pictured). When screened cables are used, the shields are connected to the overall screens of the cables. This creates an electrically continuous screen covering the whole cable and connector system.

The D-sub series of connectors was introduced by Cannon in 1952.[3] Cannon's part-numbering system uses D as the prefix for the whole series, followed by one of A, B, C, D, or E denoting the shell size, followed by the number of pins or sockets,[4] followed by either P (plug or pins[5]) or S (socket) denoting the gender of the part. Each shell size usually (see below for exceptions) corresponds to a certain number of pins or sockets: A with 15, B with 25, C with 37, D with 50, and E with 9.[6] For example, DB-25 denotes a D-sub with a 25-position shell size and a 25-position contact configuration. The contacts in each row of these connectors are spaced 326/3000 of an inch apart, or approximately 0.1087 inches (2.76 mm), and the rows are spaced 0.112 inches (2.84 mm) apart; the pins in the two rows are offset by half the distance between adjacent contacts in a row.[7] This spacing is called normal density. The suffixes M and F (for male and female) are sometimes used instead of the original P and S for plug and socket.

Variants

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DA-26 male connector, sometimes incorrectly called DB-26HD or HD-26
The DB13W3 connector with three coaxial connections and ten ordinary pins
Male DB13W3 connector (plug)

Later D-sub connectors added extra pins to the original shell sizes, and their names follow the same pattern. For example, the DE-15, usually found in VGA cables, has 15 pins in three rows, all surrounded by an E size shell. The pins are spaced at 0.090 inches (2.3 mm) horizontally and 0.078 inches (2.0 mm) vertically,[7] in what is called high density. The other connectors with the same pin spacing are the DA-26, DB-44, DC-62, DD-78 and 104-pin. They all have three rows of pins, except the DD-78 which has four, and the 104-pin which has five rows.[1] The double density series of D-sub connectors features even denser arrangements and consists of the DE-19, DA-31, DB-52, DC-79, and DD-100. These each have three rows of pins, except the DD-100, which has four.

Common misnomers

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The above naming pattern was not always followed. Because personal computers first used DB-25 connectors for their serial and parallel ports, when the PC serial port began to use 9-pin connectors, they were often mislabeled as DB-9 instead of DE-9 due to ignorance of the fact that B represented a much larger shell size. It is now common to see DE-9 connectors sold as "DB-9" connectors. DB-9 nearly always refers to a 9-pin connector with an E-size shell. The non-standard 23-pin D-sub connectors for external floppy drives and video output on most of the Amiga computers are usually labeled DB-23, even though their shell size is two pins smaller than ordinary DB sockets. Several computers also used a non-standard 19-pin D-sub connector, sometimes called DB-19,[8] including Macintosh (external floppy drive), Atari ST (external hard drive), and NeXT (Megapixel Display monitor[9] and laser printer).

Reflecting the same confusion of the letters DB with just D as mentioned above, high-density connectors are also often called DB-15HD (or even DB-15 or HD-15), DB-26HD (HD-26), DB-44HD, DB-62HD, and DB-78HD connectors, respectively, where HD stands for high density.

Cannon also produced combo D-subs with larger contacts in place of some of the normal contacts, for use for high-current, high-voltage, or co-axial inserts. The DB13W3 variant was commonly used for high-performance video connections; this variant provided 10 regular (#20) pins plus three coaxial contacts for the red, green, and blue video signals. Combo D-subs are currently manufactured in a broad range of configurations by other companies.[10] Some variants have current ratings up to 40 A; others are waterproof and meet IP67 standards.[citation needed]

A further family of connectors of similar appearance to the D-sub family uses names such as HD-50 and HD-68, and has a D-shaped shell about half the width of a DB-25. They are common in SCSI attachments.

The original D-sub connectors are now defined by an international standard, IEC 60807-3 / DIN 41652. The United States military also maintains another specification for D-subminiature connectors, the MIL-DTL-24308 standard.[7]

Micro-D and Nano-D

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Comparison of microminiature D connector and male DE-9

Smaller connectors have been derived from the D-sub including the microminiature D (micro-D) and nanominiature D (nano-D) which are trademarks of ITT Cannon. Micro-D is about half the length of a D-sub and Nano-D is about half the length of Micro-D. Their primary applications are in military and space-grade technology such as SpaceWire networks. The MIL-SPEC for Micro-D is MIL-DTL-83513[11] and for Nano-D is MIL-DTL-32139.[12]

Typical applications

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A 9-pin male (DE-9M) connector (plug), and a 25-pin female (DB-25F) connector (socket)

Communications ports

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The widest application of D-subs is for RS-232 serial communications, though the standard did not make this connector mandatory. RS-232 devices originally used the DB-25, but for many applications the less common signals were omitted, allowing a DE-9 to be used. The standard specifies a male connector for terminal equipment and a female connector for modems, but many variations exist. IBM PC-compatible computers tend to have male connectors at the device and female connectors at the modems. Early Apple Macintosh models used DE-9 connectors for RS-422 multi-drop serial interfaces (which can operate as RS-232). Later Macintosh models use 8-pin miniature DIN connectors instead.

On PCs, 25-pin and (beginning with the IBM PC/AT) 9-pin plugs were used for the RS-232 serial ports; 25-pin sockets were used for parallel ports (instead of the Centronics port found on the printer itself, which was inconveniently large for direct placement on the expansion cards).

Many uninterruptible power supply units have a DE-9F connector on them in order to signal to the attached computer via an RS-232 interface. Often these do not send data serially to the computer but instead use the handshaking control lines to indicate low battery, power failure, or other conditions. Such usage is not standardized between manufacturers and may require special cables.

Network ports

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DE-9 connectors were used for some Token Ring networks as well as other computer networks.

Router with DA-15 (AUI) and DE-9 (serial console) connectors. Note the sliding clip on the former.

Originally in the 1980s Ethernet network interface cards or devices were connected using Attachment Unit Interface (AUI) cables to Medium Attachment Units that then connected to 10BASE5 and later 10BASE2 or 10BASE-T network cabling. The AUI cables used DA-15 connectors albeit with a sliding latch to lock the connectors together instead of the usual hex studs with threaded holes. The sliding latch was intended to be quicker to engage and disengage and to work in places where jackscrews could not be used for reasons of component shape.

In vehicles, DE-9 connectors are commonly used in Controller Area Networks (CAN): female connectors are on the bus while male connectors are on devices.[13]

Computer video output

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DE-9 connectors

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A female 9-pin connector on an IBM compatible personal computer may be a digital RGBI video display output such as MDA, Hercules, CGA, or EGA (rarely VGA or others). Even though these all use the same DE-9 connector, the displays cannot all be interchanged and monitors or video interfaces may be damaged if connected to an incompatible device using the same connector.[14][15][16][17][18][19]

9-pin connector pinouts[14][15][16][17][18][19]
Adaptor MDA CGA EGA VGA (early DE-9 variant)
Pin 1 Ground Ground Ground + Analog red
Pin 2 Ground Ground + Secondary red (intensity) + Analog green
Pin 3 + Red + Red + Analog blue
Pin 4 + Green + Green − Horizontal sync. (31.5 kHz)
Pin 5 + Blue + Blue ± Vertical sync. (70 / 60 Hz)
Pin 6 + Intensity + Intensity + Secondary green (intensity) Red ground
Pin 7 + Video Reserved + Secondary blue (intensity) Green ground
Pin 8 + Horizontal sync. (18.43 kHz) + Horizontal sync. (15.7 kHz) + Horizontal sync. (15.7 / 21.85 kHz) Blue ground
Pin 9 − Vertical sync. (50 Hz) + Vertical sync. (60 Hz) ± Vertical sync. (60 Hz) Combined sync ground

DE-15 connectors

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Female DE-15 connector (socket), used for VGA, SVGA and XGA ports. It is blue per to the PC System Design Guides color-coding scheme.

Later analog video (VGA and later) adapters generally replaced DE-9 connectors with DE-15 high-density sockets (though some early VGA devices still used DE-9 connectors). DE-15 connectors have the same shell size as DE-9 connectors (see above). The additional pins of the DE-15 VGA connector were used to add increasingly sophisticated monitor-sensing plug and play functionality.

DA-15 connectors

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Many Apple Macintosh models, beginning with the Macintosh II, used DA-15 sockets for analog RGB video out. These connectors had the same number of pins as the above DE-15 connectors, but used the more traditional pin size, pin spacing, and size shell of the DA-15 standard connector. "VGA adapters" (i.e. DA-15 to DE-15 dongles) were available but sometimes monitor-specific, or they needed DIP switch configuration, as the Macintosh's monitor sense pins[20] in particular were not identical with a VGA connector's DDC.

The earlier Apple IIGS used the same physical DA-15 connector for the same purpose but with an incompatible pinout. A digital (and thus also incompatible) RGB adapter for the Apple IIe also used a DA-15F. The Apple IIc used a DA-15F for an auxiliary video port which was not RGB but provided the necessary signals to derive RGB.

Game controller ports

[edit]

DE-9 connectors

[edit]
An unshielded DE-9 connector commonly used on early home consoles and computers for game controllers

The 1977 Atari Video Computer System game console uses modified DE-9 connectors (male on the system, female on the cable) for its game controller connectors. The Atari joystick ports have bodies entirely of molded plastic without the metal shield, and they omit the pair of fastening screws. In the years following, various video game consoles and home computers adopted the same connector for their own game ports, though they were not all interoperable. The most common wiring supported five connections for discrete signals (five switches, for up, down, left, and right movement, and a fire button), plus one pair of 100 potentiometers, or paddles, for analog input. Some computers supported additional buttons, and on some computers additional devices, such as a computer mouse, a light pen, or a graphics tablet were also supported via the game port. Unlike the basic one-button digital joysticks and the basic paddles, such devices were not typically interchangeable between different systems.

Systems using the DE-9 connector for their game port include the TI-99/4A,[21] Atari 8-bit computers, Atari ST, Atari 7800, VIC-20, Commodore 64, Commodore 128, Amiga, Amstrad CPC (which employs daisy-chaining when connecting two Amstrad-specific joysticks), MSX, X68000, FM Towns, ColecoVision, SG-1000, Master System, Mega Drive/Genesis, and the 3DO Interactive Multiplayer.

The ZX Spectrum lacks a built-in joystick connector of any kind but aftermarket interfaces provided the ability to connect DE-9 joysticks. NEC's home computers (e.g. PC-88, PC-98) also used DE-9 connectors for game controllers, depending on the sound card used.

The Fairchild Channel F System II[22] and Bally Astrocade[23] use DE-9 connectors for their detachable joystick as well. Both are incompatible with the Atari connector.

Many Apple II computers also use DE-9 connectors for joysticks, but they have a female port on the computer and a male on the controller, use analog rather than digital sticks, and the pinout is completely unlike that used on the aforementioned systems. DE-9 connectors were not used for game ports on the Macintosh, Apple III, IBM PC compatibles, or most game consoles outside the aforementioned examples. Sega switched to proprietary controller ports for the Saturn and Dreamcast.

DA-15 connectors

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DA-15 game port connector (yellow color, top)

DA-15S connectors are used for PC joystick connectors, where each DA-15 connector supports two joysticks each with two analog axes and two buttons. In other words, one DA-15S game adapter connector has 4 analog potentiometer inputs and 4 digital switch inputs. This interface is strictly input-only, though it does provide +5 V DC power. Some joysticks with more than two axes or more than two buttons use the signals designated for both joysticks. Conversely, Y-adapter cables are available that allow two separate joysticks to be connected to a single DA-15 game adapter port; if a joystick connected to one of these Y-adapters has more than two axes or buttons, only the first two of each will work.

The IBM DA-15 PC game connector has been modified to add a (usually MPU-401 compatible) MIDI interface, and this is often implemented in the game connectors on third-party sound cards, for example, the Sound Blaster line from Creative Labs. The standard straight game adapter connector (introduced by IBM) has three ground pins and four +5 V power pins, and the MIDI adaptation replaces one of the grounds and one of the +5 V pins, both on the bottom row of pins, with MIDI In and MIDI Out signal pins. (There is no MIDI Thru provided.) Creative Labs introduced this adaptation.[citation needed]

The Neo Geo AES game console also used the DA-15 connector, however, the pins are wired differently and it is therefore not compatible with the regular DA-15 PC game controllers.[24]

The Family Computer console had controllers that were hardwired but also included a DA-15 expansion port for additional peripherals.[25] Many clones of the hardware used a DA-15 which implemented a subset of the Famicom expansion port and were therefore compatible with some Famicom peripherals. Later clones switched to the cheaper DE-9 port.[26]

The Atari 5200 console also used a DA-15 instead of the DE-9 of its predecessor to facilitate the matrix for the keypad.[27] The Atari Falcon, Atari STe and Atari Jaguar used a DE-15.[28]

Other

[edit]

25-pin sockets on Macintosh computers are typically single-ended SCSI connectors, combining all signal returns into one contact (again in contrast to the Centronics C50 connector typically found on the peripheral, supplying a separate return contact for each signal), while older Sun hardware uses DD-50 connectors for Fast-SCSI equipment. As SCSI variants from Ultra2 onwards used differential signaling, the Macintosh DB-25 SCSI interface became obsolete.

D-subminiature connectors are often used in industrial products, the DA-15 version being commonly used on rotary and linear encoders.

19-pin connector for an external floppy drive on a Macintosh 512K

The early Macintosh and late Apple II computers used a non-standard 19-pin D-sub for connecting external floppy disk drives. Atari also used this connector on their 16-bit computer range for attaching hard disk drives and the Atari laser printer, where it was known as both the ACSI (Atari Computer System Interface) port and the DMA bus port. The Commodore Amiga used an equally non-standard 23-pin version for both its video output (male) and its port for daisy-chaining up to three extra external floppy disk drives (female).

In professional audio, several connections use DB-25 connectors:

  • TASCAM and many others are using a connection over DB-25 connectors,[29] which has been standardized into AES59. This connection transports AES3 digital audio or analog audio using the same pinout.[30]
  • TASCAM initially used their TDIF connection over DB-25 connectors for their multitrack recording audio equipment. The transported signals are not AES3 compatible.
  • Roland used DB-25 connectors for their multi-track recording audio equipment (R-BUS). A few patch panels have been made which have the DB-25 connectors on the back with phone jacks (or even TRS phone connectors) on the front, however, these are normally wired for TASCAM, which is more common outside of broadcasting.

In broadcast and professional video, parallel digital is a digital video interface that uses DB-25 connectors, per the SMPTE 274M specification adopted in the late 1990s. The more common SMPTE 259M serial digital interface (SDI) uses BNC connectors for digital video signal transfer.

DC-37 connectors are commonly used in hospital facilities as an interface between hospital beds and nurse call systems, allowing for the connection and signaling of Nurse Call, Bed Exit, and Cord out including TV entertainment and lighting controls.[citation needed] The comparatively rare DC-37 connector was also found as the so-called "GeekPort" electronics experimentation breakout connector on the even rarer BeBox computer.[31]

DB-25 connectors are commonly used to carry analog signals for beam displacement and color control to laser projectors, as specified in the ISP-DB25 protocol published by the International Laser Display Association.[32]

Wire-contact attachment types

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IDC D-Sub connectors DE-9 (male) and DA-15 (female)
A male PCB-mounting DD-50 connector (plug)

There are many different methods used to attach wires to the contacts in D-sub connectors.

  • Solder-bucket (or solder-cup) contacts have a cavity into which the stripped wire is inserted and hand-soldered.
  • Insulation displacement contacts (IDCs) allow a ribbon cable to be forced onto sharp tines on the back of the contacts; this action pierces the insulation of all the wires simultaneously. This is a very quick means of assembly whether done by hand or machine.
  • Crimp contacts are assembled by inserting a stripped wire end into a cavity in the rear of the contact, then crushing the cavity using a crimp tool, causing the cavity to grip the wire tightly at many points. The crimped contact is then inserted into the connector where it locks into place. Individual crimped pins can be removed later by inserting a special tool into the rear of the connector.
  • PCB pins are soldered directly to a printed circuit board and not to a wire. Traditionally through hole plated (THP) board style pins were used (print) but increasingly gull-wing surface mount (SMD) connections are used, although the latter frequently exhibit solder pad contact problems when exposed to mechanical stress. These connectors are frequently mounted at a right angle to the PCB, allowing a cable to be plugged into the edge of the PCB assembly.
  • Wire wrap connections are made by wrapping solid wire around a square post with a wire wrap tool. This type of connection is often used in developing prototypes.

The wire wrap and IDC connections styles had to contend with incompatible pin spacing to the 0.05 in ribbon cable or 0.1 in proto board grid, especially for larger pin counts.

See also

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References

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Further reading

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[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

D-subminiature

View on Grokipedia
from Grokipedia
The D-subminiature (D-sub) connector is a family of compact, rectangular electrical connectors distinguished by their D-shaped metal shell, which provides electromagnetic interference (EMI) shielding and mechanical polarization to prevent incorrect mating. Originally invented by engineers at Cannon Electric (later acquired by ITT) in 1952 as a lightweight alternative to larger circular plugs for aircraft radio systems, these connectors were designed to meet the growing demand for smaller, versatile interconnects in electronic applications. Standardized by the U.S. military under MIL-DTL-24308, D-subs feature machined pin or socket contacts arranged in one or two parallel rows, supporting standard-density (#20 AWG) layouts with 9-50 pins across shell sizes A-E or high-density (#22 AWG) layouts with up to 15-78 pins in the same shells, and operate reliably in temperatures from -55°C to +125°C. Following their debut, D-sub connectors quickly evolved into the first multipurpose interconnect system, earning a patent in 1957 and gaining adoption across civilian and military sectors due to their ruggedness, ease of assembly via crimp, solder, or PCB terminations, and cost-effectiveness. The MIL-DTL-24308 specification, which covers non-environmental, polarized shell designs with removable contacts made from copper alloy and gold-plated for corrosion resistance, ensured interoperability and high performance in harsh conditions, including vibration and shock resistance up to 20 g vibration and 50 g shock. Over decades, enhancements like combo power/signal layouts (incorporating #8 AWG power contacts) and filtered variants for EMI suppression expanded their utility, while international equivalents such as IEC 60807 further promoted global standardization. In design, D-subs consist of a die-cast or machined aluminum/stainless steel shell housing a thermoset epoxy insert that secures contacts and provides insulation, with optional grommets and seals for environmental protection in advanced variants. Common configurations include the DB-25 (25 pins for parallel ports), DA-15 (for legacy video), and DC-37 (for high-pin-count interfaces), alongside high-density options like the DD-50 for space-constrained applications. Their mating uses jackscrews or board locks for secure panel or cable mounting, supporting current ratings up to 5A per contact in standard setups and higher for power hybrids. Micro-D variants, derived from the same family but smaller (per MIL-DTL-83513), extend the lineage for ultra-compact needs, though the original D-sub remains dominant for its balance of density and durability. D-sub connectors are integral to numerous industries, including military and aerospace for avionics and navigation systems, telecommunications for data links, and computing for serial/parallel ports in legacy and industrial hardware. In medical equipment, test instrumentation, and robotics, they facilitate reliable signal transmission and power delivery, with filtered versions mitigating electromagnetic compatibility issues in sensitive environments. Despite the rise of modular alternatives like USB and Ethernet, D-subs persist in mission-critical and legacy systems due to their proven reliability, with ongoing production by manufacturers like ITT Cannon, Amphenol, and Glenair ensuring availability for new and retrofit designs.

Design and Nomenclature

Physical Structure

The D-subminiature connector features a characteristic D-shaped metal shell that provides electromagnetic shielding, mechanical support, and polarization to ensure proper mating orientation. This shell design prevents incorrect connections by allowing insertion only in one direction, with the flat side of the "D" aligning specific contacts. The shell is available in five standard sizes designated A through E, each accommodating a maximum number of pins: A shell up to 15 pins, B shell up to 25 pins, C shell up to 37 pins, D shell up to 50 pins, and E shell up to 9 pins. The connector consists of a two-piece construction comprising a plug (male) with protruding pins and a receptacle (female) with corresponding sockets, facilitating secure electrical and mechanical interconnection. Locking mechanisms, such as #4-40 UNC jackscrews or set screws, secure the mated pair against vibration and disconnection, with options for M3 threaded inserts in some variants. Materials for the shell typically include zinc-plated steel for corrosion resistance and cost-effectiveness, or stainless steel for enhanced durability in harsh environments. Dimensions vary by shell size to accommodate pin arrangements, with the E shell measuring approximately 30.81 mm in width and 16.92 mm in height, providing a compact footprint for lower-density applications. Larger shells scale accordingly, such as the A shell at 39.14 mm width and 25.25 mm height. Polarization is further enhanced by integral keys on the shell, while strain relief features like integrated grommets or rear inserts protect cable terminations from flexing and pulling forces.

Naming System

The standardized nomenclature for D-subminiature connectors originates from the MIL-DTL-24308 military specification, which designates the connector type with a "D" prefix indicating its subminiature classification, followed by a shell size letter from A to E that corresponds to the physical envelope and maximum pin capacity. In this system, gender is indicated separately, such as "P" for male plugs or "S" for female receptacles, with the pin count appended after a hyphen to specify the contact arrangement, such as DB-25P for a 25-pin male connector in a B-shell. In MIL-DTL-24308 part numbers, like M24308/4-01F, the numbers specify shell size, gender (e.g., 4 for plug), and other details. This MIL-spec naming ensures interoperability in military and aerospace applications by precisely defining the connector's form factor and mating compatibility. In civilian and commercial contexts, the nomenclature simplifies to notations like DB-25 for a 25-pin male connector, DE-9 for a 9-pin male in an E-shell, DA-15 for a 15-pin male in an A-shell, and DC-37 for a 37-pin connector in a C-shell, often appending "P" for pin (male) or "S" for socket (female) to clarify gender. A common misnomer persists with the 9-pin connector, frequently labeled as "DB9" instead of the correct "DE-9," stemming from historical errors in early documentation where the popular 25-pin DB-25 influenced shorthand usage despite the distinct E-shell size. Density variants are distinguished within the naming: standard density uses the base shell letter and pin count (e.g., DB-25 with two rows of pins), while high-density versions incorporate "HD" or sometimes "W" suffixes to indicate three-row arrangements for increased contacts in the same shell, such as DB-15HD for a 15-pin high-density male in a B-shell. This naming convention evolved from original U.S. military specifications developed in the 1950s by ITT Cannon to meet demands for compact, reliable interconnects in early electronic systems, and it has since been harmonized with international standards like IEC 60807-2 for performance levels in non-environmental rack-and-panel applications.

Standard Variants

The standard variants of D-subminiature connectors are characterized by their shell sizes, which determine the number of pins or sockets in standard density configurations. These include the E-shell with 9 contacts, A-shell with 15 contacts, B-shell with 25 contacts, C-shell with 37 contacts, and D-shell with 50 contacts. These shell sizes provide a range of options for different interconnection needs while maintaining compatibility within the D-sub family. D-subminiature connectors are available in male (pin) and female (socket) genders, designed to mate securely via a D-shaped metal shell that ensures proper alignment and shielding. Configurations include straight versions for cable-to-cable or panel mounting and right-angle types for printed circuit board applications, allowing flexibility in installation. Sealed variants of standard D-subminiature connectors incorporate environmental protection, such as IP67-rated designs that withstand dust, water immersion up to 1 meter for 30 minutes, and harsh conditions like vibration and corrosion, making them suitable for marine and industrial environments. These connectors were originally introduced by Cannon (now part of ITT) in the 1950s for military avionics applications, marking a significant advancement in compact, reliable multi-pin interconnects.

Electrical and Mechanical Specifications

Pin Counts and Configurations

D-subminiature connectors feature standard pin counts of 9, 15, 25, 37, and 50, corresponding to shell sizes E, A, B, C, and D, respectively. These configurations adhere to the MIL-DTL-24308 specification, which defines the layouts for reliable interconnection in rack-and-panel applications. The pins are arranged in parallel rows within the D-shaped shell, with most variants using two rows: the 9-pin (two rows of 5 and 4), 15-pin (two rows of 8 and 7), 25-pin (two rows of 13 and 12), and 37-pin (two rows of 19 and 18). The 50-pin variant employs three rows (17, 17, and 16 pins) to fit the larger shell size while maintaining consistent contact spacing of 2.76 mm horizontally and 2.84 mm vertically.
Pin CountShell SizeRow Arrangement
9E2 rows (5 + 4)
15A2 rows (8 + 7)
25B2 rows (13 + 12)
37C2 rows (19 + 18)
50D3 rows (17 + 17 + 16)
Pin numbering follows a standardized zigzag pattern per MIL-DTL-24308, starting from the top row left to right, then proceeding to the bottom row right to left (and similarly for the third row in 50-pin models if applicable). For instance, in the 9-pin (DE-9) configuration, pins 1–5 occupy the top row from left to right, while pins 6–9 are on the bottom row from right to left. This scheme ensures consistent orientation when mating connectors. Male connectors incorporate protruding pins, while female connectors use corresponding sockets for mating, providing polarized and secure connections. Optional hoods or backshells are employed for cable strain relief and environmental protection. Certain configurations permit blank positions within the insert arrangement, which can be utilized as dedicated shielding grounds to enhance electromagnetic interference protection without active contacts.

Contact and Shell Types

D-subminiature connectors utilize two primary types of contacts: machined and stamped. Machined contacts, typically fabricated from copper alloys and plated with gold for enhanced conductivity and corrosion resistance, offer superior mechanical strength and higher current-carrying capacity, making them ideal for applications requiring high reliability. In contrast, stamped and formed contacts, also derived from copper alloys but produced via cost-effective stamping processes, are commonly used in lower-power scenarios where economy is prioritized over peak performance. The shells of D-subminiature connectors are predominantly constructed from steel, which provides structural integrity and electromagnetic shielding. These steel shells are finished with zinc plating followed by a chromate conversion coating—often yellow chromate—for improved corrosion resistance and durability in various environments. Insulating inserts within the shells are made from thermoplastic materials, such as polybutylene terephthalate (PBT) or nylon, ensuring electrical isolation while maintaining flexibility and resistance to environmental stresses. Certain premium variants of D-subminiature connectors incorporate floating contacts, which allow for limited axial and angular movement to accommodate mating misalignment, thereby reducing stress on the connection during assembly. This design feature enhances ease of mating in applications with potential alignment challenges. Standard D-subminiature connectors are rated for 500 mating cycles, with some high-reliability versions extending to 1,000 cycles under MIL-DTL-24308 specifications, ensuring long-term mechanical durability.

Performance Standards

D-subminiature connectors adhere to established electrical performance standards that ensure reliable signal and power transmission. Standard signal contacts are rated for a maximum current of 5 A per pin, with higher-capacity variants available for power applications up to 40 A in specialized configurations. The dielectric withstand voltage is typically 1000 V AC RMS for one minute, supporting operation in low- to medium-voltage environments without breakdown. For RF variants incorporating coaxial contacts, characteristic impedance is maintained at 50 Ω or 75 Ω to minimize signal reflections in high-frequency applications. Environmental compliance is governed by MIL-DTL-24308, which specifies robust resistance to mechanical stresses and thermal extremes suitable for military and industrial use. Operating temperature range extends from -55°C to +125°C, accommodating harsh conditions without degradation in contact integrity. Vibration resistance meets EIA-364-28 Test Condition IV, enduring 20 G sinusoidal vibration from 10 Hz to 2000 Hz across three axes, while shock tolerance reaches 50 G peak per EIA-364-27 Test Condition E. Electromagnetic compatibility (EMC) is enhanced through the full 360° metal shell design, which provides grounding for shields and achieves shielding effectiveness greater than 30 dB up to 2000 MHz with backshells, reducing electromagnetic interference in sensitive systems. Recent updates to D-subminiature standards include compliance with RoHS Directive 2011/65/EU and REACH regulations since 2006, restricting hazardous substances like lead and promoting lead-free manufacturing. Post-2020 developments have introduced low-smoke, zero-halogen (LSZH) variants for aerospace applications, minimizing toxic emissions in fire scenarios while meeting flammability standards such as FAR 25.

Applications

Legacy Computing Interfaces

D-subminiature connectors played a pivotal role in early personal computing by serving as the standard interfaces for serial and parallel communication, enabling connections to peripherals such as modems, terminals, and printers. The RS-232 standard, developed by the Electronic Industries Association (EIA) in 1960, originally specified a 25-pin D-subminiature connector (DB-25) for serial data transmission, utilizing dedicated pins for transmit data (TX), receive data (RX), and signal ground to facilitate asynchronous communication at speeds up to 20 kbps. This DB-25 configuration became widespread in the 1960s and 1970s for telecommunications equipment and early computers, supporting modem connections for dial-up networking and terminal interfaces for data entry. With the advent of the IBM PC in 1981, a smaller 9-pin variant (DE-9) was adopted for RS-232 serial ports, maintaining compatibility while reducing size; the DE-9 pinout retained key signals like TX (pin 3), RX (pin 2), and ground (pin 5) for PC-to-peripheral links. Parallel ports, essential for high-speed data transfer to printers, leveraged the DB-25 connector in IBM PC-compatible systems starting in the early 1980s, adapting the Centronics interface developed in the 1970s. The Centronics parallel standard used a 36-pin connector on the printer side, but IBM standardized the host-side connection as a DB-25 female port on the computer, supporting 8-bit data lines (pins 2-9) along with control signals for strobe and acknowledge to achieve transfer rates around 150 kB/s. This setup dominated printer connectivity through the 1970s and 1980s, with the DB-25 enabling direct attachment of dot-matrix and daisy-wheel printers to PCs without additional adapters. In video applications, D-subminiature connectors facilitated analog RGB signal transmission for early PC displays. The Video Graphics Array (VGA), introduced by IBM in 1987 with the PS/2 series, employed a 15-pin high-density connector (DE-15) to carry three analog RGB signals (pins 1, 2, 3 for red, green, blue) plus horizontal sync (pin 13) and vertical sync (pin 11), supporting resolutions up to 640x480 at 256 colors. Preceding standards like the Color Graphics Adapter (CGA) from 1981 and Enhanced Graphics Adapter (EGA) from 1984 primarily used a 9-pin connector (DE-9) for TTL-level RGB outputs, with pins 1-3 for red, green, blue intensities and pin 7 for composite sync in CGA, limiting displays to 320x200 with 4 colors or 640x200 monochrome. Game ports for joysticks and analog controllers also relied on D-subminiature designs, with the IBM PC introducing a 15-pin connector (DA-15 or DB-15) in 1981 to support two joysticks simultaneously. This interface provided four analog input channels (pins 1-4 for X1/Y1/X2/Y2 axes via potentiometers) and four digital button lines (pins 9, 10 for joystick 1; pins 6, 7 for joystick 2), enabling real-time input for 1980s gaming titles on systems like the IBM PC and compatibles. The DA-15 configuration, often integrated into sound cards or motherboard headers, became the de facto standard for PC gaming peripherals through the decade, accommodating simple flight simulators and arcade-style games.

Industrial and Specialized Uses

D-subminiature connectors, qualified under MIL-DTL-24308, are extensively employed in aerospace and military applications due to their robustness in extreme conditions, including vibration, shock, and temperature variations ranging from -55°C to +125°C. These connectors support pin counts from 9 to 50 in standard density, with machined contacts rated for up to 5 A per contact and 1000 VAC, ensuring reliable signal and power transmission in avionics systems. In avionics, ARINC 600 series rack-and-panel connectors enable hybrid configurations that integrate signal, power, coaxial, and fiber optic contacts within a single shell, facilitating up to 800 contacts for high-density interconnects in aircraft electronics. For instance, these hybrids incorporate ELIO fiber optic contacts in quadrax cavities, achieving insertion loss as low as 0.3 dB per contact, which supports data rates essential for modern flight systems. Sealed variants of D-subminiature connectors further enhance performance in harsh environments by providing IP67-rated protection against dust and moisture. In the automotive sector, the On-Board Diagnostics II (OBD-II) interface utilizes a 16-pin D-subminiature connector defined by the SAE J1962 standard, first published in 1996, to enable standardized vehicle diagnostics through protocols like CAN and ISO 9141. This connector features two rows of eight pins in a trapezoidal shell, with pin 16 providing battery power and pins 4 and 5 serving as grounds, allowing mechanics to access engine data, emissions, and fault codes reliably. For instrumentation and test equipment, D-subminiature connectors, such as the DB-25 variant, are integral to interfaces like the General Purpose Interface Bus (GPIB, IEEE-488), where micro-D versions adapt 24-pin GPIB signals for compact integration in oscilloscopes and multimeters. In factory process control, these connectors facilitate robust RS-232 and RS-485 communications between programmable logic controllers (PLCs) and sensors, supporting industrial automation in environments requiring electromagnetic interference resistance. In telecommunications, early T1 and E1 line interfaces employed DB-25 D-subminiature connectors for serial data transmission in channel service units (CSUs) and data service units (DSUs), handling balanced signaling at 1.544 Mbps (T1) or 2.048 Mbps (E1). Although largely legacy today, these connectors persist in some network equipment for RS-449 or V.35 protocols, providing 25 pins for transmit/receive pairs and control signals in rack-mounted telecom systems.

Modern Adaptations

In contemporary applications, D-subminiature connectors have evolved to support higher data rates through specialized adapters and variants, particularly in industrial environments where legacy compatibility is essential. For instance, USB-to-D-sub adapters enable USB 2.0 interfaces (up to 480 Mbps) to interface with traditional serial ports using DE-9 (9-pin) configurations, facilitating the integration of modern peripherals with older systems in legacy setups. Similarly, Ethernet adaptations via RJ45-to-DB-9 modular adapters allow serial D-sub ports to connect to Ethernet networks, commonly used in industrial automation for RS232/RS422/RS485-to-Ethernet conversions, ensuring reliable data transmission in rugged settings. Hybrid D-sub connectors represent a significant modern adaptation, combining power, signal, and coaxial contacts within a single shell to meet demands for integrated high-performance interfaces. Amphenol's hybrid series, for example, supports up to 40 A power alongside signal contacts rated at 7.5 A, with coaxial options for enhanced shielding, compliant with MIL-C-24308 standards. In high-speed contexts, Glenair's HiPer-D (a D-sub variant) incorporates hybrid Ethernet, signal, and power elements, achieving 10 Gbps (10G-Base-T) over Category 6A cabling with 500 MHz bandwidth and crosstalk isolation, suitable for post-2015 aerospace and industrial protocols like ARINC 664. While 50-pin configurations exist for dense signal applications, hybrid implementations with coax often prioritize fewer pins for speed, though scalable to higher counts in custom designs. Despite these advancements, D-subminiature connectors face obsolescence in consumer electronics, largely phased out in favor of USB and HDMI interfaces since the 2010s due to superior speed and compactness. However, they persist in legacy systems and specialized sectors; in 2020s aerospace applications, micro-D and nano-D variants offer up to 35% weight reduction compared to standard sizes, aiding CubeSat and miniaturized spacecraft designs while maintaining MIL-spec reliability. The global market for D-sub in aerospace and defense is projected to grow from USD 1,482 million in 2024, driven by such optimizations. To support ongoing compatibility, accessories like gender changers and null modem cables remain essential for D-sub deployments. Gender changers convert male-to-male or female-to-female configurations for direct mating, available in DB-9 and DB-25 sizes with gold-plated contacts for low resistance. Null modem cables, typically DB-9 female-to-female, cross pins 2-3 and 4-5 to simulate local connections over serial lines, widely used in legacy networking and diagnostics without additional hardware.

Assembly and Variants

Wire Attachment Methods

D-subminiature connectors support several wire attachment methods to facilitate reliable electrical connections during assembly, primarily tailored for cable terminations. These include solder cup, crimp, and insulation displacement contact (IDC) techniques, each suited to different production volumes and wire types. Tooling standards ensure mechanical integrity through specified pull tests. The solder cup method involves direct soldering of stripped wire ends into cup-shaped contact terminations on the rear of the connector, providing a secure, low-resistance joint ideal for low-volume or prototype applications. This process requires pre-tinning the wire and cup with flux to prevent oxidation and ensure proper adhesion, while heat sinks are often applied to adjacent contacts to avoid thermal damage during soldering with a controlled iron at around 350°C. It accommodates wires from 24-28 AWG and is commonly used for custom cable assemblies where precision manual work is feasible. Crimp termination compresses a ferrule on the contact using specialized tools to form a gas-tight mechanical and electrical bond with the wire strands, followed by insertion of the contact into the connector shell. This method supports wires in the 20-28 AWG range, with an additional insulation grip crimp providing strain relief to prevent wire pull-out under mechanical stress. Hand or hydraulic crimpers, such as the AF8 or AFM8 series, are employed for consistent deformation, making it suitable for medium- to high-volume production due to its speed and repeatability. Insulation displacement contact (IDC) enables solder-free attachment by piercing the wire insulation with slotted contacts, creating direct conductor contact without stripping, which is particularly efficient for mass-terminating flat ribbon cables at a 0.05-inch (1.27 mm) pitch. In D-sub configurations, IDC plugs are pressed onto the cable using a cover or tool, forming multiple connections simultaneously for applications like panel-mount interfaces or PCB integrations. This technique is common for 28-30 AWG ribbon cables in data and signal transmission, reducing assembly time while maintaining reliability in compact setups. Dedicated tooling from manufacturers like Molex (formerly AMP) and TE Connectivity ensures compliance with assembly standards, including positioners and dies for precise crimping. Verification involves destructive pull tests exceeding 10 lbs per contact for size 20 pins, confirming retention strength without insulation interference, as per UL 486A-B guidelines adapted for connector applications.

High-Density and Miniature Forms

High-density variants of D-subminiature connectors utilize a three-row pin arrangement within the same shell sizes as standard two-row configurations, enabling greater pin counts for space-constrained printed circuit board (PCB) applications. For instance, the A-shell size accommodates 26 pins in high-density form compared to the standard 15 pins, while larger shells support up to 78 pins. Micro-D connectors represent a significant miniaturization of the D-subminiature design, featuring a 0.050-inch (1.27 mm) contact pitch and compliance with MIL-DTL-83513 specifications for polarized shell, microminiature rectangular connectors. Originating in the 1970s, these connectors offer pin counts up to 100 in various shell sizes and are particularly suited for avionics and other space-limited environments due to their compact footprint, roughly half the size of standard D-subs. They maintain durability comparable to standard variants, with mating cycles rated at 500 and vibration resistance of 20 G. Further advancing miniaturization, Nano-D connectors employ an even finer 0.025-inch (0.635 mm) pitch under MIL-DTL-32139 specifications, allowing for ultra-compact configurations such as a 9-pin connector in a 7 mm × 5 mm footprint. Developed in the 1980s as an evolution from Micro-D designs, Nano-D variants support up to 85 pins and have seen increased adoption post-2010 in applications like unmanned aerial vehicles (drones) and satellites, where weight and size are critical. Like Micro-D, they offer 500 mating cycles and 20 G vibration resistance, ensuring reliability in harsh conditions despite their reduced dimensions.

References

  1. https://www.ittcannon.com/about/1950s
  2. https://connectorsupplier.com/meet-the-connector-mil-dtl-24308/
  3. https://www.glenair.com/hiper-d/index.htm
  4. https://www.peigenesis.com/images/content/flashcards/d-sub-cheatsheet.pdf
  5. https://landandmaritimeapps.dla.mil/programs/milspec/ListDocs.aspx?BasicDoc=MIL-DTL-24308
  6. https://www.amphenolpcd.com/product/mil-dtl-24308-d-sub/
  7. https://www.glenair.com/hermetic-connectors/mil-dtl-24308/pdf/materials-finishes-and-specifications.pdf
  8. https://www.smithsinterconnect.com/products/connectors/emi-emp-filter-connectors/mil-dtl-24308-%28d-sub%29/
  9. https://blog.peigenesis.com/understanding-mil-spec-d-sub-and-mil-spec-micro-d-sub-connectors
  10. https://www.ittcannon.com/mil-dtl-24308-d-mm-d-subminiature
  11. https://www.mouser.com/pdfDocs/ITT-Cannon-D-Subminiature-Catalog-2.pdf
  12. https://www.peigenesis.com/images/content/amphenol/d-sub_m24308_catalog.pdf
  13. https://www.accesscomms.com.au/d-subminiature-connectors/
  14. https://rogerarrick.com/dcon/
  15. https://www.amphenol.co.jp/military/catalog/StandardDensity_MD.pdf
  16. https://sgconnector.com/types-of-d-sub-connectors-and-their-uses.html
  17. https://www.norcomp.net/products/ip67-rated/127
  18. https://www.mouser.com/datasheet/2/18/1/DSUB_2018-1651582.pdf
  19. https://www.norcomp.net/products/dsub-connectors/1
  20. https://www.arrow.com/en/research-and-events/articles/molex-how-to-choose-the-right-d-sub-connector-for-your-application
  21. https://www.peigenesis.com/images/content/amphenol/other/aph_d_sub.pdf
  22. https://www.amphenol-cs.com/d-sub-connectors-cables.html
  23. https://www.arrow.com/en/research-and-events/articles/intro-to-d-sub-connector-ordering-information
  24. https://www.mouser.com/datasheet/2/18/DSUB_CATab-1773482.pdf
  25. https://www.molex.com/en-us/products/connectors/d-sub-connectors
  26. https://www.mouser.com/datasheet/2/578/original-3045065.pdf
  27. https://www.farnell.com/datasheets/2654687.pdf
  28. https://www.axon-cable.com/publications/axon-rectangular-backshell_cg.pdf
  29. https://cdn.amphenol-cs.com/media/wysiwyg/files/documentation/datasheet/inputoutput/io_dsub_highdensity.pdf
  30. https://cablesondemand.com/amphenol-cs-dslszh9mm0-002-5-9-pin-db9-lszh-low-smoke-d-sub-cable-double-shielded-emi-cage-male-male-2-5ft-cs-dslszh9mm0-002-5
  31. https://www.camiresearch.com/Data_Com_Basics/RS232_standard.html
  32. https://news.sparkfun.com/14298
  33. https://www.assured-systems.com/faq/what-is-a-parallel-25-connector/
  34. https://www.electrostandards.com/840926-xxx-840926-xxx-m-m-xxx-ft-you-specify-length-1009.html
  35. https://components101.com/connectors/vga-connector-pinout-datasheet
  36. https://www.dosdays.co.uk/topics/graphics.php
  37. https://allpinouts.org/pinouts/connectors/input_device/joystick-pc-gameport/
  38. https://www.mouser.com/datasheet/2/379/Arinc-600-Series-337170.pdf
  39. https://www.glenair.com/mil-spec-rectangular-connectors/index.htm
  40. https://www.digikey.com/en/products/detail/avr-global-technologies-inc/OBD2-2004-J1962/16909485
  41. https://www.dashlogic.com/docs/technical/obdii_connector_pinout
  42. https://www.ni.com/en-vn/support/model.24m-24f-microdb25m-x13-gpib-cable.html
  43. https://www.rflelect.com/products/fiber-service-units/t1-e1-and-c37-94
  44. https://www.newegg.com/p/1DH-01FY-007J4
  45. https://www.digi.com/support/knowledge-base/using-an-rj45-adapter-to-connect-to-a-db9-connecto
  46. https://www.l-com.com/ethernet-modular-d-sub
  47. https://www.amphenol-cs.com/product-series/d-sub-hybrid.html
  48. https://www.glenair.com/presentations/pdf/high-speed-datalink-connectors-and-cables-for-ethernet-grade-protocols.pdf
  49. https://connectorsupplier.com/top-12-trends-for-universal-serial-bus-connectors/
  50. https://www.marketgrowthreports.com/market-reports/d-sub-connectors-for-aerospace-and-defense-market-115138
  51. https://us.rs-online.com/connectors/d-sub-connectors-contacts-accessories/d-sub-connector-accessories/d-sub-adapters/
  52. https://www.amphenol.com/products/connectors-d-shaped
  53. https://www.te.com/en/product-CAT-035-DCPPS201.html
  54. https://www.showmecables.com/d-sub-pin-crimp-tool
  55. https://www.crimptech.com.au/wp-content/uploads/2020/01/Tooling_Guide_for_High_Reliability_Electrical_Systems.pdf
  56. https://amphenolltw.com/news-events/how-does-an-idc-connector-work.html
  57. https://www.te.com/en/product-CAT-AM7-43650.html
  58. https://www.molex.com/content/dam/molex/molex-dot-com/products/automated/en-us/commercialcrimpbookpdf/638/63800/TM-638000029-001.pdf
  59. https://www.amphenol-cs.com/product-series/d-sub-high-density.html
  60. https://www.glenair.com/micro-d/l.htm
  61. https://connectorsupplier.com/what-are-mil-dtl-83513-connectors/
  62. https://www.ultimateconnector.com/whitepapers/nano-interconnects
  63. https://raytronics.ch/phocadownloadpap/MIL-DTL/MIL-DTL%2083513.pdf
  64. https://landandmaritimeapps.dla.mil/Downloads/MilSpec/Docs/MIL-DTL-24308/dtl24308.pdf
  65. https://www.omnetics.com/products/nano-d/
  66. https://www.axon-cable.com/en/nano-d-connectors
  67. https://landandmaritimeapps.dla.mil/Downloads/MilSpec/Docs/MIL-DTL-32139/dtl32139.pdf
  68. https://www.sunkye.com/products/mil-dtl-32139-nano-d-connector/
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